NONINVASIVE METHODS
IN CARDIOLOGY 2012
MASARYK UNIVERSITY • FACULTY OF MEDICINE
BRNO • CZECH REPUBLIC
Brno 2012
Edited by: HALBERG F., KENNER T., SIEGELOVÁ J., DOBŠÁK P.
NONINVASIVE METHODS
IN CARDIOLOGY 2012
MASARYK UNIVERSITY • FACULTY OF MEDICINE
BRNO • CZECH REPUBLIC
Brno 2012
Edited by: HALBERG F., KENNER T., SIEGELOVÁ J., DOBŠÁK P.
Under the auspices of
doc. PhDr. Mikuláš Bek, Ph.D., Rector of Masaryk University Brno
prof. MUDr. Jiří Mayer, CSc., Dean of Faculty of Medicine Masaryk University Brno
Ing. Petr Koška, MBA, Director of The St. Anna Teaching Hospital in Brno
Reviewed by: prof. MUDr. Zdeněk Placheta, DrSc.
© 2012 Masarykova univerzita
ISBN 978-80-210-6026-5
CONTENTS
PROF. DR. THOMAS KENNER, 80 YEARS OF AGE ��������������������������������������������������������������������������������������5
Jarmila Siegelova
THE FUNCTIONAL EFFECT OF TIME-DELAYS IN CHRONOBIOLOGY AND CHRONOPATHOLOGY��9
Thomas Kenner
CONTRIBUTIONS TO THE ANALYSIS AND INTERPRETATION OF FORCES INFLUENCING
THE PRESSURE-FLOW-RELATION IN ARTERIES�������������������������������������������������������������������������������������14
Thomas Kenner
AEOLIAN CROSS-SPECTRAL COSMIC COHERENCE ENTERS MEDICINE BY GLOCAL VASCULAR
VARIABILITY MONITORING��������������������������������������������������������������������������������������������������������������������������22
Franz Halberg, Germaine Cornélissen, Larry A. Beaty, Dewayne Hillman, Shiyu Hong, Othild Schwartzkopff,
Yoshihiko Watanabe, Kuniaki Otsuka, Jarmila Siegelová
PHYSICAL THERAPY (PT) CONCERNS IN THE USA COULD LEAD TO PREHABILITATION
COMPLEMENTING REHABILITATION ��������������������������������������������������������������������������������������������������������94
Othild Schwartzkopff, Germaine Cornelissen, Franz Halberg
INTERNATIONAL PROJECTS “WOMB TO TOMB” AND “BIOCOS (BIOSPHERE
AND THE COSMOS)” IN HALBERG CHRONOBIOLOGY CENTER, MINNESOTA:
GERMAINE CORNELISSEN����������������������������������������������������������������������������������������������������������������������������96
Jarmila Siegelova
CLINICAL APPLICATION OF CARDIO-ANKLE VASCULAR INDEX (CAVI)
AS A MARKER OF ARTERIAL WALL STIFFNESS������������������������������������������������������������������������������������114
Kohji Shirai, Norio Sato
CIGARETTE SMOKING AND THE CARDIO-ANKLE VASCULAR INDEX (CAVI)
OF ARTERIAL STIFFNESS: A REPORT FROM CZECH POPULATION DATASET��������������������������������119
Petr Dobsak, Vladimir Soska, Ondrej Sochor, Michaela Frantisova, Vlastimil Racek, Pavel Homolka, Pavel Vank,
Michaela Sosikova, Ladislav Dusek L., Jiri Jarkovsky, Marie Novakova, Jarmila Siegelova
DAY-TO-DAY VARIABILITY OF 24-HOUR MEAN BLOOD PRESSURE IN MAN:
SEVEN-DAY AMBULATORY BLOOD PRESSURE MONITORING�����������������������������������������������������������124
Jarmila Siegelova, Alena Havelkova, Michal Pohanka, Jiri Dusek, Leona Dunklerova, Petr Dobsak,
Germaine Cornelissen, Franz Halberg
SEVEN-DAY AMBULATORY BLOOD PRESSURE MONITORING:
BLOOD PRESSURE VARIABILITY AT REST AND DURING EXERCISE �����������������������������������������������128
Jarmila Siegelova, Alena Havelkova, Jiri Dusek, Michal Pohanka, Leona Dunklerova, Pavel Vank, Petr Dobsak,
Germaine Cornelissen, Franz Halberg
FATHER OF CHRONOBIOLOGY:
PROF. DR. FRANZ HALBERG, 93 YEARS OF AGE������������������������������������������������������������������������������������137
Jarmila Siegelova
DYSPHAGIA AFTER STROKE�����������������������������������������������������������������������������������������������������������������������139
Petr Konecny, Milan Elfmark, Stanislav Horak, Jarmila Siegelova, Petr Dobsak, Tomas Kadlcik,
Marcela Charvatova, Jarmila Skotakova
AD MULTOS ANNOS SANOS PROF. MUDR. JARMILA SIEGELOVA, DRSC.�����������������������������������������142
Franz  Halberg, Germaine Cornelissen, Othild Schwartzkopff
SUN’S AND EARTH’S MAGNETISM:
FEATURES OF COMMUNICABLE DISEASE ETIOLOGY��������������������������������������������������������������������������144
Franz Halberg, Shiyu Hong, Lyazzat Gumarova, Germaine Cornélissen
CELEBRATION OF A LIFETIME’S ACHIEVEMENTS IN CARDIOVASCULAR CHRONOMICS.
A TRIBUTE TO FRANZ HALBERG ON THE OCCASION OF HIS 93RD
BIRTHDAY��������������������������������148
Germaine Cornelissen
WHAT IS THE BEST TIME TO EXERCISE?������������������������������������������������������������������������������������������������163
R. B. Singh, Franz Halberg, Jarmila Siegelova, Germaine Cornelissen
CHRONOMIC CLOUD SYSTEM FOR CHRONORISK-INTERPRETED
AMBULATORY BLOOD PRESSURE MONITORING (C-ABPM)?�������������������������������������������������������������165
Yinjing Guo, Germaine Cornelissen, Bing Wu, Larry A. Beaty, Chris Adams, El ­Nolley, Jinyi Wu, Franz Halberg
5
NONINVASIVE METHODS IN CARDIOLOGY 2012
PROF. DR. THOMAS KENNER, 80 YEARS OF AGE
JARMILA SIEGELOVA
Dept. of Physiotherapy and Rehabilitation, Dept. of Sportsmedicine and Rehabilitation,
Faculty of Medicine, Masaryk University, St. Ann’s University Hospital in Brno
Prof. Dr. Thomas Kenner, M.D., Dr. h.c. mult.
Dr. h. c. Universität Jena, 1990
Dr. h. c., Semmelweis University Budapest, 1998
Dr. h. c., Masaryk Universiy Brno, 2000
Prof. Thomas Kenner is exceptional physiologist who focused primarily on physiology of cardiovascular system,
covering diverse areas such as aerodynamic properties of arteries, chronobiology of cardiovascular system, pathophysiology
and incidence of sudden infant death syndrome, physiology and monitoring of physiological functions in
space.
Prof. Thomas Kenner was born in Vienna 29. 9. 1932. He studied medicine at University of Vienna, where he qualified
in 1956. From 1956 to 1958 he worked in Dept. of Internal Medicine in Vienna. In 1959 he worked in Max Plank-Institut
in Bad Nauheim in Germany. From 1959 to 1965 he was back to Vienna and worked in the Dept. of Experimental
Pathology. Since 1963 he is married to Brigitte Hackl and has three children: Bernhard, born 1964, Lukas, born
1965 and Clara, born 1967. In 1965 he started work in Dept. of Physiology in Erlangen, Germany, where he began
with University lectures in Physiology, and in 1966 was appointed lecturer in Physiology (habilitation). He continued
researching in cardiovascular physiology and from 1967 to 1968 he was a Visiting Scientist in Presbyterian Hospital
in Philadelphia and Division of Biomedical Engineering, University of Virginia, and from 1969 to 1971 he worked
as Associate Professor, Division of Biomedical Engineering, University of Virginia in Charlottesville, Virginia, USA.
In 1971 Prof. Thomas Kenner was nominated for and got „Career Development Award“ (NIH). In 1972 he was appointed
full-time Professor and Chairman of the “Physiologisches Institut der Universität Graz”. He worked as the
head of the Dept. of Physiology until 2000, and in October 2000 he retired as Professor Emeritus of Karl-FranzensUniversität,
Graz, Austria.
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NONINVASIVE METHODS IN CARDIOLOGY 2012
It is very difficult to describe the outstanding scientific, educational and organizational activities of Prof. Thomas
Kenner in physiology. The Dept. of Physiology under his guidance flourished and attracted many researchers from
different countries. His outstanding capabilities to carry out physiological experiments were were presented and
published particularly in the area of cardiovascular physiology and cardiovascular pathology and in clinical disciplines,
where his students continued in the experimental scientific work.
From 1989 to 1991 he was nominated Rektor (President) of Karl-Franzens-Universität and from 1991 to 1997 Dean
of Medical School of Karl-Franzens-Universität, Graz, Austria. In this period a new building for theoretical Departments
of Medical Faculty of Karl-Franzens-Universität was constructed in Graz under his administrative guidance.
His cooperation with other universities in Austria and abroad was renowned internationally, he collaborated with
scientific groups from around the world, particularly in the USA and in European countries. Prof. Thomas Kenner
won many honors and was member of scientific societies - Austrian Academy of Sciences, Academia Scientiarum et
Artium Europaea, American Physiological Society, Cardiovascular Systems Dynamics Society, Deutsche Physiologische
Gesellschaft, and Honorary Member of the Hungarian Physiological Society etc. He was nominated Professor
honoris causa, University Ljubljana, Slovenia. In1993 he was honored from the Country Styria with “Großes
Goldenes Ehrenzeichen des Landes Steiermark”.
Prof. Thomas Kenner held many scientific positions, from 1978 to 1981 he was Member of the Life Science Working
Group of the European Space Agency (ESA, Paris),
from 1980 to 1987 he was Referee for Medicine in the “Kuratorium of the Austrian Research Fund (FWF)”, from
1986 to 1988 he was President of “Cardiovascular System Dynamics Society”, from 1985 to 1997 “Curriculum Dean
of Medical School of University Graz, Austria”. Prof. Thomas Kenner was nominated because of his exceptional scientific
work and international cooperation Dr. honoris causa in Germany at “Universität Jena” (1990), in Hungary
from Semmelweis University Budapest (1998), in the Czech Republic from Masaryk University Brno (2000).
Prof. Thomas Kenner cooperation with Faculty of Medicine, Masaryk University, Brno, Czech Republic started in
1991. Prof. Thomas Kenner was known in our University as a scientist from the publication about the dynamic of
arterial pulses from the year 1968. We met personally for the first time in Prague in 1991 on International Physiological
Congress, he was also accompanied by his wife Brigitte Kenner. Then he went to Masaryk University and at
the meeting we signed an agreement of cooperation and since this time we were meeting every year once or twice in
Brno, where we organized every year one Symposium about Chronobiology at Faculty of Medicine and one Symposium
during Medical Trade Fair in Brno. Usually we presented latest scientific discoveries together with Prof Thomas
Kenner, Austria, Prof. Franz Halberg, Prof. Germaine Cornelissen, both USA, Prof. Jean-Paul Martineaud, Paris,
France and Brno team – Prof. Bohumil Fiser, Dr. Jiri Dusek and me. Sometimes Prof. Thomas Kenner, everytime
accompanied by his wife, took also with him his pupils to Brno who presented at Masaryk University their scientific
lectures. Prof. Thomas Kenner published some lectures in the journal Scripta Medica and they are included in selected
publications. Brno chronobiological team visited also some scientific meetings in Graz and presented results
in the area of cardiovascular control in man in health and diseases in Austria.
In 2012, Prof. Thomas Kenner continues his scientific activities, he actively participates in meetings across the world
and publishes scientific papers. We are very glad and appreciate very much the long lasting cooperation with Prof.
Thomas Kenner. Especially we esteem his friendship and collaboration, his enthusiasm and large scientific knowledge,
which are all the time an inspiration for advancing the knowledge of cardiovascular physiology in health and
pathology. We have a privilege to have him in Masaryk University as a visiting professor and we wish him many
happy returns at the occasion of his anniversary of eighty years.
Ad multos Annos!
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NONINVASIVE METHODS IN CARDIOLOGY 2012
SELECTED PUBLICATIONS
1.	 Kenner T: Neue Gesichtspunkte und Experimente zur Beschreibung und Messung der Arterienelastizität. Arch.
Kreislauff. 54: 68–139 (1967)
2.	 Wetterer E, Kenner T: Grundlagen der Dynamik des arteriellen Pulses. Springer-Verlag, Berlin-HeidelbergNew
York (1968)
3.	 Kenner T, Busse R, Hinghofer-Szalkay H (eds): Cardiovascular System Dynamics, Models and Measurements.
Plenum Press, New York – London 1982
4.	 Kenner T: Small arteries and the interaction with the cardiovascular system. In: Rodkiewicz CM (ed) “Arteries
and the Arterial Blood Flow”, Springer Verlag, Berlin – Heidelberg (1983)
5.	 Kenner T: Dynamik arterieller Pulse. In: F Unger (eds) “Herzerkrankungen und Interventionsmöglichkeiten”,
pp. 105–124, Springer-Verlag Berlin Heidelberg 1998
6.	 Kenner T: Physiology of Circulation. In: Dalla Volta S et al. (eds) “Cardiology”, pp.15–25 McGraw-Hill Clinical
Medicine Series 1999
7.	 Halberg F, Kenner T, Fiser B, Siegelova (eds): Chronobiology and non-invasive methods in cardiology. Faculty
of Medicine, Masaryk University Brno (1999)
8.	 Kenner T: Introduction to the physiology of the circulation of blood. pp. 1–25, In: Verdonck P and Perktold K
(eds): Intra- and extracorporeal fluid dynamics. WIT-Press, Southampton, Boston, 2000
9.	 Kenner T: Medizin und Tiere. In: Goltschnigg DB, Müller-Kampel (ed): „Die Katze des Propheten“, pp. ­107–115,
Passagen Verlag, Wien, 2002
10.	 Proceedings of the 1st
Int.Fair of med.Technology and Pharmacy. Brno: Eds T. Kenner, J.P. Martineaud, P. Mayer,
B. Semrád, J. Siegelová, B. Fišer. 1993
11.	 Halberg F, Kenner T, Fiser B, Siegelova J(eds): Faculty of Medicine, Masaryk University, Brno (1996)
12.	Halberg F, Kenner T, Fiser B, Siegelova J(eds): Chronobiology and non-invasive methods in cardiology. Brno:
IDV PZ, MU, 1999. ISBN 80-7013-279-5. Faculty of Medicine, Masaryk University, Brno (1999)
13.	Halberg F, Kenner T, Fiser B (eds): The importance of chronobiology in diagnosis and therapy of internal diseases.
Faculty of Medicine, Masaryk University, Brno (2002)
14.	Halberg F, Kenner T, Siegelova J (eds): The importance of chronobiology in diagnosis and therapy of internal
diseases. Faculty of Medicine, Masaryk University, Brno (2003)
15.	 Cornelissen G, Kenner T, Fiser B, Siegelova J (eds): Chronobiology in medicine. Faculty of Medicine, Masaryk
University, Brno (2004)
16.	Halberg F, Kenner T, Fiser B, Siegelova J (eds): Nonivasive methods in cardiology 2006; Faculty of Medicine,
Masaryk University, Brno (2006)
17.	 Halberg F, Kenner T, Fiser B, Siegelova J (eds): Nonivasive methods in cardiology 2007; Faculty of Medicine,
Masaryk University, Brno (2007)
18.	Halberg F, Kenner T, Fiser B, Siegelova J (eds): Nonivasive methods in cardiology 2008; Faculty of Medicine,
Masaryk University, Brno (2008)
19.	 Halberg F, Kenner T, Fiser B, Siegelova J (eds): Nonivasive methods in cardiology 2009; Faculty of Medicine,
Masaryk University, Brno (2009)
20.	Halberg F, Kenner T, Fiser B, Siegelova J(eds): Nonivasive methods in cardiology 2010; Faculty of Medicine,
Masaryk University, Brno (2010)
21.	 Halberg F, Kenner T, Siegelova J (eds): Nonivasive methods in cardiology 2011; Faculty of Medicine, Masaryk
University, Brno (2011)
22.	Kenner, T., Moser, M. Systems physiology and chronobiology and their relation to music (2010) Scripta Medica
Facultatis Medicae Universitatis Brunensis Masarykianae, 83 (1), pp. 33–37. http://www.scopus.com/inward/
record.url?eid=2-s2.0-77953844777&partnerID=40&md5=816ec4ce022dccc97a55ff36393c18d7 DOCUMENT
TYPE: Short SurveySOURCE: Scopus
23.	Kenner, T. The evaluation of arterial pulses, role and clinical importance (2008) Scripta Medica Facultatis
­Medicae Universitatis Brunensis Masarykianae, 81 (3), pp. 131–140. http://www.scopus.com/inward/record.
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NONINVASIVE METHODS IN CARDIOLOGY 2012
url?eid=2s2.064949125914&partnerID=40&md5=afe9ab068f5f6447d03ef788a8f56aabDOCUMENT TYPE:
Article SOURCE: Scopus
24.	Moser, M., Frühwirth, M., Kenner, T. The symphony of life (2008) IEEE Engineering in Medicine and Biology
Magazine, 27 (1), pp. 29–37. Cited 5times.http://www.scopus.com/inward/record.url?eid=2-s2.038549135455
&partnerID=40&md5=a6c90fe91cb68b5abf5d220b08a0a51cDOCUMENT TYPE: ArticleSOURCE: Scopus
25.	Kenner, T. The significance of oscillations in scaling, ageing, and biological time(2007) Scripta Medica Facultatis
Medicae Universitatis Brunensis Masarykianae, 80 (4), pp. 167–174. http://www.scopus.com/inward/
record.url?eid=2-s2.0-62649124655&partnerID=40&md5=5742a1903e64ec654e6f5881d74fd316DOCUME
NT TYPE: ArticleSOURCE: Scopus
26.	Kenner, T. An observation on chronopathology of peptic ulcer revisited(2006) Scripta Medica Facultatis Medicae
Universitatis Brunensis Masarykianae, 79 (3), pp. 155–162. http://www.scopus.com/inward/record.
url?eid=2-s2.0-33947722719&partnerID=40&md5=1615be9e937ea0710a736a8966851543DOCUMENT
TYPE: ArticleSOURCE: Scopus
27.	 Kenner, T. Reform and remodeling of the university as a complex living system(2004) Scripta Medica ­Facultatis
Medicae Universitatis Brunensis Masarykianae, 77 (5–6), pp. 247–254. http://www.scopus.com/inward/
record.url?eid=2-s2.0-21244452270&partnerID=40&md5=c82006554bb652687a1deb13beaa9fcaDOCUME
NT TYPE: ArticleSOURCE: Scopus
28.	Kenner, T., Cornélissen, G., Katinas, G., Schwartzkopff, O., Kenner, B., Halberg, F.Population cycle in sudden
infant death syndrome (SIDS)?(2003) Neuroendocrinology Letters, 24 (SUPPL. 1), pp. 96–100. Cited 1 time.
http://www.scopus.com/inward/record.url?eid=2-s2.0-0242577751&partnerID=40&md5=38587f8baf75e406
14e6c0980892310dDOCUMENT TYPE: ArticleSOURCE: Scopus
29.	Kenner, T. Structural asymmetry and the optimisation of transport function in the circulation. Review 2002)
Scripta Medica Facultatis Medicae Universitatis Brunensis Masarykianae, 75 (2), pp. 81–86. Cited 3 times.
http://www.scopus.com/inward/record.url?eid=2-s2.0-0036072621&partnerID=40&md5=480e84c8a6fdecf
6c093c25a2bc06dacDOCUMENT TYPE: Review SOURCE: Scopus
30.	 Siegelová, J., Kenner, T. The 2000 symposium on non-invasive diagnostic methods in kardiology (2002) Scripta
Medica Facultatis Medicae Universitatis Brunensis Masarykianae, 75 (2), pp. 69–70.http://www.scopus.
com/inward/record.url?eid=2-s2.0-0036072699&partnerID=40&md5=265c2df44f98e16e44ecba184632ac75
DOCUMENT TYPE: Conference PaperSOURCE: Scopus
31.	Kenner, T., Kenner, L. Risk factors, protective factors and medical decisions (2001) Scripta Medica Facultatis
Medicae Universitatis Brunensis Masarykianae, 74 (1), pp. 5–10. http://www.scopus.com/inward/record.
url?eid=2-s2.0-0035184775&partnerID=40&md5=1a12eefed3756d1ea71f20b4f227e58f DOCUMENT TYPE:
Review SOURCE: Scopus
32.	 Kenner, T., Moser, M., Tanev, I., Ono, K. The Liebau-effect or on the optimal use of energy for the circulation of
blood (2000) Scripta Medica Facultatis Medicae Universitatis Brunensis Masarykianae, 73 (1), pp. 9–14. Cited
13 times.http://www.scopus.com/inward/record.url?eid=2-s2.0-0033760074&partnerID=40&md5=d166e25
7339c48b35c3c1030d1e0c784 DOCUMENT TYPE: Article SOURCE: Scopus
33.	 Gallash, E., Kenner, T. Microvibrations: An interrelation between heart beat, muscle tremor and resting muscle
tone (1998) Scripta Medica Facultatis Medicae Universitatis Brunensis Masarykianae, 71 (4), pp. 165–169. Cited
1 time. http://www.scopus.com/inward/record.url?eid=2-s2.0-0032438267&partnerID=40&md5=54f6652
4137fac3db072c9ffa88c71f7 DOCUMENT TYPE: Conference Paper SOURCE: Scopus
34.	 Muhry, F., Moser, M., Kenner, T. Weak health indicators. Their meaning and their time course during rehabilitation
(1997) Scripta Medica Facultatis Medicae Universitatis Brunensis Masarykianae, 70 (4–5), pp. 183–185.
http://www.scopus.com/inward/record.url?eid=2-s2.0-0031452470&partnerID=40&md5=2d34464d5e01a9
95e693b091c6ca3aaf DOCUMENT TYPE: Conference Paper SOURCE: Scopus
35.	Niederl, T., Kenner, T. Optimization of cardiac function (1997) Scripta Medica Facultatis Medicae Universitatis
Brunensis Masarykianae, 70 (4–5), pp. 187–189. http://www.scopus.com/inward/record.url?eid=2-s2.0-
0031466922&partnerID=40&md5=dc67c59336ed0e86d01ea8f1ea1ab34a DOCUMENT TYPE: Conference
Paper SOURCE: Scopus
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NONINVASIVE METHODS IN CARDIOLOGY 2012
THE FUNCTIONAL EFFECT OF TIME-DELAYS IN
CHRONOBIOLOGY AND CHRONOPATHOLOGY
THOMAS KENNER
Physiologisches Institut of the Medical University Graz, Austria
Dedicated to Prof. Dr. Jarmila Siegelova on the occasion of her 70th
birthday.
SUMMARY
The field of chronobiology mainly is concerned with rhythms of different frequency, like circadian, circaseptan, circannual
etc. (1). Although most periodic events are composed of periods of activity and periods of rest, or of periods
of higher and lower activity, it appears that the term delay was so far, until recently, not yet of particular interest.
There are two reasons why a short introduction to the chronobiological and chronopathological aspects of delay appear
to be of interest.
The first reason is the fact that a team at the University of Virginia in Charlottesville performed experiments to study
the effect of a delay in the control loop of the blood pressure control. The theoretical background of a systems description
was worked out and published in 1971 (2). The results of our experiments were published in 1974 (3). These
experiments demonstrated, that a delay in the control loop generates instability of the blood pressure in the form
of periodic auto-oscillations. An early experiment concerning the control system of the blood pressure control was
performed by Hatakeyama (4). He studied effects of the stimulation of the carotid sinus nerves. Already somewhat
earlier Guyton and coworkers (5) studied the generation of the so called Cheyne-Stokes respiration, a characteristic
form of periodic oscillations of the breathing movements, which is typical for severe cardiac failure. Cheyne-Stokes
respiration can also be observed in persons in high altitude, who are not adequately adapted to this situation.
These studies were not yet appropriately recognized. However, the fact must be mentioned, that recently the problem
of delay appears to arise more and more interest (6). As usual, results of early studies can now be reproduced with
more sophisticated techniques.
A further reason for discussing delay comes from the fact, that this phenomenon plays a role in many fields, like biology,
social science, economic science and in many other aspects.
In other words: Delays play an enormous role in chronobiology, chronopathology, in every-day medicine, in everyday
life, in society, in economics, politics and in all fields, which have something to do with time.
THE WORD DELAY
The word delay comes from Latin: the first part of the word is derived from de, indicating moving away “from”; then
added the word laxare: “to make something loose”, or “to extend something” (7).
One can add the following interpretation: The word DELAY can indicate a neutral, or a rather negative or even a more
positive meaning:
•	 Postponement
•		Detainment (being delayed)
•	 Recovery – Rehabilitation
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NONINVASIVE METHODS IN CARDIOLOGY 2012
It is of interest, that the term delay is best understood in music. Many of the terms and signs which determine the
speed of performance actually determine delays: pause, ritardando, etc.
SINGULAR OR PERIODIC DELAYS IN BIOLOGICAL SYSTEMS
Delay may be a singular phenomenon like the waiting period for the belated arrival of a train or of some person. In
medicine, the incubation period means the delay after an infection until the outbreak of symptoms of a certain infection.
From the viewpoint of chronobiology or chronopathology the processes, which are going on in an organism
during the incubation period are of interest.
EXAMPLE: MITOSIS
As an important example from biology, the process of mitosis, which includes several characteristic delay-periods,
can be mentioned (8).
The mitosis starts with the duplication of the chromosomes. After some further delay the chromosomes separate.
Finally, the two completely separated daughter cells can be observed.
The further processes – including a resting stage of each daughter cell – depend on the type of cells. In tumor cells,
only a short delay may precede the next mitoses. In other types of cells the state of rest may be very long or even permanent.
There are indications that cellular cycles are influenced by the main biological clock in the hypothalamus.
Another example is the pacemaker mechanism, which generates the – usually periodic – cycle of excitation and contraction
of the cardiac muscle. Similar mechanisms can be found in nerve cells and nerve fibers.
The generation and timing of chronobiological rhythms is based on the sequence of the activity of clock genes and
the production and action of clock proteins.
SYNCHRONIZATION
In many examples of delay one can observe the phenomenon of synchronization. The synchronization of two periodic
processes requires slight delays in order to permit the adjustment of two or more processes. Synchronization
can be understood as the adjustment of two oscillators the frequencies of which are close, but can be forced to become
equal. The term which describes this narrowing locking of two frequencies are called Arnold tongues (9). It
can be shown that in fast growing tissues such synchronization among mitoses and also synchronization with other
periodic processes like the circadian rhythm can be observed (10).
INSTABILITY
Everybody is familiar with the phenomenon of positive feedback within the system: microphone – amplifier – loudspeaker.
If the location of microphone is too close to the loudspeaker then tremendous loud sound (of a certain frequency)
is produced.
Positive feedback may play a role in the generation of instability in certain neuro-muscular symptoms.
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NONINVASIVE METHODS IN CARDIOLOGY 2012
Here we discuss the generation of symptoms by delay in the negative feedback loop of a control system. Biological and
medical examples of interest are: the control systems for the regulation of certain functions, including breathing,
blood gases and pH of blood and, finally the control system for the regulation of arterial blood pressure.
INSTABILITY OF BREATHING
Guyton and his coworkers (5) were the first in 1956 to study experimentally the possible generation of instability
of the control system for the regulation of breathing. They performed experiments in dogs in order to observe the
generation of periodic Cheyne-Stokes respiration, which appeared to be a sign of instability. It was assumed, if the
sensors in the carotid bodies and in the brain stem receive the information about pH and pO2
in the arterial blood
not on time but only after a marked delay of time, then the respiration starts to oscillate with a typical periodicity. In
their summary (5) they write: “The periodic breathing was induced by inserting a circulatory delay system between
the heart and the brain to prolong the transit time of blood from the lungs to the brain. The duration of each cycle of
Cheyne-Stokes breathing increased proportionately with the volume of the delay system…” The figures in the cited
publication by Guyton and coworkers (5) show the time course of the ventilation in a dog with a delay circuit. Periods
of hyperventilation are followed by periods of apnea. The time-period of these oscillations as measured from the time
between the maxima of breathing amplitudes ranges between 5 and 6 min.
As already mentioned, also in the paper by Guyton and coworkers (5), the so called Cheyne-Stokes respiration can
also be observed in patients with cardiac failure. This fact indicates, that in this pathological condition the blood flow
velocity is markedly reduced.
INSTABILITY OF BLOOD PRESSURE
Hatakeyama (4) published 1967 experiments performed in rabbits. He examined the reaction of the blood pressure
control system indirectly by stimulation of the carotid sinus nerve. The stimulation of the nerve was adjusted in such
a way as to correspond to the estimated reaction of the carotid sinus nerve in response to the direct stimulation of
the carotid sinus by blood pressure. Using this indirect technique he observed, that the pressure response to delayed
sinus nerve stimulation produced blood pressure oscillations.
In 1974 Kenner and Coworkers (3) published experiments, which demonstrated the generation of instability and
auto-oscillations of the blood pressure by time delay in the blood pressure control system of dogs by using a direct
pressure related procedure. In our experiments the carotid sinus nerves stayed intact and were not touched.
The procedure of our experiments is described as follows: “Both carotid arteries of anesthetized mongrel dogs were
perfused with arterial blood by a servo controlled peristaltic pump. By applying a hybrid computer system to control
the perfusion pump, the preparation could be examined under open loop condition and also under closed loop condition.
Particularly, the effect of an artificial time delay (1–35 sec) between systemic and carotid sinus pressure was
tested. The systemic blood pressure was recorded in the carotid artery close to the aorta. The data were stored in a
computer, which was programmed to control a perfusion pump. The blood then was pumped by the servo-controlled
pump into the distal part of the carotid arteries where the carotid sinus receptors are located. It was observed, that
this procedure generates auto-oscillations of the arterial pressure as soon as the pump action and the blood pressure
in the carotid sinus is delayed behind the actual blood pressure. The period of the oscillations is proportional to the
artificial time delay.
The following picture demonstrates the described relation between the time of delay and the period of auto-oscillations.
It can be seen that there is a linear relation between these time periods.
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NONINVASIVE METHODS IN CARDIOLOGY 2012
Figure 1. shows the relationship between the period of the auto-oscillations and the chosen time
delay. The predicted curves were calculated from open loop data. (Kenner et al. 1974).
TIME AND DELAY AND THEIR ROLE IN ECONOMICS, FIGHT,
AGGRESSIVITY
One example, which opens the understanding to further problems of zoology, psychology, epidemiology, population
growth and social science, is the model of “predator and prey”. Oscillations of the two populations are generated:
at first by the reduction of the number of pray through the activity of the predators. Consequently, the number of
predators begins to decrease as a consequence of the reduction of the number of pray. The described process finally
leads to a decrease of the number of predators, which in turn gives rise to the generation of more and more individuals
of prey. So, the process starts again, as described above. It follows a repetition of periodic cycles, which can
be described by the so called Volterra-Lotka equations. In this example of periodic oscillations, one component of
delaycan be attributed to the time periods, which are determined by the development – the rise and the fall – of the
two involved populations.
Delay and “bureaucratic character” as described by Erich FROMM (11):
The following sentences by Erich Fromm show one further problem,
which can be attributed to the term “delay”. Unfortunately, in our
time of growing bureaucracy, such events can by observed quite often.
One could consider the bureaucrat in the post office; and one
could observe his small smiling when he – exactly at 5.30 p.m. – 
closes his office. Consequently, two persons, who were already
waiting for half an hour, had to leave. They will have to come
again next day.
For this “bureaucrat” it is not important that he closes his office
exactly on time – at 5.30 p.m. – but it is his joy to frustrate the
two persons by showing them that he has them under control.”
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NONINVASIVE METHODS IN CARDIOLOGY 2012
REFERENCES
1.	 Halberg F.: Chronobiology. Ann. Rev. Physiol. 31, 675–725 (1969)
2.	 Kenner T. Dynamic control of flow and pressure in the circulation. Kybernetik 9, 215–225 (1971)
3.	 Kenner T. Baertschi A.J. Allison J.L. Ono K.: Amplitude Dependence of The Carotid Sinus Reflex. Pflügers
Arch. 346, 49–59 (1973)
4.	 Hatakeyama I.: Analysis of baroreceptor control of the circulation. In: E.B. Reeve and A.C. Guyton (eds.)
­Physical basis of circulatory transport. p. 91–120. W.B.Saunders, Philadelphia-London (1967)
5.	 Guyton C.G. Crowell J.W. Moore J.W.: Basic Oscillating Mechanism of Cheyne-Stokes Breathing. Amer. J. Physiology
187, 3495–398 (1956)
6.	 Batzel JJ, Kappel F.: Time delay in physiological systems: analyzing and modeling its impact. Math. Biosci.
234(2), 61–74. Epub (2011 Sep 16.)
7.	 The American Heritage Dictionary of the English Language. 1969
8.	 Alberts B. et al.: Lehrbuch der Molekularen Zellbiologie. Wiley – (VCH 2005)
9.	 Pikovsky A. Rosenblum M. Kuhrts J.: Synchronization, A universal concept of nonlinear sciences. Cambridge
University Press (2003) p. 65–66
10.	 Jasser S.A., Blask D.F., Brainard G.C.: Light during darkness and cancer: relationships in circadian photoreception
and tumor biology. Cancer Causes Control 17, 515–523 (2006)
11.	Fromm E.: Anatomie der menschlichen Destruktivität. Aggressionstheorie, Gesamtausgabe Vol. VII (1980).
p. 268
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NONINVASIVE METHODS IN CARDIOLOGY 2012
CONTRIBUTIONS TO THE ANALYSIS AND
INTERPRETATION OF FORCES INFLUENCING
THE PRESSURE-FLOW-RELATION IN ARTERIES
THOMAS KENNER
Physiologisches Institut, Medical University Graz
PREFACE
Each one of the scientific meetings in Brno is a very special event. Not only the beautiful city and its surroundings, and the
friendly inhabitants have to be mentioned, but especially the interesting and stimulating presentations and discussions,
organized by Professor Jarmila Siegelova. I want to express here my sincere thanks to her and to her coworkers.
FIRST PART: A PERSONAL NOTE
The title of this presentation was chosen in order to indicate that I will try to present the development of ideas related
to arterial pulses throughout the time of my learning, when even old-fashioned techniques appeared to be useful.
Shortly after I became a newly promoted Medical Doctor, I worked in the department of Internal Medicine in a hospital
in Vienna. In this department I had unexpected possibilities to perform measurements in patients. In a nearly
unused room stood an X-ray recorder with a classical screen. Attached to this screen was a device which permitted to
focus the view to a certain location of a shadow on the screen, and thus to record movements of shadows, e.g., pulsations
of the heart or of the large arteries. The name of this device is “Elektrokymograph”. Today, due to the modern
development of computer tomography, this device is obsolete.
Figure 1. from Heckmann (1) 1952
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NONINVASIVE METHODS IN CARDIOLOGY 2012
Using this Elektrokymograph, it was obvious, that the pulsations of the pulmonary artery have different shapes in
healthy persons and in persons with pulmonary hypertension. Heckmann (1) 1952, Kenner (2) 1959. It also appeared
obvious that the shape of the observed pulses represent the pulmonary arterial pressure pulses. It could be concluded,
that the analysis of pulmonary arterial pulse shapes can indicate pathological modifications. See Figure 2.
A general description about modeling and analysis of arterial pulses can be found in the book “Grundlagen der Dynamik
des Arterienpulses” (3) 1968 and in Kenner (4) (1979).
Figure 2.
At the same time, by chance – I came in contact with R. Ronniger, who just had finished his doctors thesis on recording
and analyzing the transmission of arterial pressure pulses. Ronniger (5) 1954. In addition Ronniger (6) 1955
has analyzed and generalized earlier mathematical approaches to calculate the stroke volume from non-invasively
recorded arterial pressure pulses. The school of Otto Frank, including Wezler and Böger based their modeling on the
socalled Windkessel (air chamber) model.
Ronniger (5) used the transmission equations and the presentation of the pulse transmission in the arterial system
in the frequency domaine in then form of a Nyquist diagram. I had the opportunity, to work with him and learn from
him in this field.
From a historical viewpoint it is interesting, that already much earlier J. von Kries (7) (1889) had published a book in
which he proposed and explained the application of the transmission equations to describe the propagation of arterial
pulse waves. As mentioned above, the school of Otto Frank were successfully using Windkessel.
I had the opportunity to work with E. Wetterer in Munich. So I had the chance to study the transmission properties
of pressure pulses along elastic rubber tubes in different types of models. The results of our measurements were summarized
in our book Wetterer & Kenner (3) (1968).
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NONINVASIVE METHODS IN CARDIOLOGY 2012
Figure 3 (from Kenner (4) 1979) shows Nyquist diagrams calculated from arterial pressure pulses recorded in an
anesthetized cat. Left row: calculated for the assumption of an homogeneous elastic tube-model. Right row: estimated
from recordings from central and peripheral part of the aorta of a cat.
Figure 3.
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NONINVASIVE METHODS IN CARDIOLOGY 2012
With respect to the pulse wave velocity we have later compared the usual measurement at the front of the proximal
and distal pulse wave with a cross correlation technique.
Figure 4.
Figure 4 from Kenner (4) 1979 shows a comparison of the estimation of the transmission time (inverse of pulse wave
velocity) through cross correlation of central and peripheral pulse (CCF). For the calculation of the next line (CCFD)
the measured data were differentiated versus time (dp/dt) eliminating the effect of lower frequencies. The blood pressure
was varied by infusion of Noradrenaline (NA).
Later on, in the department of Physiology of the University Graz, the analysis was computerized and improved und
studied in anlmal experiments. At that time we had a very large laboratory computer.
Furthermore, as a development of fast evaluation, the following sequence of steps was programmed: 1. the first step
is the simultaneous record of a central and a distal pressure pulse. 2. the pair of simultaneous pulses is picked out.
The period is measured. 3. a fast Fourier analysis on the two pulses is performed; then the quotient of amplitudes
and the Phase difference are calculated. 4. the final step is the presentation of the resulting Nyquist diagram on the
screen. The procedure can be repeated continuously.
Unfortunately we have never tried further development – and especially clinical application. The following picture
from Wetterer and Pieper (8) 1953 shows an experiment in a dog. During different procedures, the pulse wave velocity
was measured. One can see, that the pressure dependence of pulse wave velocity is markedly influenced by different
procedures. R – resting condition, Vk – cooling of vagus nerve, Sy – injection of Sympatol. VKSy – some time
after Sympatol during Vagus cooling.
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NONINVASIVE METHODS IN CARDIOLOGY 2012
Figure 5.
It is remarkable, that the value of the pulse wave velocity does not only depend on the blood pressure, but also on the
influence of vasoactive effects.
During the time of my interest in arterial pulses and in the functional importance of arterial elasticity, it seems to me
that viewpoints changed markedly. Around the time of 1950, the measurement pulse wave velocity in a patient was
considered the result of some rather useless idea.
I enjoy the recent rise if interest. However, I am somewhat critical about the development of an industrial monopoly
of a diagnostic language. I am very curious to discuss this matter.
The following figure from the Japanese book by Professor Koichi ONO summarizes in a schematic manner the arrangement
of the control mechanisms acting on the cardiovascular system.
Figure 6.
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NONINVASIVE METHODS IN CARDIOLOGY 2012
REFERENCES – FIRST PART
1.	 Heckmann K.: Grundriss der Elektrokymographie. Stuttgart 1952
2.	 Kenner Th.: Über die elektrokymographische Pulskurve der Arteria Pulmonalis. Arch. Kreisl. Forsch. 29,
­268–290 (1959)
3.	 Wetterer E., Kenner T.: Grundlagen der Dynamik des Arterienpulses. Springer – Verlag Berlin. Heidelberg-New
York 1968
4.	 Kenner, Th.: Physical and mathematical modeling in cardiovascular systems. In: Hwang N.H.C., Gross D.R.,
Patel D.J. (eds.) Quantitative Cardiovascular Studies Clinical and Research > Applications of Engineering Principles.
University Park Press Baltimore (1979)
5.	 Ronniger R.: Über eine Methode der übersichtlichen Darstellung hämodynamischer Zusammenhänge. Arch.
Kreisl. -Forsch. 21: 127–160 (1954)
6.	 Ronniger H.: Zur Theorie der physikalischen Schlagvolumenbestimmung. Arch. Kreisl. -Forsch. 22: 332–373
(1955)
7.	 Kries, J. v.: Studien zur Pulslehre, Freiburg 1892
8.	 Wetterer E., Pieper H.: Messungen am Arteriensystem in vivo während erzwungener periodischer Volumenschwankungen.
Verh. Dtsch. Ges. Kreisl.-Forsch. 19, 259–264 (1953)
SECOND PART: INTRODUCTION
In the first part the description was focused on pressure pulse-pressure and on transmission of pressure pulses. In
the second part the relation between pressure and flow will be discussed. In the frequency domain the relation again
is shown in complex form as “impedance”.
The pressure – flow relation in the frequency region of heart rate and the higher harmonic frequencies can be called
“high frequency”. The “low frequency” region describes the effect of control mechanisms – baroreceptor loop and
autoregulation.
With my Japanese friend and coworker Koichi Ono we have participated on studies concerning pressure control and
local autoregulation.
During our presence in the Department of Biomedical engineering in Charlottesville, we performed and participated
in experiments on anesthetized dogs, where not only the pressure transmission, but also the pressure-flow relation
(impedance) was measured.
If one records pressure and flow at the entrance (= input) of the aorta, it can be seen that the peak flow preceeds the
peak pressure. From this observation one can conclude that the phase angles of the main part of the input-impedance
is negative region of the coordinate system. One example of a Nyquist-diagram of the input-impedance of the aorta
of a dog is shown in the following figure (next page), from Kenner 1972.
In the literture all the papers which are related to the discussed topics are listed. Furthermore, in addition, particularly
those in which my friend Koichi Ono and I have cooperated are listed.
The last cited paper – regarding heart rate variability and synchronization, will also be discussed in the
PPT-presentation.
This important extension of our work, the consideration of time in the sense of Chronobiology, brought many exchanges
of ideas with Franz HALBERG and our friends in BRNO.
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NONINVASIVE METHODS IN CARDIOLOGY 2012
One of the early ideas, as already mentioned was the observation of heart rate variability and sychronization between
respiration and heart beat. Right now it appears that, a as we think about synchronization, the more complex appears
the regulation of this process.
Figure 7.
Furthermore, I will mention my friend and mathematician Karl Perktold and a book which he co-edited with
P. ­Verdonck, with the title: “Intra- and extracorporeal Cardiovascular Fluid flow”. This book contains aspects which
seem worthwhile to be mentioned, and which have also a connection with observations by the late by pathologist
Doerr. concerning defects of the aorta,
REFERENCES – SECOND PART
1.	 Kenner T.: Flow and pressure in the arteries. Fung, Y.C., Perrone N. Anliker M. (eds) Biomechanics: its foundations
and objectives (1972). Prentice Hall, Inc., Englewood Cliffs, N.J.
2.	 Kenner, T. and Ono, K. (1971): The low frequency input impedance of the renal artery, Pflügers Arch 324: 155
3.	 Kenner, T. and Ono, K. (1971): Reciprocal autoregulation of blood flow and pressure, Experientia 27: 528
4.	 Kenner, T. and Ono, K. (1972): Interaction between circulatory control and druginduced reactions, Pflügers
Arch 331 335
5.	 Kenner, T. and Ono, K. (1972): Analysis of slow autooscillations of arterial flow, Pflügers Arch 331: 347
6.	 Kenner, T. and Ono, K. (1972): A nonlinear property of the renal autoregulation, Experientia 28: 527
7.	 Kenner, T. and Ono, K. (1972): Humoral autoregulation of blood flow and bloodpressure, Experientia 28: 528
8.	 Kenner, T., Rubenstein, J. and Ono, K. (1973): Pseudorandom testing technique for the characterization of local
hemodynamic control, Pflügers Arch 343: 309
9.	 Kenner, T., Baertschi, A., Allison, J. and Ono, K. (1974): Amplitude dependence of the carotid sinus reflex,
Pflügers Arch 346: 49
10.	 Ono, K., Uozumi, T. and Yoshimoto, C. (1979): A role of the carotid barostatic reflex in the hierarchical levels,
Pflügers Arch 379: 28
11.	 Ono, K., Uozumi, T., Y oshimoto, C. and Kenner, T. (1981): The optimal cardiovascular regulation of the arterial
blood pressure, Cardiovascular System Dynamics, Plenum Press
12.	Verdonck P., Perktold K.: Intra und extracorporeal cardiovascular fluid dynamics. WITpress Southampton,
Boston (2000)
13.	 Karner G., Perktold K., Zehetner H.P. Prosi M. Mass transport in large arteries and through the artery wall. In
Verdonk P. & Perktold K., pp. 209–247 (Fig. 9, p. 237)
14.	 Doerr W. Perfusionstheorie der Arteriosklerose. Georg Thieme Verlag Stuttgart 1963
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NONINVASIVE METHODS IN CARDIOLOGY 2012
15.	Kenner, T., Baertschi, A., Allison, J. and Ono, K. (1974): Amplitude dependence of the carotid sinus reflex,
Pflügers Arch 346: 49
16.	 Kenner, Th., Pessenhofer, H., and Schwaberger, G. 1976. Method for the analysis of the entrainment between
heart rate and ventilation rate. Pflügers Arch. 363: 263–265
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NONINVASIVE METHODS IN CARDIOLOGY 2012
AEOLIAN CROSS-SPECTRAL COSMIC COHERENCE ENTERS
MEDICINE BY GLOCAL VASCULAR VARIABILITY MONITORING
FRANZ HALBERG1
, GERMAINE CORNÉLISSEN1
, LARRY A. BEATY2
, DEWAYNE HILLMAN1
, SHIYU
HONG1
, OTHILD SCHWARTZKOPFF1
, YOSHIHIKO WATANABE3
, KUNIAKI OTSUKA3
,
JARMILA SIEGELOVÁ4
1
Halberg Chronobiology Center, University of Minnesota, Minneapolis, MN, USA
2
Phoenix Study Group, IEEE, Minneapolis, MN, USA
3
Tokyo Women’s Medical University, Medical Center East, Tokyo, Japan
4
Masaryk University, Brno, Czech Republic
ABSTRACT
Health care already changes with emphasis on wellness by recommendations for exercise and a proper lifestyle, notably
diet. The effect of these recommendations is not yet assessed in the individual involved, except for the taking
of vital signs or at least of a blood pressure (BP) measurement, e.g., before each exercise session, as is also the case
in any physical examination. Moreover, exercise, like meals, is implemented at times chosen by convenience, not
necessarily pertinence, without concern for the possibility of doing harm to oneself. Hence the next step is the detection
of the earliest unwellness, which occurs in the normal range where “physiological” is now equated with “random”.
Therein, masked for homeostatic thought, lies a new diagnostic and therapeutic realm which can be opened
by chronobiologically-interpreted automatic ambulatory BP and heart rate (HR) monitoring (C-ABPM). C-ABPM is
of interest in itself for preventive cardiology, since it reveals new diagnoses as vascular variability anomalies (VVAs),
and renders old diagnoses made conventionally more reliable (as MESOR-hypertension, an elevation of the MidlineEstimating
Statistic Of Rhythm, based on around-the-clock data at least for 7 days and preferably continued until
death, as soon as affordable unobtrusive instrumentation is generally available). The recommendation for continuous
C-ABPM recognizes several principal, inseparably intertwined contributors to severe cardio- and cerebrovascular
disease (CVD), namely the genetics and effects of physical and mental loads upon them that are all best assessed
from womb to tomb. C-ABPM yields marker rhythms for vascular and/or other aspects of physiology, including mental
functions, and thus provides a quantifiable measure of stress, as a VVA. When a VVA persists in successive 7-day
records it becomes a Vascular Variability Disorder (VVD), as an index of strain. When several VVDs persist and accumulate,
they become a Vascular Variability Syndrome (VVS). The risk of a hard outcome within 6 years increased
from < 5 % to nearly 100 % in a study on 297 patients by Kuniaki Otsuka with hard outcomes. It had a confirmatory
follow-up on a much larger number of subjects with a proxy outcome of the left ventricular mass index (LVMI) and
was further in keeping with a study followed up for over 4 decades. Some VVDs can be treated, as another study and
case reports document. C-ABPM further reveals a new transdisciplinary spectrum with novel infradian (longer than
28-hour) components that contribute to sudden cardiac death, suicide, homicide, terrorism and war, as well as to
cycles in church membership and proselytism.
Those who regard the proposition of lifelong ABPM as utopian may realize that we can attach to our health the same
attention as we do for security on the road to the tires of our cars when we continuously measure their pressure. This
technological opportunity can be made available to our bodies as well as to our automobiles and laboratory animals
used for research. By lifelong monitoring, we also gain new objective quantifiable perspectives of how space weather
affects us and arrive at new diagnoses in a personalized, a societal and a still broader environmental medicine, that
in turn leads to a unified science. Beyond health care, we can start to think globally and act locally in space and can
also be “glocal” in time, both with a view of the historical cycles that mold us and in the practice of analyzing time
series, such as data from C-ABPM, with repeated passes over them as they accumulate both as a whole at a given time
(globally) and further in sections systematically varied in length (locally), with a view of the cycles that characterize
them. This requirement of glocality in concept and as an analytical method can be demonstrated, among others, by
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NONINVASIVE METHODS IN CARDIOLOGY 2012
the fruits of a glocally-analyzed C-ABPM, yielding a marker for the human mind as well as for the circulation. In so
doing, it reveals our intimate associations with our cosmos. In the language of frequencies, the odds ratio for the
number of periods shared by human mental function and geomagnetics more than matches that between the magnetisms
of the interplanetary field and the earth1
.
1.0 SELF-SURVEILLANCE
Insurance companies are too slowly starting to realize that the current costly, mainly physician-implemented health
service to the individual, mostly after the onset of disease, can be complemented by programs for “wellness” not
only by good advice and rewards (cost reduction) by those who follow the counsel, but also by an improved, largely
self-help-based care with ongoing surveillance and early actions whenever warranted, as needed for everyone. Immediately
available, worldwide on a small scale, is a cost-effective C-ABPM system around the clock at 30-minute
intervals at all ages, with free analyses from a project on The Biosphere and the Cosmos, BIOCOS (corne001@umn.
edu), to all comers. This project constitutes a validation test for an international website recommended by a World
Forum on “Natural Cataclysms and Global Problems of the Modern Civilization”, held 19–21 September 2011 in
Istanbul, Turkey (www.2011.geocataclysm.org) (1), in extending the scope of prior consensus conferences (e.g., 2–4;
see 3 for a partial list of earlier meetings advocating C-ABPM). Thus, responses to Sir William Osler’s wear and
tear, putative harbingers of severe disease (1–4), are detected as gauges of loads (4–8), prompting preventive action.
Eventually this task can be implemented on a large scale by an international multilingual analytical and educative
website (1, 4), Figure 1, on a larger than the currently ongoing small-scale albeit worldwide endeavor. With emphasis
on wellness that is checked so as to act when prevention is needed, we need no longer fly blind to the circadian and the
many other variabilities in us and around us, as soon as we have in this generation a computer-savvy family member
or friend, or can be assigned to such a person until a system is instituted where such a service can be offered freely,
such as in community libraries or pharmacies. In the next generation, everyone can be trained in self-monitoring in
earliest schooling (9).
2.0 WHAT CAN BE DONE TODAY
In a forthcoming book for the lay public, aimed to advise patients found to have a BP that is too high or too low,
a colleague asked the authors whether he could reproduce Figure 2, published in 1984 (10), as an example of interindividual
differences among 24-hour (h) profiles. At the time of the original publication, we had not yet formulated
VVAs or VVDs, Figure 3, that are not generally known, a long series of consensus meetings notwithstanding (1–4)
and of course had no reference values for them. Mostly not implemented is the detection of circadian and about
(~) 7-day (circaseptan) BP periodicities, documented over a century ago that is immediately available for diagnostic
and therapeutic use in 2012. As to diagnosis, let us start by asking: Who in Figure 2 is at the greater risk of a cerebral
stroke or other severe cardiovascular disease? The important answer, contrary to current worldwide practice, is: We
can’t tell, the record is too short. We need a 7-day record as a start and must continue to monitor if it shows abnormality,
Figure 4.
In looking at Figure 2 in 2012, some readers who rely on current official guidelines (11) may infer that CH, the
60-year-old man, had a larger swing in BP and may be the healthier of the two. Many more may recognize CH, the
subject whose data are shown on the left of Figure 2, as an excessive dipper, a very common diagnosis based on
a single 24-h profile, associated with undesirable outcomes, on a population basis (12–15). This majority in turn
should not only question a record length of 24 h as a basis of a diagnosis (5, 16–18), Figure 2, but can compare the
1	 See definitions at the end, best viewed first.
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NONINVASIVE METHODS IN CARDIOLOGY 2012
utility of a classification of dipping with the chronobiologic diagnosis, i.a., of a circadian overswing, CHAT (short for
Circadian Hyper-Amplitude-Tension) (19; cf. 4), Figure 3, associated with a high risk of stroke, Figures 5A–C (4). It
must be realized that a diagnosis based on the single measurement of BP, Figure 6A–C, like that relying on a single
24-h record, as in the case of Figure 2 and others, is a spotcheck rather than a platinum standard, Figure 7 (2).
2.1 HISTORY SHOWS URGENCY AND FEASIBILITY OF LIFELONG
MONITORING, STARTING AT THE DIAGNOSIS OF BP ABNORMALITY 2
In 1904, Theodore C. Janeway of Johns Hopkins University (20), then the opinion leader, did not wish to see a patient
before collecting sufficient data to assess periodicities. (The plural was justified since by 1880 and 1881 Ignaz Zadek
in Berlin had collected sufficiently long time series to document 24-h, 84-h and 168-h rhythms, Figure 8 [21, 22].) In
1974, Frederic C. Bartter, of Bartter syndrome fame, then head of the Hypertension-Endocrine Branch at the U.S.
National Institutes of Health (NIH), and later the director of the Clinical Center at the NIH3
, recognized that the reason
why his patient was diagnosed differently by two physicians who saw him at different times of day stemmed from
circadian changes in BP, Figure 9A. His foresight was later illustrated in the abstract (Figure 9B), with additional
evidence accumulating since the availability of automatic BP monitoring, Figure 9C.
Frederic C. Bartter reached the following conclusion after having his patient studied in the clinical center (23; cf. 24):
“By conventional standards, this patient is clearly normotensive every morning. Yet the BP determined each day at
6 in the afternoon provides especially convincing evidence that this patient is a hypertensive. … My plea today [in
1974!] is that information contained in such curves [cosinor fits; see Figures 2 and 3: our addition] become a routine
minimal amount of information accepted for the description of a patient’s blood pressure. The analysis of this information
by cosinor should become a routine. It is essential that enough information be collected to allow objective
characterization of a periodic phenomenon, to wit, an estimate of M [the time structure or chronome-adjusted mean,
or MESOR] … an estimate of [the amplitude] A itself, and finally an estimate of acrophase, f [a measure of timing]
[Figure 10A] [24] [our addition]. In this way, a patient can be compared with himself at another time [Figure 10B]
[25] [our addition], or under another treatment, and the patient can be compared with a normal [Figure 2; our addition]
or with another patient” (23).
2.2 WHAT TO DO WITH 24-H CHAT OR WITH OTHER
RECORDS COVERING A SINGLE CYCLE
Turning back to Figure 2, by using “clinically” healthy in its title rather than just “healthy”, in 1984 (!) we implied that
we had no outcome data on the subjects investigated, but were not aware of any abnormality. We still lack outcomes
for CH, but have (we emphasize tentative) gender- and age-specified reference standards (RS) for whites, among others
(26). We can make a diagnosis of 24-h CHAT (27) specifically in the light of now-available acceptability limits for
the 24-h amplitude, still to be improved by restriction to long-lived disease-free individuals. Having diagnosed 24-h
CHAT, we must realize the limitations of the record’s brevity (5, 16–18). Taking a 24-h profile to assess a single circadian
cycle being equivalent to taking the pulse for one second to gauge just a single cardiac cycle was recognized long
ago (27)4
. The analogy of taking the pulse for only one second as assessing only a single cycle can now be extended
2	 Dr. Howard Levine, the late head of medical education at the New Britain (Connecticut) General Hospital, and professor of medicine
at the University of Connecticut, implemented self-measurements of blood pressure, heart rate and other performance variables,
including grip strength, around the clock from the time of a chronobiologic diagnosis of MESOR-hypertension until the end
of life from amyotrophic lateral sclerosis, his weakness notwithstanding.
3	 Dr. Bartter also self-measured BP around the clock from the time of diagnosis until a fatal stroke.
4	 Halberg et al. wrote in 1997 (27): “Even a single heartbeat, however faint, will rule in at least a glimmer of life. The taking of the
pulse for only a second or two then provides valuable information as to the merits of further efforts in resuscitation. But if the
pulse were routinely taken for only a second or so, a bradycardic athlete in the best of health might be presumed dead!” We paraphrase
these authors by stating further that a record of the beating heart for a minute or two may be compatible with diagnosing
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to the physiological counterparts of a half-year and of the seasons and to periods shorter than 6 months, the cis-halfyear
(on this side of the period = cis) or longer than 12 months, the transyear (beyond = trans). Like the 11-year (undecennian)
or decadal period of the sunspots, they are all reflected in the human circulation, Figures 11A–C (28–30).
Whether it is normal or abnormal, neither a 24-h nor a single 10- or 11-year record can eventually remain the basis of
a diagnostic, therapeutic or etiologic decision. In either case, the need remains for further lifelong C-ABPM, and for
continued epidemiological data collection and analysis, the purpose of the website in Figure 1. When the 24-h record
happens to be abnormal, it constitutes no more than an indication of the urgency of C-ABPM to assess a possibly acceptable
physiological response. Reliance on data covering less than a solar cycle length have led to controversy (31,
32) and have retarded recognition of heliobiology in the West, Figure 12A–D (32; cf. 33).
2.3 1-WEEK CHAT
A diagnosis of 24-h CHAT, of an excessive circadian swing, can be physiologically associated, in certain individuals,
with events such as the arrival of welcome visitors, Figure 13 (5), or any other pleasant tasks (not necessarily loads)
such as giving a party (5) or discussing important-seeming topics with a friend or even with a dear family member
or without any obvious reason but perhaps one hidden in space weather (34; cf. 35). When a 24-h cosine curve is
fitted to a 7-day series as a whole (rather than to a 24-h profile, as in Figure 2), a few days of CHAT may be smoothed
out and the record as a whole may be acceptable, Figure 14A, or at least the number of weeks with CHAT is reduced,
Figure 14B (36). On a population basis, the high risk of severe events associated with CHAT, Figures 5A–C, and more
so with coexisting VVDs is clearly demonstrated in Figures 15A and 15B (4). A VVA for a single day should invariably
prompt, as a follow-up, at least an added 7-day C-ABPM. In a case of fulminating CHAT, Figure 10B (25), this
recommendation was not fully implemented, albeit a second short record was even more abnormal than the first. The
patient took a conventional stress test instead, which was normal, and hence nothing else was done. Some months
later, he returned asking for an implanted BP sensor. We asked why, and he told us that in the interim he had had
a myocardial infarction (25). C-ABPM was also ignored in a single case of CHAT during pregnancy but not others. In
that case, the systolic BP average (MESOR) was 115 mmHg, Figure 16 (4). In that case, not in others, a premature
birth was associated with a partly cost-accounted expense of U.S. $1 million (4).
2.4 “SIMPLER” CLASSIFICATION BY DIPPING CAN MISLEAD
A chronobiologic approach works when a dipping classification can fail (19, 37, 38) or dipping misleads (39) on
a small group basis. It seems the more important to realize that dipping cannot be recommended for the diagnosis
of individuals, even for 7-day records, it is not equivalent to C-ABPM (4, 40, 41), in keeping with Einstein’s “make
everything as simple as possible but no simpler”.
3.0 CHRONOTHERAPY
When the diagnosis of MESOR-hypertension is made, the dose prescribed is preferably varied, starting with a time
preceding the peak by several hours. Hence, the circadian acrophase of BP as a marker preceded by an interval whose
length depends on the chronopharmaceutics of the drug(s) involved is a procedure that has yielded a faster desired
response, with fewer side effects compared to traditional therapy, Figure 17 (42; cf. 43). If needed, the timing of the
drug can next be varied empirically to find the optimum, Figures 18A and 18B (part 2 of 44). This is the more important
since the same dose of the same drug in the same patient tested at 6 different circadian stages, for ~1 month at
each time (at clock hours after awakening 3 h apart) can induce or enhance an existing CHAT at one test time or at
death vs. life, but it is hardly recommended when a full 24-h record can fail to reveal abnormality that is present during each of
11 subsequent days, and of course vice versa.
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NONINVASIVE METHODS IN CARDIOLOGY 2012
another remove CHAT and lower BP, as intended, Figure 19 (45; cf. 46). Sometimes, a single change in the timing of
a medication can correct abnormality, Figure 20 (cf. 2). Continued surveillance is indicated, Figure 21 (2). The many
millions receiving hypotensive drugs need not fly blind, concerning risks in Figures 15A and 15B, while for security
on the road we routinely automatically measure the pressure in automotive tires. Moreover, if we monitor ourselves
continuously and automatically, we may learn about a new world of infradian rhythms that reflect physical environmental
counterparts and relate to sudden cardiac death (Table 1 and Figure 22), suicide (Figures 23A–D), homicide
(Figure 24), and terrorism (Figures 25 and 26). We may even find, on a population basis, the antecedents, Figure 27
(30, 47) as well as the consequences (48) of a tsunami accompanying an earthquake.
4.0 BEYOND CIRCADIANS
Time series collected and accumulating for the goal of self-surveillance, once aligned with physical environmental
time series, enlarge the scope of Vladimir Ivanovich Vernadsky’s noösphere (49, 50), the sphere of the human mind
by a transdisciplinary spectrum of cycles congruent insofar as their periods in us and around us have overlapping CIs
(95% confidence intervals) (51–54), Figures 28A-H.
Our inclusion of the moon, i.a., in Figure 28B is in keeping with studies on his own heart (56) by Miroslav Mikulecky,
emeritus head of internal medicine and professor of statistics at Comenius University in Bratislava, Slovakia, organizer
of meetings on this and related topics (57–61). It is here prompted by the first patient encountered by us who
shows the double period of tides (62) averaging 24.8 h, repeatedly in the computer output (not input) of analyses of
time series. JF is a woman, 61 years of age at start of a years-long around-the-clock study, including C-ABPM, with
a 20-year history of twice-yearly adynamic depression, each lasting 2–3 months. During “downtimes”, JF is unable
to get out of bed and to keep synchronized with a 24-h periodic sleep-wake schedule. Her sleep pattern scans the
hours of the day during her episodes. She self-rated vigor-wellness while claiming sensitivity to the moon. In the
first months of the first two adynamic episodes investigated, we found a double tidal period of 24.8 h supporting
her impression of selenosensitivity. JF self-measured BP and HR for 5 initial months and for > 16 months thereafter,
Figure 28D. At least 2 circadian periods coexist most of the time, Figure 28E. She also collected saliva at 4-hourly
intervals around the clock for the determination, in 11,702 assays, of cortisol, aldosterone, dehydroepiandrosterone,
estradiol, testosterone and melatonin, Figure 28F, showing multiple recurring circadian endocrine as well as vascular
ecfrequentia. Several circadian periods were also present in her outside downtimes during relative wellness (55),
suggesting a “wrangling” of the tides with society and (natural and artificial) light. We may speculate whether the
tides act via gravity and magnetism, a view shared with physicist-chemist Vladimir Evstafyev (63) and Prof. Mikulecky
(their personal communications), acting by mechanisms considered by Friedemann Freund (64). In any event,
in JF, this tug of war yields (compromise?) periods between 24.0 and 24.8 h except that during some of the first
months of an adynamic desynchronized episode, a precise average double tidal period prevails. The diagnosis in JF
of dysfrequentia, visualized by a comparison with an age- and gender-matched control, in Figures 28G and 28H can
be made by C-ABPM (but not by self-measurement, a highly motivated JF notwithstanding, in keeping with earlier
results [65]).
Cycles in us, such as the physiological week, among others, led to natural geomagnetic near-weeks, Figures 29A
and 29B (51). Reports of new cycles by physicists prompted our discovery of coperiodic biospheric signatures of the
cosmos such as ~5‑ or ~16-month-long, Figures 30A–C (34), and other cycles, Figures 31A–C (53, 54). There are
further cross-spectral coherences (54, 66–68) and phase synchronizations (68) between endpoints around us, such
as Bz, Kp, Wolf number or coronal mass ejection or cosmic rays and urinary variables or the decades-long monitored
BP of individuals. Associations are also seen from cross-wavelets and coherence between myocardial infarctions of
populations or the incidence of terrorism on the one hand and space weather on the other hand, Figures 32A–D.
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NONINVASIVE METHODS IN CARDIOLOGY 2012
We trust that with Figures 33 and 34, among others, a chronousphere 5
emerges, consisting of many infradians with
periods longer than 28 h, up to myriadennians (69, 70). For some of the infradian pairs of periods, the disappearance
or reappearance of the environmental, e.g., solar or interplanetary component entails corresponding biospheric consequences,
Figures 34 (44), 35 (61) and 36 (62). The approach by removal of a gland and replacement of its hormone
started endocrinology and eventually chronobiology (71). Investigation seems indicated not only by mapping (51, 54,
71–74) but also by the subtraction and/or addition approach (44, 75), notably for those in health care interested in
the effects of space weather (34).
TAKE HOME
In confronting congruent cycles in us and around us, the biospheric cycles when they are coded in our genes, may
reflect what goes on and went on outside us from the origins of living matter, more reliably than the relatively recently
recorded corresponding physical cycles. The dynamics of the cosmos almost certainly went on for a very long time.
The solar wind and its aeolian cycles probably blew for billions of years and left their mark in our makeup. A record of
polar lights and sunspots traces only a millennium or less. It can be aligned with time series of helio‑, interplanetary,
lunar or geomagnetic variables for a much shorter span. Recording by satellites of interplanetary, solar and cosmic
variable is still more recent, but there are, of course, physical measures for carbon and other dating. None of them,
however, matches in density or length the dynamic information provided by cycles in living matter. The latter phrase
aims to use Vernadsky’s plea for dealing with life as part of the crust of the earth, as a biosphere turning, with him,
Edouard Le Roy and Pierre Teilhard de Chardin, into a sphere of the human mind (Gk noos; hence noosphere) by
a directed evolution.
In this context the cycles of the biosphere, mimicking those of the cosmos, constitute another novel way of dating
(where we come from and what we encountered on our way to where we are and to where we want to go) and certainly
serve to validate, as magnetometers or cosmometers, the relatively recent physical counterparts (52), notably in the
human baby (74). This dating by mapping from archaea to man reveals a set of transdisciplinary cycles pervading all
disciplines, each a sphere of the human mind (also Attic Gk nous), yielding a novel time structure. We can get much
information about such a chronousphere by monitoring ourselves glocally, namely with repeated passes over the accumulating
data as a whole (globally), eventually from the womb, and now from where we happen to start, eventually
to the “tomb” in the individual, with a view of achieving the same by the monitoring of natality, health, morbidity and
mortality statistics for the well-being of populations.
We have learned to deal with excessive heat or cold and now have thermometers to trigger heating or cooling as need
be. Similarly, we must deal with excessive or lacking magnetism and other, not always obvious factors that complicate
not only physical communications among us (what Stetson [76] and Düll and Düll [77] detected long ago, as the
effect of solar emissions). We must also learn to deal with each other toward a desirable not only cross-spectral but
also much broader insofar as measurable and manipulable “coherence” with our environment near and far, including
space weather. The cosmos affects not only the easily measured “bad” such as sudden cardiac death, suicide,
5	 From Gk chronos = time, Attic Gk nous = mind and Gk sphairos = globe. We used “nous” in the portmanteau’d “nousphere” to
credit Vladimir Ivanovich Vernadsky, Pierre Teilhard de Chardin and Edouard le Roy, who, i.a., used the derivation of “noosphere”
from “noos”, recognizing the need for a sphere of the human creative mind or broader culture, courageously extrapolating beyond
the sphere of available data (criticized by Hagemeister M. In: Rosenthal BG, ed. The Occult in Russian and Soviet Culture. Ithaca,
NY: Cornell University Press; 1997. p. 185–202, yet endorsed with extensive study by Ertel S. Studia Psychologica 1996; 38: 3–22).
Cosmism’s pioneers as yet did not have the means (computers and satellites) for detecting and documenting the pervading transdisciplinary
spectrum of solar, interplanetary, geo- and biospheric cycles and the consequences in the human mind of the aeolian
disappearance and/or reappearance of non-photic rhythms.
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NONINVASIVE METHODS IN CARDIOLOGY 2012
homicide and war, but also the hard-to-assess “good”, as perhaps revealed by church membership (78) and religious
proselytism (79), a task of optimization for a budding chronobioethics (80, 81).
In a global coherence initiative, Rollin McCraty and his associates seek a shift from “competition” to “greater cooperation”
in a coherent planetary standing wave (82; cf. 83). The “increased power of connected intention and
consciousness”, also a topic of interest to Michael Persinger’s (84, 85) and Hans Wendt’s (86) research, should all
prompt attempts to find better measures of coherence beyond those used herein from physics and numerical analysis.
Perhaps the language of frequencies within them and far outside Schumann’s resonances is pertinent, that yielded
Figure 23 and remove-and-replace approaches in arriving at Figures 24–26 constitute a step in that direction.
It seems the more important to assess the status quo of information measured as tangible “coherence” with our cosmos,
the topic of this paper. From this viewpoint, C-ABPM, while worth implementing for immediate health benefit,
once it is aligned with physical environmental monitoring, provides marker rhythm information concerning both
environmental magnetism and other nonphotic factors competing with oscillations in the visible range. Patient JF,
alluded to herein, is a case in point at the clinical level.
As to mechanisms involved, the physicist and chemist Vladimir K. Evstafyev suggests that while the earth’s atmosphere
absorbs most cosmic radiation, there is a “transparency window between 375 and 10 MHz” through which
radio waves reach the earth’s surface and, if of appropriate frequency, bring about spin inversions, as a way to affect
chemical reactions (63), a problem also discussed by Waldemar Ulmer as diffusion at the atomic level, modeled
further as interaction among quantum mechanical frequency-coupled circuits, as bio-resonance at a very high frequency
and resulting in beats at a low frequency fueled by ATP and involving DNA, a speculation based on extensive
data (87; cf. 88).
CONCLUSION
The BP cuff in the provider’s office must go for the moment to the homes of each individual. In the 1960s and 1970s it
seemed worthwhile to plead, as Frederic C. Bartter, of Bartter’s syndrome, also did, for moving the BP cuff from the
providers’ offices to everybody’s (including his own) office or other work place by day and home by night. This recommendation
holds until a system of C-ABPM became affordably available to everybody. Bartter advocated this as
head of the Hypertension-Endocrine Branch at the U.S. National Institutes of Health (NIH), and later as head of the
NIH’s Clinical Center. In 2012, self-measurements at home have detected an effect of the great earthquake in Japan,
proving their possible broader value (48). They confirmed, if not the finding of antecedents (30, 47), at least the consequences
of the same quake, found on a small scale yet worldwide in a de facto validation test of an ongoing C-ABPM
system, serving for cost-free analyses of self-surveillance data by all comers. This model for a website has now also
been proposed by a World Forum on “Natural Cataclysms and Global Problems of the Modern Civilization”, held
19-21 September 2011 in Istanbul, Turkey (www.2011.geocataclysm.org). The data collected for the prevention of
personal cataclysms, such as a massive stroke, may also be used to attempt an understanding (for countermeasures)
of the mechanisms underlying societal disease, such as suicide, crime, homicide, terror and war and natural disasters
such as earthquakes and tsunamis, as well as “coherence” or rather mutual understanding and chronobioethical
cooperation among people.
DEFINITIONS (1 AND 3–10 ARE BOTH NOUN AND ADJECTIVE)
1. 	 Aeolian. Nonstationary oscillations that appear, may disappear and reappear ubiquitously and/or in limited
geo- (or cosmo-) graphic space and time, with changes in period, t, amplitude, A, and/or phase (f). Many
physical as well as biological cycles are aeolian, including among the latter ~24-hour (h) circadians, synchronized
with or desynchronized from a 24-h society (socidian and asocidian, respectively). Because of their
aeolian nature, some spectral components can be defined only tentatively by the CIs (95% confidence inter-
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NONINVASIVE METHODS IN CARDIOLOGY 2012
vals) of their t. Even this precaution was not sufficient in the case of the BEL, initially defined as a τ with a CI
(not the point estimate) of t covering the range between 30 and 40 years. But then we found CIs nearing (but
not reaching) that range that could have been BELs. Hence, some definitions refer only to the CI of t and not
to a point estimate of τ, and others may refer to a “CI near a given range” rather than a CI in a given range,
with the limits still to be revised if need be; they are tentative. Biospheric aeolians are not now replicated in
the same individual in the case of BEL cycles and have been studied in populations, where some of them are
already documented.
2. 	 CI. 95% confidence interval of a characteristic such as period, amplitude or phase.
3. 	 Circadian. Cycle of ~20- to 28-h duration, usually 24-h synchronized (socidian in societal organisms like
humans) but even a 24-h synchronized circadian (in circulating endothelin) can disappear and reappear,
by the criterion of statistical significance, while it cannot be decided whether it is actually lost or obscured
by noise to the point of failing detection. In biology, several circadians can coexist, such as an average τ of
~24.00 h, a socidian corresponding to the societal day, and an average τ of ~24.84 h, corresponding to a lunisolar
(double tidal) day (in sleep-wakefulness of a healthy man on a self-selected sleep-activity schedule and
of a patient with recurrent adynamic depression).
4. 	 Ultradian. Cycle shorter than 20 h (coined with reference to frequency).
5. 	 Infradian. Cycle longer than 28 h (coined with reference to frequency).
6. 	 Circasemiseptan. Cycle of ~3.5 days.
7. 	 Circaseptan. Cycle of ~7 days.
8. 	 Quinmensal (also cis-half-year). Cycle of ~5 months.
9. 	 Circasemiannual. Cycle of ~6 months.
10. 	Circannual. Cycle of ~1 year.
11. 	Near-transyear. Cycle slightly but statistically significantly longer than 1 year (1.00 year < [τ − CI] < [τ + CI]
< 1.20 years).
12. 	Far-transyear. Cycle considerably longer than 1 but shorter than 2 years (1.2 years ≤ [τ − CI] < [τ + CI] < 1.9
years).
13. 	Horrebow-Schwabe cycle. Cycle with a CI of τ near 11 years (circaundecennian or decadal).
14. 	Hale cycle. Cycle with a CI of τ near ~22 years.
15. 	BEL (Brückner-Egeson-Lockyer) cycle. Cycle with a CI of τ near 30 to 40 years (paratridecadal).
16. 	Kondratiev cycle. Cycle with a CI of τ near ~50 years (quindecadal).
17. 	Sexadecadal. Cycle with a CI of τ near ~60 years.
18. 	Congruence (vs. acongruence) classifies sets of τs that, if not identical, are very close to each other in length;
“closeness” is defined by overlapping CIs of the τs, introducing objectivity where subjectivity and a lack of
indications of uncertainty prevailed for the majority of reports dealing with the many non-stationary cycles,
aeolian in space as in time, i.a., in biomedicine, economics and physics, notably in the infradian domain, that
characterize our psychophysiology, epidemiology and many other human affairs, and leading to a societal
(and thus novel aspect of environmental) medicine.
19. 	Resonance. The induction or amplification of an oscillation by virtue of interacting natural frequencies
(­eigenfrequencies) that are similar (approximately or fully identical), within an ever-broader system such as
a biosphere, a noösphere and a chronousphere, i.e., ω1 − ω2 ≈ 0.
20. 	Coherence. Stable wave-packet without (or with an extremely small) dispersion of frequencies. Such
a physico-chemical state, whether induced or merely reactive or self-sustained, can be stabilized by oscillations
with similar frequencies, according to the requirements or conditions for resonance. The non-selfsustained
­oscillation may break down in the absence of coherence with an external oscillation, whereas the
self-sustained one may decrease in amplitude whenever the coherent fraction of the underlying mechanism
is subtracted. (In the context of time series, coherence, from cross-spectral analysis, may be used to identify
variations which have similar spectral properties [high power in the same spectral frequency bands], if the
variability of two distinct time series is interrelated in the spectral domain.)
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NONINVASIVE METHODS IN CARDIOLOGY 2012
Support: GM-13981 (FH), University of Minnesota Supercomputing Institute (GC, FH)
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University of Minnesota/Medtronic Chronobiology Seminar Series, #2, December 1991, 3 pp. of text, 38 ­figures
27.	Halberg F, Cornélissen G, Otsuka K, Watanabe Y, Wood MA, Lambert CR, Zaslavskaya R, Gubin D, Petukhova
EY, Delmore P, Bakken E. Rewards in practice from recycling heart rate, ectopy, ischemia, and blood pressure
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can differ among variables and circadian endpoints and in individuals vs. populations. World Forum
“Natural Cataclysms and Global Problems of the Modern Civilization”, 19–21 September, 2011, Istanbul, Turkey.
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29.	Watanabe Y, Cornélissen G, Hillman D, Otsuka K, Halberg F. Long periods in 23 years of around-the-clock automatic
measurements of human blood pressure and pulse. World Forum “Natural Cataclysms and Global Problems
of the Modern Civilization”, 19–21 September, 2011, Istanbul, Turkey. London: SWB; 2011. p. ­121–122
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NONINVASIVE METHODS IN CARDIOLOGY 2012
32.	Lipa BJ, Sturrock PA, Rogot E. Search for correlation between geomagnetic disturbances and mortality. Nature
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Friendship University of Russia, Moscow, Oct. 10-12, 2005, p. 4–22
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Research, Tokyo, November 1–3, 2006. p. 64–68
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International Workshop of the TsimTsoum Institute, Krakow, Poland, June 3, 2010, p. 22–23
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47.	 Watanabe Y, Halberg F, Otsuka K, Cornelissen G. Physiological changes in relation to the 2011 East Japan
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48.	Satoh M, Kikuya M, Ohkubo T, Imai Y. Acute and subacute effects of the great East Japan earthquake on home
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heliogeomagnetics, transyears, near-weeks, near-decades, phylogenetic and ontogenetic memories. Biomed &
Pharmacother 2004; 58 (Suppl 1): S150–S187
54.	Halberg F, Breus TK, Cornélissen G, Bingham C, Hillman DC, Rigatuso J, Delmore P, Bakken E, International
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for Aerospace and Environmental Medicine, Nagoya, Japan, November 8–9, 1991. University of Minnesota/
Medtronic Chronobiology Seminar Series, #1, December 1991, 21 pp. of text, 70 figures
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Pappadoupoulou A, Chrousos GP, Costella JF, Mikulecky M. Multiple circadian periods in a lady with recurring
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Bratislava: Slovak Medical Society; 1997. 287 pp
59.	 Mikulecky M, Florida PL. Daily birth numbers in Davao, Philippines, 1993-2003: Halberg’s transyear stronger
than year. Abstract, 26th
Seminar, Man in His Terrestrial and Cosmic Environment, Upice, Czech Republic, May
17–19, 2005
60.	Kovac M, Mikulecky M. Secular rhythms and Halberg’s paraseasonality in the time occurrence of cerebral
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65.	 Stinson SM, Cornélissen G, Scarpelli PT, Halberg F. Self-measurement and ambulatory monitoring of blood
pressure: a subject’s chronobiological perspective. Biomed & Pharmacother 2002; 56 (Suppl 2): 333s–338s
66.	Hillman DC, Siffre M, Milano G, Halberg F. Free-running psycho-physiologic circadians and three-month pattern
in a woman isolated in a cave. New Trends in Experimental and Clinical Psychiatry 1994; 10: 127–133
67.	 Hillman DC, Siffre M, Milano G, Halberg F. Urinary about-84-hour (circasemiseptan) variations of a woman
isolated in a cave and cosmic ray effects. New Trends in Experimental and Clinical Psychiatry 1994; 10: 173–178
68.	Halberg F, Cornélissen G, Bingham C, Witte H, Ribary U, Hesse W, Petsche H, Engebretson M, Geissler H‑G,
Weiss S, Klimesch W, Rappelsberger P, Katinas G, Schwartzkopff O. Chronomics: Imaging in time by phase
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Rhythmen hinausgeht”) In memoriam – lost future: Dr.-Ing. habil. Dr. rer. nat. Barbara Schack: 1952–2003.
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diversity of oceanic genera. Abstract, III International Conference, Civilization diseases in the spirit of V.I. Vernadsky,
People’s Friendship University of Russia, Moscow, Oct. 10–12, 2005, p. 47–49
70.	 Sonkowsky RP, Cornélissen G, Chibisov SM, Schwartzkopff O, Sampson M, Halberg F. Myriadennian, including
perhaps millionennian or the shorter megennian – a choice to be made: invitation for comment. Abstract,
III International Conference, Civilization diseases in the spirit of V.I. Vernadsky, People’s Friendship University
of Russia, Moscow, Oct. 10–12, 2005, p. 123–125
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Y, Schwartzkopff O, Otsuka K, Tarquini R, Perfetto P, Siegelova J. Transdisciplinary unifying implications
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T, Baevsky R, Engebretson M, Schröder W. Schwabe’s ~10.5- and Hale’s ~21-year cycles in human pathology
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75.	 Cornélissen G, Halberg F, Wendt HW, Bingham C, Sothern RB, Haus E, Kleitman E, Kleitman N, Revilla MA,
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Table 1. Geomagnetic/geographic differences among cycles with periods in the range of 0.8–2.0 years,
characterizing the incidence of sudden cardiac death (SCD)1* and myocardial infarction (MI)
Sudden Cardiac Death (SCD)1
Site Span T, ∆t, N SCD (N) Period (y) (95% CI) Amplitude (95% CI) A (%
MESOR)
P-
value2
- - - - - Transyear (TY) or Candidate Transyear (cTY) Detected - - - - Minnesota
1999-2003 5y, 1d, 1826 343 1.392 (TY) (1.173, 1.611) 0.042 (0.00, 0.09) 22.0 0.014
Arkansas 1999-2003 5y, 1d, 1826 273 1.095 (0.939, 1.251) 0.032 (0.00, 0.07) 21.1 0.040
1,686 (cTY) (1.293, 2.071) 0.031 (0.00, 0.07) 20.7 0.044
Czech Rep. 1999-2003 5y, 1d, 1826 1006 0.974 (0.856, 1.091) 0.078 (0.00, 0.16) 14.2 0.007
1.759 (cTY) (1.408, 2.110) 0.077 (0.00, 0.15) 13.9 0.01
1994-2003 10y, 1d, 3652 1792 1.726 (TY) (1.605, 1.848) 0.074 (0.02, 0.13) 15.1 <0.001
1 (0.944, 1.056) 0.052 (0.00, 0.10) 10.6 0.01
- - - - - Candidate Transyear Not Detected - - - - North
Carolina 1999-2003 5y, 1d, 1826 752 0.929 (0.834, 1.023) 0.069 (0.00, 0.14) 16.9 0.007
Tbilisi, Georgia Nov 99-2003 4.1y, 1d, 1505 130 0.988 (0.862, 1.114) 0.035 (0.00, 0.07) 40.7 0.007
Hong Kong 2001-2003 3y, 1m, 36 52 0.843 (0.651, 1.036) (NS) 44.9 0.077
Myocardial Infarction (MI)
Site Span T, ∆t, N MI (N) Period (y) (95% CI) Amplitude (95% CI) A (%
MESOR)
P-
value2
- - - - - Coexisting Year (Circannual) and Transyear (TY) - - - - Czech
Rep. 1999-2003 5y, 1d, 1826 52598 1.014 (0.989, 1.038) 2.85 (2.22, 3.48) 9.88 <0.001
1.354 (TY) (1.252, 1.456) 1.35 (0.69, 2.02) 4.68 <0.001
1994-2003 10y, 1d, 3652 115520 0.998 (0.988, 1.009) 3.03 (2.47, 3.60) 9.58 <0.001
1.453 (TY) (1.417, 1.489) 1.91 (1.34, 2.49) 6.04 <0.001
1.15 (TY) (1.116, 1.184) 1.23 (0.64, 1.82) 3.88 <0.001
*With focus on transyears, with periods longer than 1.0 year (underlined; double underline for near-transyear).
1
International Classification of Diseases (ICD10), Code I46.1, excluding MI and
sudden death of unknown or unspecified cause (except before 1999).
T: length of data series (y=years); ∆t: sampling interval (d=day, m=month); N: number of data (including 0s).
Period and 95% confidence interval (CI) estimated by nonlinear least squares. In longer (10-year) series, a neartransyear
(cycle with a period between 1.0 and 1.2 years) is detected for MIs in addition to a far-transyear. Brevity
of series and lack of ordering statistical significance qualify results from Hong Kong. Note that transyears are
found in 3 of 6 locations (P<0.05 by linear least-squares) with a relative amplitude > 12 (% of MESOR).
2
From linear least-squares analyses, not corrected for multiple testing. Amplitude expressed in N/day.
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NONINVASIVE METHODS IN CARDIOLOGY 2012
Figure 1. Physiological, other biological, notably epidemiological, and sociological as well as physical and environmental
data collection and analyses in the project on The Biosphere and the Cosmos, BIOCOS, are ongoing worldwide on a very
small scale, yielding, i.a., the data of this paper and some of those cited from our team. They constitute a validation test
underlying a proposal by a World Forum on “Natural Cataclysms and Global Problems of the Modern Civilization”, held
19–21 September 2011 in Istanbul, Turkey (www.2011.geocataclysm.org), for a manned international multilingual website,
providing analyses for all comers, and saving the data, beyond both the medical community (bottom right) and physical
environmental science concerned about space weather effects (upper right), also for the self-surveilling public at large,
notably for those interested in science and art, a unified transdisciplinary chronousphere. The Phoenix Project of volunteering
members of the Twin Cities chapter of the Institute of Electrical and Electronics Engineers (http://www.phoenix.tc-ieee.
org) is planning on developing an inexpensive, cuffless auto­matic monitor of blood pressure and on implementing the
concept of a website (www.sphygmochron.org) for a service providing automatic analyses in exchange for the data that in
turn are to be used for refining methods and for monitoring psychophysiological effects of space weather. © Halberg.
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NONINVASIVE METHODS IN CARDIOLOGY 2012
Figure 2. 24-h profiles of blood pressure (BP) variation in two clinically healthy men were described in 1984 (10) as revealing
inter-individual differences. In the interim, reference values from clinically healthy subjects with outcomes have demonstrated that
a double amplitude of 60.2 mmHg in CH, 60 years of age, is compatible with a diagnosis of 24-h CHAT (Circadian Hyper-AmplitudeTension,
a circadian overswing; see Figure 3) found on occasion in certain individuals as a physiological event (response) under
routine conditions. If CHAT persists (is not smoothed out) in the 24-h cosine fit to a 7-day around-the-clock record, the diagnosis of
“7-day CHAT”, like that of “1-day CHAT”, is no more than an indication for further C-ABPM. Two patients whose BP averages (here
the MESORs, Midline-Estimating Statistics Of Rhythm) are practically identical differ in terms of their psychophysiology, here
gauged by the circadian amplitude of BP. Longer monitoring is indicated to arrive at an assessment of stress or load by a Vascular
Variability Anomaly (VVA), or a gauge of strain, a Vascular Variability Disorder (VVD), and thus to assess the risk of developing
a stroke within 6 years. As compared to the risk associated with high BP, a risk of systolic CHAT doubled that risk. © Halberg.
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NONINVASIVE METHODS IN CARDIOLOGY 2012
Figure 3. Definitions and abstract illustrations of circadian Vascular Variability Anomalies (VVAs), for systolic
(S), mean arterial (MA) or diastolic (D) blood pressure (BP) or a combination of the foregoing when the CI
(95% confidence interval) of the period, t, overlaps 24 h for I to III. I to IV are diagnosed by cosinor (10) with
reference to gender- and age-specified reference limits (RL) with a CI of the amplitude (A) not overlapping
zero and the characteristic(s) M (MESOR), A and f (acrophase) within the corresponding RL:
I. MESOR (M)-hypertension (MH), an elevation of the M above RL, can be S-MH, D-MH, MA-MH or a
combination thereof, demonstrated by M, from curve-fitting complemented by stacking along the 24-hour (h)
scale by a measure of load, the hyperbaric index and by percentages and times of abnormal values (4).
II. Circadian Hyper-Amplitude (A)-Tension (CHAT), an elevation of the 24-h A above RL, which can also be
systolic (S-CHAT), diastolic (D-CHAT), mean arterial (MA-CHAT), or a combination of the foregoing.
III. SBP-, DBP- or MAP-ecphasia (when persisting and associated with illness, circadian dysphasia),
an odd timing outside RL of the circadian rhythm of BP but often not of that in HR.
IV. Circadian ecfrequentia, (when persisting and associated with illness, circadian dysfrequentia), one or several circadian
periods, t, with a CI not overlapping RL, represents a 720% increase in risk of ischemic stroke (see last column on right).
V. Excessive pulse pressure (EPP), when the difference in the MESORs of SBP and DBP for adults exceeds 60 mmHg.
VI. A deficient HR variability (DHRV), defined as a standard deviation of HR less than 7.5 beats/minute.
Threshold values remain to be replaced by RL. All RLs remain to be improved by restriction to those of
disease-free long-lived peers specified by gender, age, ethnicity and geography. © Halberg.
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NONINVASIVE METHODS IN CARDIOLOGY 2012
Figure 4. At the start of monitoring, CHF, a woman in presumably good health, was 60 years of age. She monitored her blood
pressure (BP) and heart rate (HR) around the clock with a TM-2421 monitor from A&D (Tokyo, Japan). The reliability of the
TM-2421 monitor had been documented. This monitor measures BP and HR according to the oscillometric and the auscultatory
method. As a rule, with the instrument used, oscillometric readings are more reliable than auscultatory measurements.
The monitor gives a beep as a warning to stand still (e.g., if the user is walking or engaged in some other activity) or remain
seated or recumbent, as the case may be. After the beep, the cuff inflates automatically, taking and storing a measurement of
systolic (S) and diastolic (D) BP and HR. If so set at half-hourly intervals, automatic measurements are taken and stored for up
to 2.5 weeks if the instrument is recharged at 3-day intervals, by being plugged into an electrical outlet for several minutes.
Monitoring sessions were repeated at intervals of weeks or months during 6 years. CHF kept a thorough diary at the
time of monitoring, which allowed the association of spans when her BP was found to be deviant with the presence
of strong emotions such as grief, conflict and concern, albeit not in association with annoyance by particular
measurements. Irrespective of the duration of a given monitoring session, analyses were carried out in repeated
scans of the same data for separate subspans of 1. at least 24 h, 2. a week, 3. longer spans, sections of the data such as
4. only nightly readings or 5. readings without those accompanied by a note indicating annoyance by measurement.
6. In particular, interest such as concern for several weeks about a diagnosis of ovarian cancer in her daughter (showing
gross abnormality) and 7. including analyses on all her data accumulated at certain times during the 6 years.
Each data series was analyzed using a curve-fitting and a stacking approach, with analyses of the long series confirming that
CHF was 24-h synchronized; the CI (95% confidence interval) of her period, t, overlapped 24.00 h. A model was fitted by least
squares, which consisted of cosine curves with periods of 24 and 12 h. This model for most people accurately approximates
the circadian waveform in BP and HR. The parameters are the MESOR, M, a rhythm-adjusted mean; the amplitude, A (of
each of the two components), which is a measure of half the predictable extent of change within a cycle; and the acrophase,
f (also of each of the two components), a measure of the timing of overall high values recurring in each cycle, were computed.
The circadian amplitude and acrophase, together with the MESOR, are interpreted in the light of reference values obtained
from data bases on clinically healthy subjects matched by gender and age. These reference intervals are calculated as 90%
prediction limits. When the MESOR exceeds the upper 95% prediction limit, MESOR-hypertension is diagnosed; when the
circadian amplitude exceeds the upper 95% prediction limit, the condition of CHAT is diagnosed; and when the f or the period
lies outside the 90% prediction interval, ecphasia or ecfrequentia, respectively, is diagnosed, as apparent from Figure 3.
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In the stacking approach, the data as a whole, averaged over an idealized 24-h cycle, are compared by computer with the
time-specified reference limits (derived from data bases obtained independently on clinically healthy subjects). These
reference standards are again calculated as 90% prediction limits over 1-h intervals that are displaced by half an hour
throughout the 24-h day. The reference values are thus specified as a function of clock-hour, gender and age (for 24-h
synchronized subjects only, not for JF in Figure 28D during episodes of depression). CHF’s data are compared with the
upper limit of standards, called chronodesms. Whenever the subject’s data exceed the upper limit of the chronodesm,
BP deviation is diagnosed. The amount of time when the data are above the reference limit represents the percent time
elevation. The area delineated between the subject’s curve when the data are excessive and the upper limit of acceptability
delineates the hyperbaric index in the case of BP and the tachycardic index in the case of HR. As an area under the curve,
this index has the units of mmHg x h during 24 h for BP and of beats/min x h during 24 h for the case of HR.
The center of gravity of the area of excess is also calculated to represent the time of overall excess, which usually is
informative for specifying the timing of treatment administration when it is needed. Cosine fit- and stacking-derived
indices were computed for each profile as a whole as well as for spans of about 24 h so as to determine the extent of
day-to-day variability in the circadian variation and any deviation in relation to chronobiologic norms. The limitation
of a profile of 24 h is seen as intermittent black excesses above the upper limit of the chronodesm in daily summaries
in the first record, yet missing (with one initial exception) in the second record, each record covering weeks.
MESOR-hypertension was then detected for the first 5 days but not for the next 16 days in February (top left). The
circadian amplitude was acceptable for the first 3 days in February, but was intermittently excessive in February (top
middle) but not in April (bottom middle). The circadian acrophase was deviant only at the beginning of the record
in February (top right) and is invariably acceptable in April (bottom right). These results suggest the desirability to
monitor for much longer than 24 h to obtain a reliable diagnosis. Abnormality can occur while most or all measurements
lie within acceptable limits insofar as they are neither too high nor too low on the average. © Halberg.
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Figure5A.Anexcessivecircadianamplitudeofdiastolicbloodpressureraisestheriskofanischemiceventby720%(seelastcolumnonright).OriginaldataofKuniakiOtsuka.©Halberg.
Figure5B.Excessivecircadianamplitudeofdiastolicbloodpressureraisestheriskofnephropathyby590%(seelastcolumnonright).OriginaldataofKuniakiOtsuka.©Halberg.
Figure5C.Notehighrelativeriskatlowestaveragebloodpressure.OriginaldataofKuniakiOtsuka.©Halberg.
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Figure 6A. Need for systematic long-term surveillance by C-ABPM for subject JCM, a clinically healthy
neurosurgery resident who had two systolic values of 160 mmHg while giving blood. © Halberg.
Figure 6B. Sometimes, as in JCM, 23 days of monitoring are not enough for a diagnosis. © Halberg.
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Figure 6C. Dilemma of JCM persists. © Halberg.
Figure 7. The current gold standard must go, just like THE blood pressure at the provider’s office. © Halberg.
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Figure 8. By 1880–1881 Ignaz Zadek had enough data on 4 patients to allow the demonstration by cosinor of daily, half-weekly
and weekly rhythms, seen with cosinor diagrams by error ellipses around the tip of vectors that do not overlap the center of the
graph (pole) with the length of the directed line indicating the amplitude and its direction the acrophase (24). © Halberg.
Figure 9A. Blood pressures of Frederic C. Bartter’s patient who had been diagnosed as normotensive by one
physician seen in the morning and as hypertensive by another provider seen in the afternoon. © Halberg.
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Figure 9B. Limitation of fixed limits for a circadian rhythmic function: fixed (horizontal) limits must go. We are reminded of
outmoded laws and guidelines, still on the books in many states, intended to protect horses and mules at a time when automobiles
(read chronobiologic monitors) were regarded as noisy toys, imposing obligations on motorists such as “In the event that
a horse refuses to pass a car on the road, the owner must take his car apart and conceal the parts in the bushes”. © Halberg.
Figure 9C. Daytime office or dense waking self-measurements would have missed very high blood pressures
by night. Reliance on office or self-measurements only during waking must go. © Halberg.
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Figure 10A. Circadian ecphasia of cardiovascular variables in diabetic pregnancy. Blood pressure (BP) and
heart rate (HR) monitoring of an 18-year-old, gravida 1, para 0, with Type I brittle diabetes treated by an insulin
pump during the 23rd
week of pregnancy reveals not only a low BP and a high HR MESOR, but also ecphasia
(actually a delayed acrophase, i.e., epiphasia) by reference to peer group limits (68% prediction intervals).
Results from Maggioni C, Halberg F, Cornélissen G, Work BA. Nocturnal heart rate and blood pressure peaking
quantified as circadian ecphasia in a diabetic pregnancy. Chronobiologia 1987; 14: 201. © Halberg.
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Figure 10B. Presence of CHAT found in two consecutive short records from a 35-year-old man
preceded by a few months the occurrence of a heart attack while a stress test, carried out following
the abnormal alarming BP monitoring results, found no abnormality. © Halberg.
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Figure 11A. Different decadal and/or multidecadal periods in different variables of the
same elderly man (FH) treated with hypotensive drugs. © Halberg.
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Figure 11B. Different decadal and/or multidecadal periods in different variables of YW,
a man untreated for his developing MESOR-hypertension. © Halberg.
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Figure 11C. Different decadal and/or multidecadal periods in different variables
of WRB, a man treated for high blood pressure. © Halberg.
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Figure 12A. Geographic as well as temporal differences in the association of the incidence pattern of myocardial
infarction and magnetism in the USA, Israel and Russia (where the original studies were done). An excess of
death at peak solar activity can be demonstrated in sufficiently (29-year) long series. Time-varying associations
revealed by also changing phase synchronizations and coherences readily account for site- and time-specific results.
Controversy can be avoided when aeolian time- and site-specific changes are anticipated and documented.
	 The analogy of a blood pressure measurement over a single circadian cycle comes to mind: such a spotcheck may
lead to a lifetime of unneeded treatment (when, in several repeated sessions, the patient was excited and the spotchecks
showed a “hypertension”, not the “white-coat effect” which in a group examined was hypertension in the morning and
hypotension in the evening. A hypertensive patient may be caught on several measurements with occasional normotensive
values and hence will not be treated until a stroke or other severe event occurs. Furthermore, an individual with blood
pressure overswinging limited to the normal range may not be recognized as being at a very high risk of stroke by limitation
of a record to a single cycle. Likewise, studies that cover a single solar cycle may not be conclusive and may miss a relation
that can be documented in the same solar cycle elsewhere or over 3 solar cycles (in Minnesota, USA). Taking evidence over
a single solar cycle, just like relying on a single circadian cycle, is equivalent to taking the pulse for one second. © Halberg.
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Figure 12B. Meta-analyses in Minnesota on diagnoses made in response to a set of ambulance calls in Moscow (54) are confirmed
and extended by Villoresi G, Breus TK, Iucci N, Dorman LI, Rapoport SI. The influence of geophysical and social effects on
the incidences of clinically important pathologies (Moscow 1979-1981). Physica Medica 1994; 10: 79-91. © Halberg.
Figure 12C. Demonstration of about 10.5-year cycle in mortality from myocardial infarction in Minnesota (1968–1996) after removal
of decreasing linear trend, aligned with about 10.5-year solar activity cycle. Fitted curves represent fundamental component as a first
approximation that does not account for the asymmetry of the solar activity cycle considered in Figure 12D. Minnesota data on
myocardial infarction and solar activity (see Figure 12A) reveal association of the latter with the former (see Figure 12D). © Halberg.
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Figure 12D. During years of maximal solar activity, there is an about 5% excess mortality (220 cases per year) from myocardial
infarction in Minnesota (1968–1996) as compared to years of minimal solar activity. 29 years of data allow detection of overall
mortality from myocardial infarction associated with solar cycle stages. Further analyses in Figures 32B–D. © Halberg.
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Figure 13. Original data underlie an association of CHAT (fit not shown) with visitors who were friendly, one a prospective
collaborator, the other an earlier provider of important data for analysis. FH, an elderly man, was unaware of the fact that the arrival
on March 7 of one and on March 10 of the other was preceded by spikes in BP by hours or a day, respectively. All results were within
the acceptable range, yet the swing within that range was excessive. CHAT was present while the visitors were around. © Halberg.
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Figure 14A. A 24-h cosine fit to 7-day data sections removes the occasional abnormality (bottom)
found in analyses of 24-h data sections (top) in an elderly woman. © Halberg.
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Figure 14B. A 24-h cosine fit to 7-day data sections reduces the extent of abnormality (bottom)
found in analyses of 24-h data section (top) in an elderly man. © Halberg.
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Figure 15A. Percentages of Vascular Variability Disorders (VVDs) or rather Vascular Variability Anomalies (VVAs) and
Vascular Variability Syndromes (VVSs) missed in current prac­tice. The incidence of VVDs in this graph is assessed in
a clinic population of 297 patients. BP and HR of each subject were moni­tored around the clock for 2 days at 15-minute
intervals at the start of study. Each record was analyzed chronobiologically and results interpreted in the light of timespecified
reference limits qualified by gender and age. On this basis, MESOR-Hypertension (MH, diagnosed in 176
patients), Excessive Pulse Pressure (EPP), Circadian Hyper-Amplitude-Tension (CHAT), and Deficient Heart Rate
Variability (DHRV) were identified and their incidence related to outcomes (cerebral ischemic attack, coronary artery
disease, nephropathy, and/or retinopathy). Outcomes, absent at the start of study in these non-diabetic patients, were
checked every 6 months for 6 years, to estimate the relative risk associated with each VVD alone or in combination with 1,
2, or 3 additional VVDs, shown in columns complementing each circular display of incidences of variability disorders.
Earlier work showed that CHAT was associated with a risk of cerebral ischemic event and of nephropathy
higher than MH, and that the risks of CHAT, EPP, and DHRV were mostly independent and additive. It
thus seemed important to determine the incidence of each VVD, present alone or in combination with
one or more additional VVDs. Results from this investigation are summarized in this graph.
Results related to MH are shown in the upper left section of the graph. The 176 patients with MH are broken down into 103
(34.7% of the whole study population of 297 patients) with uncompli­cated MH, 55 (18.5%) with MH complicated by one
additional VVD (EPP, CHAT, or DHRV), 15 (5.1%) and 3 (1.0%) with MH complicated by two or three additional VVDs.
In the latter group, all 3 patients had a morbid outcome within 6 years of the BP monitoring. Am­bulatory BP monitoring
over only 48 h, used for diagnosis, is much better than a diagnosis based on casual clinic measure­ments, yet its results
apply only to groups. With this qualification, of the 176 patients with MH, 73 (42.2%) have additional VVDs that further
increase their vascular disease risk, and that are not considered in the treatment plan of these patients since current
practice does not assess these VVDs. This proportion may be smaller in a 7-day record (available for CHAT).
Results related to EPP (bottom left), CHAT (upper right), and DHRV (bottom right) illustrate that these conditions can be
present in the absence of MH in as many as 12 (4.0%) of the 297 subjects. Since they do not have MH, it is unlikely that these
subjects would be treated from a conventional viewpoint, even though their vascular disease risk can be as high as or even
higher than MH. Evidence exists to suggest that treatment of these conditions may trans­late into a reduction in morbidity
and/or mortality from vascular disease. Another lesson from these results is that around-the-clock monitoring of BP and HR
interpreted chronobiologically is needed, even in the absence of MH, to detect vascular disease risk associated with VVDs
such as CHAT and DHRV, that cannot be assessed on the basis of casual clinic measurements, so that non-pharmacologic
and/or pharmacologic intervention can be instituted in a timely fashion before the occurrence of adverse outcomes. Once
implemented across the board rather than in selected patient populations, vascular disease could be curbed to a much
larger extent at relatively low cost if the monitoring is offered directly to the public and care providers become involved only
after detection of a VVD. A website has to be built to interest many people and to provide cost-free analyses in exchange
for the data, as is now provided worldwide by the BIOCOS project on a small scale (corne001@umn.edu). © Halberg.
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Figure 15B. Single Vascular Variability Disorders (VVDs) or rather Vascular Variability Anomalies (VVAs) (lightest shading)
are complicated to a differing extent by one or more added VVDs (darker shading). In this graph, MESOR-Hypertension (MH)
is diagnosed in a total of 289 subjects, representing 24.6% of the 1,177 untreated, presumably normotensive subjects included
in the study. Among these 289 subjects, as many as 137 (47.4% of those diagnosed with MH) have at least one additional
VVD that is not part of the current screening but increases the vas­cular disease risk beyond that associated with MH alone.
The four graphs illustrate that VVDs other than MH occur in the absence of MH in very few patients with Excessive Pulse
Pressure (EPP) and in more patients with Circadian Hyper-Amplitude-Tension (CHAT) and in yet more with ecphasia and in
87 patients with Deficient Heart Rate Variability (DHRV), that is for a total of 182 subjects, representing 15.5% of the study
population. In this study, BP and HR data available hourly for only 24 h were complemented by an assessment of the left
ventricular mass index as a sur­rogate outcome measure. In addition to MH, EPP, CHAT, and DHRV summarized from another
earlier study, ecphasia was assessed. The great limitation of a record covering only 24 h is not overcome by the relatively
large study population of 1,177 subjects not treated with antihypertensive agents, yet results in keeping with those obtained
in a clinic population of 297 patients suggest that MH is to be recognized as a VVD and that its risk can be very greatly increased
when other VVDs combine into Vascular Variability Syndromes (VVSs) that escape current diagnostics. © Halberg.
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Figure 16. By sole reliance on the average blood pressure (of 115 mmHg systolic), disregarding our strong advice for bed
rest and treatment in view of CHAT, a particular obstetrician did not prevent a very premature delivery -- with a partly costaccounted
expense of $1 million -- which happened to be avoided in all other deliveries in an NIH-sponsored study in which
chronobiologic advice usually resulted in bed rest and/or drug treatment without incurring major cost. © Halberg.
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Figure 17. The chronocardiologist Rina Zaslavskaya was first to demonstrate a longer desired effect, by comparison
to conventional therapy, by timing hypotensive treatment prior to the circadian peak in blood pressure,
on a group basis, with less drug and fewer complications. Minnesotan meta-analysis. © Halberg.
Figure 18A. Changing timing of medication (ΔRx) during consecutive spans shows efficacy of treatment. An empirical
approach to chronotherapy: immediately after diagnosis, one should ascertain that the treatment is effective. Optimization
of treatment effects by timing can be achieved for the individual patient by systematically changing, e.g., advancing the
time of treatment. Successful treatment of MESOR-hypertension assessed by a self-starting cumulative sum control
chart. To optimize his hypotensive treatment (Rx), a just-diagnosed 24-year-old individual (TT) switched his Rx first
every 17 days by 4 h and then mostly at shorter intervals. Note statistically significant decrease in MESOR, evidenced by
the breakout outside the decision interval of the negative CUSUM line. With continued Rx, the blood pressure MESOR
leaves the decision interval, indicating a statistically significant decrease in overall blood pressure. © Halberg.
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Figure 18B. Changing timing of medication (ΔRx) during consecutive spans shows risk of iatrogenic CHAT (Circadian
Hyper-Amplitude-Tension). An empirical approach to chronotherapy: immediately after diagnosis, one should ascertain
that one does not induce CHAT by inappropriate timing of anti-hypertensive medication. In this 24-year old man (TT) who
advanced the time of treatment by 4 h every 17 days initially and at shorter intervals thereafter, treatment in the evening
was associated with iatrogenic CHAT, raising the question whether the risk of MESOR-hypertension may not have been
traded for the even higher risk of stroke that CHAT represents. Iatrogenic CHAT, induced by treatment at 20:00 daily,
was silent to office visits. TT may have traded benefit (lowering of the MESOR of blood pressure) for something worse
(circadian overswinging of blood pressure). This danger applies to some hypertensives (who tend to have a large circadian
amplitude of blood pressure) to whom treatment time is not specified by the care provider, as was the case for TT (or is
specified for bedtime). A few others who took hypertensive medication at bedtime were also found to have CHAT. The
figure also shows the assessability of otherwise undetected harm by as-one-goes sequential analysis. © Halberg.
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Figure 19. A popular drug, if prescribed without personalised surveillance, can induce a Vascular Variability Disorder (VVD)
such as Circadian Hyper-Amplitude-Tension (CHAT). A change in the time when the drug is taken can make the same dose of
the same drug in the same person beneficial or vice versa. At one administration time (before noon), Hyzaar induces CHAT in
diastolic blood pressure and exacerbates a preexisting CHAT in systolic blood pressure (red). At another time of administration,
Hyzaar eliminates a pre-existing VVD (green). These opposite effects were found in tests at six medication times, each
administered for about a month, with half-hourly surveillance of BP during the last week of each span. These differences occur
as a function of the timing of the drug’s use along the scale of 24 h. Original study of Yoshihiko Watanabe. © Halberg.
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Figure 20. The usefulness of a chronobiologic approach is supported by the demonstration that treatment with
antihypertensive drugs can be optimized by timing. The same dose of the same drug can have different effects
on the MESOR and circadian amplitude of the same patient’s blood pressure when it is administered daily at
a different circadian stage as seen by the naked eye and documented by parameter tests. © Halberg.
Figure 21. The chronobiological approach includes inferential statistical methods for the rigorous assessment of intervention
effects applicable to the individual patient, e.g., detecting whether the lowering in the MESOR of systolic (left) and diastolic
(right) blood pressure can be associated with the time when the change in treatment timing was instituted. © Halberg.
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Figure 22. A curtain of uncertainty, because of limited available data, hides any time- and geographic (geomagnetic or dipmagnetic)
site-specificity of various spectral aspects of sudden cardiac death. Thus, we find a transyear (T) in Minnesota with
a cis-half-year (cY/2) and both a calendar year (Y) and a transyear in Arkansas and the Czech Republic: at the latter site, a cis-halfyear,
corresponding in length to an also-transient period of hard solar flares, is detected after but not before 1999. Whether other
geographic differences in sudden cardiac death may also relate to any magnetic latitude deserves scrutiny. It is noteworthy in any
event that cardiac arrhythmias can also transiently reveal a transyear or a cis-half-year, each in a different solar Schwabe cycle stage.
Note site-specificity in the frequency domain displayed by patterns of sudden cardiac death worldwide. Time-specificity
is seen at bottom left in the Czech Republic. Rhythms (spectral components) with one or several widely differing periods
are found even when focusing solely upon the USA. (A phase difference of changes mirroring a didecadal [Hale sunspot
bipolarity] cycle in newborns’ body weight in Minnesota vs. Denmark is documented by millions of cases; it shows
that the local setting on earth, while depending upon input from the sun, also plays a major role.) © Halberg.
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Figure 23A. Daily incidence of suicide by day of death in the two genders in Minnesota (1979–2007). In addition to a circannual
and circasemiannual variation, a far-transyear is detected by least squares spectra, with a slightly different period in
males (~1.28 years) and females (~1.43 years). A near-transyear is detected in females but not in males. © Halberg.
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Figure 23B. Suicides in Australia by day of death and gender. The circannual component is prominent in males
but not in females. A far-transyear is detected for both genders, albeit with different periods. © Halberg.
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Figure 23C. Suicides in Bulgaria by day of death. In addition to the prominent year,
the ­half-year, a transyear and a cis-half-year are also detected. © Halberg.
Figure 23D. Suicides in England and Wales by day of birth reveal a different spectrum
without the transyears found in Minnesota by day of death. © Halberg.
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Figure 24. The Kondratiev and Hale cycles are mirrored in US homicides. © Halberg.
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Figure 25. A gliding (local, left) and aligned overall (global, right) spectral window (A, left) show similarities in the paraannual
region, a transyear around 1.33 years in solar wind speed (SWS, top), the antipodal geomagnetic disturbance index
(aa, middle), and in the incidence of terrorism in the MIPT’s (Memorial Institute for the Prevention of Terrorism) 39-yearold
database (bottom). Phases of a chronomic serial section is shown for the transyear at the average period among the three
variables (B, right). The transyear is observed to be particularly prominent in all three variables during solar cycle 22, as seen
from the darker shading at a frequency of one cycle in about 1.33 years. Changes with time of the phase of the transyear
component indicate further that statistical significance for terrorism relatively shortly follows (with only a lag) that in solar
wind speed and geomagnetism and that it may persist after statistical significance is lost for the two environmental variables.
Despite some expected wobbliness, the transyear appears to be relatively stable in all variables during most of solar cycle 22.
The fact that a predictable cycle characterizing the incidence of terrorism is also present in the physiology of individuals
renders it amenable to monitoring by a population marker rhythm for further scrutiny and for the eventual design of rational
countermeasures against undesirable effects of the cosmos. Gliding spectra prepared by Prof. George S. Katinas. © Halberg.
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Figure 26. In data then available from the Memorial Institute for the Prevention of Terrorism’s
(MIPT) Terrorism Knowledge Base (1968–2008) (http://www.tkb.org/) (top), a transyear of
~ 1.3 years is detected in the absence of a calendar year component. © Halberg.
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Figure 27. Proposed biospheric contributions to the understanding, if not prediction of earthquakes. Upper left: Locomotor activity
of some of the mice telemetered around the clock was statistically significantly decreased starting 3 days prior to the magnitude
8.0 earthquake in Chengdu, China on 12 May 2008. Upper right: Human systolic blood pressure started increasing 2 days prior to
the magnitude 9.0 earthquake in Sendai, Japan on 11 March 2011, documented on the basis of weeklong records of around-theclock
ambulatorily obtained data from 13 Japanese. Similar records from longitudinal and transverse controls differ in their time
course, suggesting that the trend observed before the earthquake was related to it rather than being a feature of an anticipated
weekly pattern. Lower left: The monthly incidence of major earthquakes since 1900 is characterized by the presence of cycles
with periods of about 49.3, 12.2, 1.44, and 0.41 year(s), given with their uncertainties in parentheses. Lower right: The prominent
about–50-year cycle is also documented in physiology, pathology, societal upheavals and space weather. Nonlinearly estimated
periods are displayed with their 95% confidence intervals shown as the length of corresponding horizontal bars. © Halberg.
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Figure 28A. Frame on lower right half lists some components of the transdisciplinary set of cyclic components
found in the bio- and/or in the litho-, hydro-, atmo-, iono-, helio-, magneto- and cosmospheres, underlying
a time-structured sphere of the human mind (Attic Gk nous), the chronousphere. © Halberg.
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Figure 28B. Signatures of the cosmos with validated statistical significance of anticipated periods characterize: a. dozens of
decades-long time series of human blood pressure and heart rate; b. other physiology and psychology, including human mental
functions; c. religious proselytism; d. suicide; e. sudden cardiac death; f. terrorist activity for the past 39 or 41 years; g. 2,556
years of international battles compiled by Raymond Holder Wheeler; h. military expenditures for training in non-medical science;
i. degrees earned; j. Gallup Polls; and k. political and military actions in nearly 200 years, meta-analyzed from the much broader
treasure of data compiled by Alexander Leonidovich Chizhevsky. While chance can never be ruled out, it would be further greatly
reduced by systematic lifetime monitoring of physiology in health, of pathology and disease, notably in archives to separate effects
of sun, tides and earth, many of which are beneficial. Other effects such as extreme cold and heat or extreme light can be met by
countermeasures such as housing, heating and air conditioning. The task remains to develop countermeasures to those nonphotic
effects that can be documented as harmful. While the earth is the immediate actor, and for that action the sun is the modulator, the
biosphere reacts directly, yet sometimes selectively to only one (or both) terrestrial and lunisolar factors, the tides, as well as natural
and artificial light competing with each other under certain circumstances, as seen in patient JF, Figures 28C–G. There may be other
more subtle effects of synchronized human action upon the earth. Effects of the moon, contributing about two-thirds of the tides,
are thus also demonstrated, Figure 25C–G. The roles of actor, reactor and modulator are continuously changing. In the greenhouse
effect, organisms are the actors, as shown by a double-headed arrow (B2
). Original compilation by Mary Sampson. © Halberg.
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Figure 28C. Chronomic serial section of self-rated vigor-wellness of JF, a woman 61 years of age at start of study
during the first 14 lunar months of investigation, revealing extreme changes in vigor and mostly a lack of statistical
significance of 24.0-h (row 4) and 2.48-h (row 6) cosine fits. Lunar cycles 4 and 11, the first months of the first two
episodes of depression investigated, are characterized by a delaying acrophase in lunar cycles 4 and 11 when a 24-h
cosine is fitted and is anticipated by a horizontal time course with a 24.84-h cosine fit in rows 3 and 5 respectively.
Each first month of an adynamic episode in nonlinear analyses is characterized by a 24.8-h period twice in succession,
never found by us earlier (also further in other variables of JF during adynamic episodes). © Halberg.
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Figure 28D. Self-measurements of systolic blood pressure of JF, from lunar cycles (vertical dashed lines) 4 to 8 inclusive, followed
by automatic monitoring in lunar cycle 8. Original data on top reveal lack of lower values during rest/sleep. The lower curve is the
second row of the circadian average (MESOR), which is higher during measurements restricted to wakefulness. The circadian
amplitude, the distance between the two curves in the second row, is small and not statistically significant, as seen from the
penultimate row of P-values for rejection of the zero 24-h amplitude assumption in cycles 4-8. Note acrophases in row 3, shown
with 95% confidence interval when statistical significance is reached, i.e., as soon as automatic measurements start in lunar cycle
9 to the end. Their time course continues in alternation horizontally (during wellness) and upward diagonally (during adynamia),
thereby indicating a changing dominance between the 24-h synchronized and desynchronized circadian variation. © Halberg.
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Figure 28E. Competition of 24.0-h and 24.8-h periods in JF’s blood circulation with 24-h
periods during spans of wellness and longer periods during illness. © Halberg.
Figure 28F. Competition of 24.0-h and 24.8-h periods in JF’s endocrines with 24-h dominance
during wellness and the tides pulling most during illness. © Halberg.
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Figure 28G. C-ABPM monitors circadian ecfrequentia of JF (left) by comparison
to a gender- and age-matched control, GC. © Halberg.
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Figure 28H. Distribution of period estimates, ts (histograms on left, individual results on right, shown with their 95% confidence
intervals) displayed as a function of time (upward) along the ordinate for a 54–60-year-old woman (GC), based on aroundthe-clock
~24-h/7-day records at 30-minute intervals. Monthly summaries of a patient’s (JF’s) t and CI during “downtimes”
(shaded) and outside such episodes of loss of vigor are shown (right, top of each section). The first winter adynamia (shaded)
is characterized for SBP by two consecutive ts longer than 24.8 h for JF, a finding not seen in GC. For all three of GC’s
variables, desynchronized ts are rare, and are absent in a sequence, while in JF’s second upper adynamic episode, based on
automatic measurements, desynchronization from society is the rule: the CIs of ts invariably fail to cover 24 h. © Halberg.
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Figure 29A. Selective transdisciplinary congruence in the spectral region around one week. © Halberg.
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Figure 29B. Combination of gliding spectral window (top) with special focus on the behavior of two selected periods
(middle and bottom), with the time course of the phase validating the 6.77-day period by a more or less horizontal
trajectory of phases in only part of the record, but invalidating a precise 7-day periodicity since no dots bracket any
horizontal time course of phases, and the small initial section with dots shows a gradual advance. © Halberg.
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Figure 30A. Waxing and waning of the aeolian ~5-month (~0.41-year) cycle in solar flares (top), sunspots (middle) and with a lag in
the heart rate of a clinically healthy man (RBS). Concomitant changes in sudden cardiac death incidence not here shown. © Halberg.
Figure 30B. Near-transyears around us (rows 1–6) and in living matter (rows 7–10). © Halberg.
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Figure 30C. Far-transyears around us (top 10), incidence of myocardial infarctions in Minnesota (MI), and in 43 blood
pressure and heart rate records from 13 subjects who provided longitudinal records covering several years. © Halberg.
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Figure 31A. Paradecadals and paradidecadals, ~10.5- and ~21-year cycles similar in length to the Schwabe and Hale solar activity
cycles characterize a host of biological variables, from micro-organisms to human physiology, pathology, anthropometry
and sociology, assessed from population statistics, yet critically dependent upon also-available individual “pilot studies”.
Such self-experimentation is indispensable for a scrutiny of mechanisms underlying population cycles. © Halberg.
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Figure 31B. Key to Figure 31A. © Halberg.
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Figure 31C. Kondratiev cycle affecting the biosphere. © Halberg.
Figure 32A. Coherence at a period of about 3.5 days is found between the daily standard deviation of hourly neutron monitor
courses from Dourbes, Belgium, and daily values for the inter-micturition interval, urine excretion rate and caffeine metabolite
ratio of a woman (VLG) during social isolation in a cave. The coherence values are 0.90 (P = 0.001), 0.85 (P = 0.006) and 0.77
(P = 0.029) for each variable, respectively, calculated by standard approximate c2
. At a period of about 7 days, similar agreement
is found among the three variables, albeit coherence with the environmental variable is not statistically significant. © Halberg.
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Figure 32B. Multiple coherence findings depend, of course, upon resolution used (54). © Halberg.
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Figure 32C. Cross-spectral coherences are time-varying. © Halberg.
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Figure 32D. Cross-wavelet coherence with Wolf numbers (WN, gauging solar activity, top row) differs between the incidence of
myocardial infarctions in Minnesota (MI, middle row) and the incidence of international terrorist acts (TA, from the total Global
Terrorism Database, bottom row). Whereas a low-frequency component is visible in the wavelet spectra of all three variables (left)
and in the cross-wavelets of MI and TA with WN (middle), only MI (but not TA) shows coherence in this region. © Halberg.
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Figure 33. Anticipated influence of the antipodal index of geomagnetic disturbance aa (top) and of the non-photic environment
(gauged by solar wind speed, an approximation of interplanetary magnetism) on human psychophysiology was assessed by
means of the congruence of periods of their spectral components (defined by overlap of the 95% confidence intervals of the
periods, ts, in the frequency range of one cycle in 2.5 years to 3 cycles per year). The biological data stem from 40 years of
self-measurements of oral temperature (Temp), systolic blood pressure (SBP), diastolic blood pressure (DBP) and heart rate
(HR) and of ratings of mood and vigor and the estimation of 1-minute by counting (1MTE), performed about 5 times a day
by a clinically healthy man, Dr. Robert B. Sothern. Congruences (assessed by means of odds ratios based on the noncentral
hypergeometric distribution) found for 1MTE and for several other variables more than equal that of the known association of
helio- and geo-magnetism (bottom, last column on right of dashed vertical line in blue). Mental functions (full red) show higher
congruence than somatic functions (green). Among the latter, SBP is responsive, perhaps constituting a seemingly acceptable
proxy for the mental functions. P-values are based on the non-central Fisher hypergeometric distribution, with 95% confidence
intervals computed using Fisher’s exact test, used since the null hypothesis was rejected in some, yet not all cases. © Halberg.
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Figure 34. The transyear can prominently characterize solar wind speed, as shown in the top gliding spectral window by the wide
dark band around 1.3 years (vertical scale are frequencies in the range of 1 cycle in 2 to 0.7 year(s)). This component, however, is
Aeolian in nature, its characteristics (frequency and amplitude) changing as a function of time. This is exemplified around 1998 (E)
when its amplitude is considerably decreased (the darker the band, the larger the amplitude is). After E, the transyear is no longer
detected in solar wind speed. A transyear is also found to characterize systolic blood pressure (SBP) of a man (FH) who monitored
himself around the clock for over 23 years (with interruptions), as seen in the gliding spectral window (row 2). With a lag (at E’),
the transyear in FH’s SBP is dampened but remains detectable, suggesting that the frequencies characterizing the solar wind may
still drive us and may be built into us since they persist in the absence of a counterpart in the Sun. Somewhat similar results are
also seen for diastolic blood pressure (DBP, row 3) and heart rate (HR, row 4), but they are most apparent for SBP. © Halberg
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Figure 35. An ~7-day spectral component in the heart rate of five men is less prominent when the solar wind loses its
counterpart of corresponding length. Implied, but not shown, is the persistence in the biosphere of
an ~7-day component that can be amplified (driven) by a reciprocal component in solar activity. © Halberg.
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Figure 36. Another remove-and-replace approach focuses on a weekly component by investigators from the
Republic of Georgia who built a clinical facility to study effects of geomagnetism. © Halberg.
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PHYSICAL THERAPY (PT) CONCERNS IN THE USA COULD LEAD
TO PREHABILITATION COMPLEMENTING REHABILITATION
OTHILD SCHWARTZKOPFF, GERMAINE CORNELISSEN AND FRANZ HALBERG
Halberg Chronobiology Center, University of Minnesota, Minneapolis, MN, USA
The main point from a publication in Physical Therapy 2011 (Nov 11); 91 (11) by Sullivan KJ et al. is described in
its title: “A vision for society by the American Physical Therapy Association [APTA]: physical therapy as partners
[sic] in the national health agenda”. Once PT is recognized as an equal partner in the execution of health care, there
is the urge, and also a necessity, to give PT professionals a broader field of responsibility, a stronger self-awareness
and a better public perception of physical therapy as a doctoring profession. A more affordable health care could also
have an impact on the demand for PT services.
The physical therapist is described as “part of the health care professional workforce, qualified to practice as one of
the ‘health diagnosing and treating practitioners’ ” in the 2010–2011 edition of the US Department of Labor’s Occupational
Outlook Handbook. The aim and desire for the future would be to be part of the health care professional
workforce, qualified to practice, as diagnosing and treating practitioners and to be active also in health promotion.
It will be necessary to advance the professional preparation of the physical therapist to achieve a clinical doctorate
for access and autonomy of care. With it comes professional responsibility, including ethical and moral duty of the
profession, meeting the needs of the society and new responsibilities should be seen as a social contract.
Let us add that, as a first step toward these goals, PT can enter and map the otherwise neglected normal range, in
order to detect variability disorders with modern technology, in particular vascular variability anomalies, VVAs,
disorders, VVDs, and, while VVDs accumulate, vascular variability syndromes, VVSs, mostly new diagnoses to be
acted upon to maintain wellness. As an important first step toward this goal, C-ABPM could detect VVAs and could
be a marker for other variability disorders more generally with respect to the dynamics of the normal range of variation,
which can be explored in time series but not in spotchecks, a challenge already met by the initiation of C-ABPM
in Brno (2–5). Part of the senior author’s (OS) personal monitoring will be demonstrated in a companion presentation
from our institute, documenting technical details. The merits of a glocal (global + local) analysis of time series
(e.g., of paired consecutive daily and weekly summaries of the same data emerge. Artifacts from gaps in the data are
shortcomings. Nonetheless, the possibility of learning about differing solar effects upon different variables of the
same person is noted, as is the plan for pooling results on individuals to also examine the dynamics of populations.
Support: GM-13981 (FH), University of Minnesota Supercomputing Institute (GC, FH)
REFERENCES
1.	 1.Sullivan KJ, Wallace JG Jr, O’Neil ME, Musolino GM, Mandich MB, Studer MT, Bottomley JM, Cormack
JC, Nicholson SK, Jensen GM. A vision for society: physical therapy as partners in the national health agenda.
Physical Therapy 2011; 91(11): 1664-1672.
2.	 Siegelova J, Havelkova A, Dusek J, Pohanka M, Dunklerova L, Cornélissen G, Halberg F. Seven-day ambulatory
blood pressure monitoring and day and night blood pressure variability. J Hypertension 2011;
28 (e-Suppl A): e174
3.	 Siegelova J, Fiser B, Dobsak P, Dusek J, Pohanka M, Cornélissen G, Halberg F. Seven day ambulatory blood
pressure monitoring: ambulatory arterial stiffness index patients after infarctus of myocardium. In: Halberg F,
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Kenner T, Fiser B, Siegelova J, eds. Noninvasive Methods in Cardiology, October 17, 2011, Brno, Czech Republic.
Brno: Faculty of Medicine, Masaryk University. p. 162–173
4.	 Halberg F, Cornelissen G, Otsuka K, Siegelova J, Fiser B, Dusek J, Homolka P, Sanches de la Pena S, Singh RB
and the BOCOS project. Extended consensus on means and need to detect vascular variability disorders and
vascular variability syndrome. World Heart J 2010; 2,4:279–305 (cf. Leibnitz-online Nr.5 ,2009, http://www2.
hu-berlin.de/Leibnitz-sozietaet/journal/archive_5_09.html. 35 pp)
5.	 Halberg F, Cornelissen G, Dusek J, Kenner B, Kenner A, Schwarzkoppf O, Siegelova J. Bohumil Fiser
(*22. 10. 1943 – 21. 3. 2011): Chronobiologist, Emeritus Head of the Physiology Department at Masaryk University
(Brno, Czech Republic), Czech Minister of Health, and Executive Board Member of World Health Organization:
His Legacies for Public and Personal Health Care. World Heart J 2011;3,1:63–77
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INTERNATIONAL PROJECTS “WOMB TO TOMB”
AND “BIOCOS (BIOSPHERE AND THE COSMOS)”
IN HALBERG CHRONOBIOLOGY CENTER,
MINNESOTA: GERMAINE CORNELISSEN
JARMILA SIEGELOVA
Dept. of Physiotherapy and Rehabilitation, Dept. of Sports Medicine and Rehabilitation,
Faculty of Medicine, Masaryk University, St. Ann’s University Hospital in Brno
Prof. Dr. Germaine Cornelissen, Ph.D.
I am honored to be asked to mention the contribution of my friend Prof. Germaine Cornelissen to the chronobiology
in the last thirty years. Prof. Germaine Cornelissen is a long-time coworker of Prof. Franz Halberg in Halberg Chronobiology
Center, University of Minnesota, USA.
Prof. Germaine Cornelissen is professor in the Department of Integrative Biology and Physiology and co-Director of
Halberg University Center, University of Minnesota, Minneapolis, USA from 2008 until now.
Prof. Germaine Cornelissen was born on November 22, 1949 in Brussels. She studied Physics in University of Brussels,
where she graduated in 1971 (M.S. in Physics and M.Ed., University of Brussels). She continued her studies and
in 1976 she obtained the degree Ph.D. in Physics in University of Brussels.
Prof. Cornelissen started studies in her main scientific task - chronobiology in 1976 in the Department of Laboratory
Medicine and Pathology, University of Minnesota, Minneapolis headed by Prof. Franz Halberg, founder of modern
chronobiology. As a fellow (1976–1982) she admired all new scientific approaches and findings in chronobiology, she
used her knowledge in physics and mathematics and applied it to chronobiology. At that time Dr. Germaine Cornelissen
was a very hard working scientist who in the team of Prof. Franz Halberg cooperated with scientists in many
countries and summarized a lot of chronobiological data, covering practice and theory of chronobiology. She was
awarded for her intensive scientific work in chronobiology in 1983 with Hoest Foundation Chronobiologia Award.
From 1982 to 1991 she held the position of Associate and later Assistant Professor (1987–1992) in the Department of
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Laboratory Medicine and Pathology, University of Minnesota, Minneapolis, USA. At that time she was also Member
of the board in International Society for Chronobiology (1985–1995).
In 1990 Prof. Franz Halberg and Prof. Germaine Cornelissen visited for the first time Masaryk University in Brno
and presented chronobiological results in cardiovascular parameters in man on the Brno Symposium. Immediately,
an intensive cooperation started between Brno team, consisting of Prof. Bohumil Fiser, emeritus head of the Physiology
Department, Czech ministry of health, Executive board member of WHO, Dr. Jiri Dusek, me and Prof. Franz
Halberg and Prof. Germaine Cornelissen from University of Minnesota. In Brno we carried out at that time the beatby-beat
noninvasive measurement of blood pressure, developed by Prof. Jan Penaz and young scientist subject Prof.
Fiser, measurement of baroreflex sensitivity and heart rate variability and we had the equipment for ambulatory 24-h
blood pressure monitoring for adults. University of Minnesota lent us equipment for oscilometric measurement of
blood pressure in new born children. At the beginning we started with common scientific work and our data were
measured in the Czech population, at first faxed, later on line via e-mail sent to Chronobiological laboratories in Minnesota,
Halberg Chronobiology Center and analyzed in the University of Minnesota, USA. Then for 22 years until
now the chronobiological data from Brno were immediately analyzed by Prof. Germaine Cornelissen and the results
of these analyses served not only for scientific work, but also for therapy of the Czech population. Between the years
2000 and 2008 the Brno team consisting of Prof. Fiser, Dr. Dusek and me collected 73 888 sets of blood pressure and
heart rate measurements and all data were in the following day analyzed by Prof. G. Cornelissen. The daily data exchange
and analysis continues until now. Very important chronobiological data are found in new born children blood
pressure, in blood pressure changes after administration of low dose aspirin, in baroreflex sensitivity, in groups of
normotensive subjects and hypertensive patients with antihypertensive therapy and without therapy. The cooperation
resulted in a lot of common publications.
From 1990 every year, sometimes two times per year, common meetings were organized in Brno, such as MEFA Congress
or chronobiological congress presenting a lot of latest findings and scientific lectures, with the participation
of Prof. Cornelissen, Prof. Halberg from Minnesota, Prof. Thomas Kenner, former president of University of Graz,
Austria and Prof. J.P. Martineaud, Hopital Lariboisiere, Medical Faculty Paris, France. Prof. Germaine Cornelissen
prepared a lot of publications for congresses and symposia in Brno.
The Brno team visited Minnesota in 1995 and at that time Prof. Germaine Cornelissen together with the Brno team
evaluated two ambulatory monitors when the scientists measured themselves. The scientific team placed blood
pressure cuffs on both arms and carried it fourteen days. The results were evaluated and published also by Prof.
Cornelissen.
In 1987 Prof. Cornelissen was appointed the secretary in North American branch of the International Society for Research
on Civilization Diseases and the Environment (SRMCE). She summarized and published a lot of papers about
risks of civilization in morbidity and mortality of cardiovascular diseases. In 1994 Prof. Cornelissen became coordinator
of international chronobiology project Womb-to-Tomb Study, now BIOCOS (BIOsphere and the ­COSmos).
The Brno team is a member of both international projects.
On November 22, 1994 BIOCOS was described for the first time. The Biosphere and the Cosmos, BIOCOS, as the
task of building a novel transdisciplinary spectrum was pursued, and further periods of decades, centuries, and
thousands and millions of years were documented. Much of the evidence was provided very successfully by Germaine
Cornelissen, Ph.D., Professor of Integrative Biology and Physiology at the University of Minnesota.
Scientific capabilities of Prof. Cornelissen were appreciated by a number of awards, citations and membership in
scientific organizations. Prof. Cornelissen is Member of Sigma Xi Society since 1988, Member of Editorial Board of
Chronobiologia from 1989 to1991, of Editorial Board of Il Policlinico from 1991 to 1996, contributes to Neuroendocrinology
Letters since 1999, Geronto-Geriatrics since 1999, Journal of Applied Biomedicine since 2006, World
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Heart Journal since 2007, Journal of Experimental Therapeutics and Oncology since 2010, was Co-Editor of Chronobiologia
from 1991 to 1994, Guest Editor of Psychophysiology (1992), Neuroendocrinology Letters (2003), The
Open Nutriceuticals Journal (2012), was on Board of Directors, Underlab Project (Ancona, Italy) (1993–1996), has
been Member Book Committee, National Chapters of Phi Beta Kappa since 2000. She became Honorary Member of
Cardiff Scientific Society (2002), Advisory Board in International College of Nutrition and International College of
Cardiology, MEODEA, Moradabad, India (2005), Foreign Member of Problem Commission on Chronobiology and
Chronomedicine in Russian Academy of Medical Sciences (2006), Member of Leibniz Society, former Academy of
Science of the German Democratic Republic (2009), Member of International Academy of Science (2010).
Prof.CornelissenparticipatedinmanyinternationalCongressesandSymposiaandworkshops.In2008Dr. ­Germaine
Cornelissen was appointed Professor in Department of Integrative Biology and Physiology, and co-Director of Halberg
Chronobiology Center, University of Minnesota, Minneapolis, USA. Prof. Cornelissen crossed from physics
to biomedicine and added a lot of transdisciplinary information. In chronobiology one of her most important challenges
remains, in all zones on earth and beyond, to be the exploitation of vascular variability disorders in man for a
universal preventive health care based on cyber-implemented self-help in collecting time series of chronobiological
measurement for the multiple Chronobiologic purposes the time series of biological data may serve in health care to
minimize the cardiovascular evence like stroke, infarctus of myocardium and other serious diseases in prevention
for individuals first and foremost.
Profits of her many chronobiological analyses of data from all over the world relate both to medical and transdisciplinary
research. Medically, by her analyses of data, she compares the relative merits of harbingers of risk. In addition,
she seeks an understanding of the effects of the sun in dealing with aggression and other diseases of society.
The effects of the sun on living organism and man are now shown by Prof. Cornelissen and are documented in many
chronobiological papers.
I thank prof. Germanine Cornelissen for a long lasting cooperation with Masaryk University and I hope for the continuation
for the future.
SELECTED PUBLICATIONS
1.	 	 Cornelissen G., Halberg F., Přikryl P., Daňková E., Siegelová J., Dušek J.: Prophylactic aspirin treatment:
The  merits of timing. JAMA 266, 1991:3128–3129
2.	 	 Cornélissen G, Prabhakaran Nayar SR, Czaplicki J, Siegelova J, Mendoza B, Halberg F. Brückner-EgesonLockyer
(BEL) cycle in heliogeomagnetics. In: Halberg F, Kenner T, Fiser B, Siegelova J (Eds.) Proceedings,
Noninvasive Methods in Cardiology, Brno, Czech Republic, Oct. 4–7, 2008. p. 106–115. http://web.fnusa.cz/
files/kfdr2008/sbornik_2008.pdf
3.	 	 Cornélissen G., Breus T.K., Bingham C., Zaslavskaya R., Varshitsky M., Mirsky B., Teibloom M., Tarquini
B., Bakken E., Halberg F., International Womb-to-Tomb Chronome Initiative Group: Beyond circadian chronorisk:
worldwide circaseptan-circasemiseptan patterns of myocardial infarctions, other vascular events, and
emergencies. Chronobiologia 20: 87–115, 1993
4.	 	 Cornélissen G., Halberg F. Introduction to Chronobiology. Medtronic Chronobiology Seminar #7, April 1994,
52 pp. (Library of Congress Catalog Card #94-060580; http://revilla.mac.cie.uva.es/chrono)
5.	 	 Cornélissen G., Halberg F. Impeachment of casual blood pressure measurements and the fixed limits for their
interpretation and chronobiologic recommendations. Ann. N.Y. Acad. Sci. 783: 24–46, 1996
6.	 	 Cornélissen G., Halberg F. Chronomedicine. In: Encyclopedia of Biostatistics, Armitage P., Colton T. (editorsin-chief),
v. 1, John Wiley & Sons Ltd., Chichester, UK, 1998, pp. 642–649. 2nd
ed. Chichester, UK: John Wiley
& Sons Ltd; 2005. p. 796–812
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7.	 	 Cornélissen G., Halberg F., Schwartzkopff O., Delmore P., Katinas G., Hunter D., Tarquini B., Tarquini R.,
Perfetto F., Watanabe Y., Otsuka K. Chronomes, time structures, for chronobioengineering for “a full life”.
Biomedical Instrumentation & Technology 33: 152–187, 1999
8.	 	 Cornélissen G, Schwartzkopff O, Halberg F, Otsuka K, Watanabe Y. 7-day ambulatory monitoring for adults
with hypertension and diabetes [letter]. Am J Kidney Diseases 2001; 37: 878
9.	 	 Cornélissen G, Halberg F, Breus T, Syutkina EV, Baevsky R, Weydahl A, Watanabe Y, Otsuka K, Siegelova J,
Fiser B, Bakken EE. Non-photic solar associations of heart rate variability and myocardial infarction. J Atmos
Solar-Terr Phys 2002; 64: 707–720
10.	 	 Cornélissen G, Masalov A, Halberg F, Richardson JD, Katinas GS, Sothern RB, Watanabe Y, Syutkina EV,
Wendt HW, Bakken EE, Romanov Y. Multiple resonances among time structures, chronomes, around and
in us. Is an about 1.3-year periodicity in solar wind built into the human cardiovascular chronome? Human
Physiology 2004; 30 (2): 86–92
11.	 	 Cornélissen G, Halberg F, Otsuka K, Singh RB, Chen CH. Chronobiology predicts actual and proxy outcomes
when dipping fails. Hypertension 2007; 49: 237–239. doi: 10.1161/01.HYP.0000250392.51418.64
12.		 Hoogerwerf WA, Hellmich HL, Cornélissen G, Halberg F, Shahinian VB, Bostwick J, Savidge TC, Cassone
VM. Clock gene expression in the murine gastrointestinal tract: endogenous rhythmicity and effects of a feeding
regimen. Gastroenterology 2007; 133: 1250–1260
13.	 	 Refinetti R, Cornélissen G, Halberg F. Procedures for numerical analysis of circadian rhythms. Biological
Rhythm Research 2007; 38 (4): 275-325. http://dx.doi.org/10.1080/09291010600903692. NIHMSID: 249029
14.		 Gupta AK, Greenway FL, Cornélissen G, Pan W, Halberg F. Prediabetes is associated with abnormal circadian
blood pressure variability. J Human Hypertension 2008; 22: 627–633. doi:10:1038/jnh.2008.32
15.	 	 Halberg F, Cornélissen G, Sothern RB, Katinas GS, Schwartzkopff O, Otsuka K. Cycles tipping the scale
­between death and survival (= “life”). Progress of Theoretical Physics 2008; Suppl. 173: 153–181
16.		 Cornélissen G, Grambsch P, Sothern RB, Katinas G, Otsuka K, Halberg F. Congruent biospheric and solarterrestrial
cycles. J Appl Biomed 2011; 9: 63–102. DOI 10.2478/v10136-009-0023-7
17.	 	 Pan W, Wu X, Kastin AJ, Zhang Y, Hsuchou H, Halberg F, Chatu F, Khan RS, Robert B, Cornélissen-Guillaume
GG. Potential protective role of IL15Ra during inflammation. J Mol Neurosci 2011; 43: 412–423
18.		 Cornélissen G, Grambsch P, Halberg F. Editorial. World Heart J 2011; 3: 123–134
19.	 	 Cornélissen G, Burioka N, Halberg F. Other-than-annual variaions in morning determinations of uric acid
[editorial]. Clin Chem Lab Med 2012; 50: 765–770
20.		 Cornélissen G. When you eat matters: 60 years of Franz Halberg’s nutrition chronomics. The Open Nutraceuticals
J 2012; 5 (Suppl. 1-M2): 16–44
21.	 	 Siegelova J., Prikryl P., Dusek J., Cornélissen G., Halberg F. Der Vergleich von circadianen rhythmischen
Schwankungen bei Hypertonikern und Normotonikern. Abstract, 14. Tagung der Wissenschaftlichen Sektion
der Deutschen Liga zur Bekämpfung des hohen Blutdruckes, Ulm, FRG, Nov. 29–Dec. 1, 1990
22.		 Prikryl P, Siegelova J, Cornélissen G, Dusek J, Dankova E, Fiser B, Vacha J, Ferrazzani S, Tocci A, Caruso
A, Rao G, Fink H, Halberg F, International Womb-to-Tomb Chronome Initiative Group: Chronotherapeutic
pilot on 6 persons may guide tests on thousands: Toward a circadian optimization of prophylactic treatment
with daily low-dose aspirin. University of Minnesota/Medtronic Chronobiology Seminar Series, #3, December
1991, 4 pp. text, 4 figures
23.		 Siegelova J., Fiser B., Dusek J., Cornélissen G., Halberg F. 24-Stunden-Baroreflex-Sensitivitätsmessung bei
normotonen Personen. Hochdruck 11: 101, 1991
24.		 Siegelova J., Fiser B., Dusek J., Cornélissen G., Halberg F. Baroreflex sensitivity during 24 hours. Scripta medica
(Brno) 64: 186, 1991
25.		 Fiser B., Siegelova J., Dusek J., Cornélissen G., Halberg F. Baroreflex heart rate sensitivity during 24 hours
period evaluated by spectral analysis of blood pressure record. Scripta medica (Brno) 65: 315, 1992
26.		 Fiser B., Siegelova J., Dusek J., Cornélissen G., Halberg F. Cosinor analysis of baroreceptor heart rate sensitivity
during 24-hour period. Arch. Int. Physiol. Biochim. Biophys. 100: A87, 1992
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27.		 Fiser B., Siegelova J., Dusek J., Halberg F., Cornélissen G. Circadian variation of baroreflex heart rate sensitivity
in man. Abstract, IV International Symposium on Control of Heart Rhythm, Slovak Academy of Sciences,
Smolenice Castle, April 6–9, 1992, #11
28.		 Fiser B., Siegelova J., Dusek J., Halberg F., Cornélissen G. Is the circadian variability of baroreflex dependent
upon sleep? Abstract, 6th
Int. Cong. Psychophysiology, Charité, Berlin, Germany, Sept. 2–6, 1992, p. 63
29.		 Prikryl P., Prikrylova P., Halberg F., Siegelova J., Dusek J., Karpisek Z. Profylaxe kardiovaskulárnich chorob
kyselinou acetylosalicylovou: chronobiologická multicentrální studie. Abstract, XX Celostátní Internisticky
Kongres s Mezinárodní Ucasti Zlin, 1992, p. 60
30.		 Siegelova J., Fiser B., Dusek J., Cornélissen G., Halberg F. Analysis of time parameters of respiratory cycle during
24 hours. Arch. int. Physiol. Biochim. Biophys. 100: A130, 1992
31.	 	 Siegelova J., Fiser B., Dusek J., Cornélissen G., Halberg F. Conscious state and control of breathing: power
spectral density of respiratory and cardiovascular parameters. Abstract, 6th
Int. Cong. Psychophysiology,
Charité, Berlin, Germany, Sept. 2–6, 1992, p. 219
32.		 Siegelova J., Fiser B., Dusek J., Cornélissen G., Halberg F. Noninvasive determination of baroreflex heart rate
sensitivity in patients with mild hypertension during 24-hours. Abstracts, 14th
Scientific Meeting, International
Society for Hypertension, Madrid, June 14–19, 1992, p. 326
33.	 	 Siegelova J., Fiser B., Dusek J., Cornélissen G., Halberg F. Spectral analysis of the timing of respiratory cycle
and cardiovascular parameters during 24 hours period. Abstract, 2nd
High Tatras International Health Symposium:
Health Management, Organization, and Planning in Changing Eastern Europe, Strbské Pleso, CzechoSlovakia,
October 16–18, 1992, p. 38
34.		 Siegelova J., Fiser B., Dusek J., Halberg F., Cornélissen G. Circadian variations of baroreflex heart rate sensitivity
in man. Physiological Research 41: 15 pp., 1992
35.	 	 Siegelova J., Fiser B., Dusek J., Halberg F., Cornélissen G. Control of respiratory cycle during 24-hours period.
Abstract, 13th Martin’s Days of Respiration, Martin, September 7–8, 1992, p. 16
36.		 Siegelova J., Fiser B., Dusek J., Semrád B., Halberg F., Cornélissen G. 24-hodinové monitorování krevního
tlaku u pacientu s esenciálni hypertenzí. Abstract, XX Celostátní Internisticky Kongres s Mezinárodní Ucasti
Zlin, 1992, p. 64
37.	 	 Siegelova J., Fiser B., Dusek J., Semrád B., Mayer P., Sevela K., Halberg F., Cornélissen G. Circadian variations
of blood pressure in patients with essential and nephrogen hypertension. Scripta medica (Brno) 65: 316, 1992.
38.		 Siegelova J., Fiser B., Sevela K., Dusek J., Mayer P., Halberg F., Cornélissen G. 24-hodinové monitorování
krevního tlaku u pacientu s nefrogenné hypertenzí lecenych aceprilem. Abstract, XX Celostátní Internisticky
Kongres s Mezinárodní Ucasti, Zlin, 1992, p. 65
39.	 	 Dusek J., Siegelova J., Fiser B., Al-Kubati M., Cornélissen G., Halberg F. Noninvasive determination of baroreflex
heart rate sensitivity in patients with essential hypertension during 24 hours. Abstract 173.38/P, IUPS
Congress, Glasgow, 1993, p. 79
40.		 Fiser B., Siegelova J., Dusek J., Cornélissen G., Halberg F. Is the circadian variability of baroreflex dependent
upon sleep? Int. J. Psychophysiol. 14: 122, 1993
41.	 	 Fiser B., Siegelova J., Dusek J., Cornélissen G., Halberg F. Determination of heart rate-baroreflex sensitivity in
man by spectral analysis during 24-hour period. Scripta medica (Brno) 66: 11–14, 1993
42.		 Fiser B., Siegelova J., Dusek J., Al-Kubati M., Cidl K., Semrád B., Cornélissen G., Halberg F. Determination of
baroreflex heart rate sensitivity in patients with essential hypertension during 24 hours using vasodilatation
method. Proceedings, 1st
Int. Fair of Medical Technology and Pharmacy, Brno, Czech Rep., November 3–6,
1993, Kenner T., Marineaud J.P., Mayer P., Semrád B., Siegelova J., Fiser B. eds., pp. 43–52
43.	 	 Prikryl P, Siegelova J, Cornélissen G, Dusek J, Dankova E, Ferrazzani S, Tocci A, Caruso A, Rao G, Fink H,
Halberg F. Chronotherapeutic pilot on 6 persons may guide tests on thousands: toward a circadian optimization
of prophylactic treatment with daily low-dose aspirin. In: Otsuka K, Cornélissen G, Halberg F, editors.
Chronocardiology and Chronomedicine: Humans in Time and Cosmos. Tokyo: Life Science Publishing; 1993.
p. 113–117
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44.		 Siegelova J., Fiser B., Dusek J., Cornélissen G., Halberg F. Conscious state and control of breathing power
spectral density of respiratory and cardiovascular parameters. Int. J. Psychophysiol. 14: 149–150, 1993
45.	 	 Siegelova J., Fiser B., Dusek J., Mayer P., Semrad B., Halberg F., Cornélissen G. Cirkadianni variabilita krevniho
tlaku u pacientu v administrative. “Clovek a technika ocima ergonoma”, Sbornik, Vysoka skola zemedelska,
Brno, 1993, pp. 30–37
46.		 Siegelova J, Fiser B, Dusek J, Semrád B, Cidl K, Sevela K, Halberg F, Cornélissen G. Blood pressure monitoring
in patients with essential hypertension during 24-hour. In: Kenner T, Marineaud JP, Mayer P, Semrád B,
Siegelova J, Fiser B, editors. Proceedings, 1st
Int. Fair of Medical Technology and Pharmacy, Brno, Czech Rep.;
November 3–6, 1993. p. 53–59
47.	 	 Siegelova J., Fiser B., Dusek J., Semrád B., Cornélissen G., Halberg F. Baroreflex heart rate sensitivity measurement
in patients with essential hypertension (I WHO) during 24-hour period. Proceedings, 1st
Int. Fair of
Medical Technology and Pharmacy, Brno, Czech Rep., November 3–6, 1993, Kenner T., Marineaud J.P., Mayer
P., Semrád B., Siegelova J., Fiser B. eds., pp. 36–39
48.		 Siegelova J., Fiser B., Dusek J., Mayer P., Halberg F., Cornélissen G. Circadian variation of baroreflex heart rate
sensitivity using non-invasive determination in healthy subjects. Proceedings, 1st
Int. Fair of Medical Technology
and Pharmacy, Brno, Czech Rep., November 3–6, 1993, Kenner T., Marineaud J.P., Mayer P., Semrád B.,
Siegelova J., Fiser B. eds., pp. 12–19
49.	 	 Siegelova J., Fiser B., Dusek J., Semrad B., Halberg F., Cornélissen G. 24-hodinove monitorovani krevniho
tlaku u pacientu s esencialni hypertenzi. Vnitr. Lek. 39: 183–190, 1993
50.	 	 Siegelova J, Fiser B, Dusek J, Sevela K, Halberg F, Cornélissen G. Circadian variability of blood pressure in
patients with essential hypertension and nephrogenous hypertension treated with enalapril. Scripta medica
(Brno) 1993; 66: 99–104
51.	 	 Siegelova J., Fiser B., Dusek J., Cornélissen G., Halberg F. Spectral analysis of the timing of respiratory cycle
and cardiovascular parameters during 24 hours period. 2nd
High Tatras International Health Symposium:
Health Management, Organization, and Planning in Changing Eastern Europe, Strbske Pleso, Czecho-Slovakia,
October 16–18, 1992, New York, Bratislava, 1993, pp. 71–78
52.		 Cornélissen G, Bingham C, Siegelova J, Fiser B, Dusek J, Prikryl P, Sonkowsky RP, Halberg F. Cardiovascular
disease risk monitoring in the light of chronobioethics. Chronobiologia 1994; 21: 321–325
53.	 	 Cornélissen G., Halberg F. Chronobiology of blood pressure: international cooperation with Dr. Jarmila Siegelova,
Dr. Jiri Dusek and Dr. Bohumil Fiser of Masaryk University. Scripta medica (Brno) 67 (Suppl. 1): 7–8,
1994
54.		 Cornélissen G, Sothern RB, Wendt HW, Tarquini B, Antuñano M, Siegelova J, Fiser B, Dusek J, Prikryl P,
Halberg F. Statistical significance without biologic signification is not enough: illustrative example. Chronobiologia
1994; 21: 315–320
55.	 	 Dusek J., Siegelova J., Fiser B., Cornélissen G., Halberg F. Chronobiology of blood pressure in waking man under
light mental load. Proc. Workshop, Chronobiology in Health and Disease—Control of Cardiovascular and
Respiratory Functions, Medical Faculty, Masaryk University, Brno, Czech Republic, July 2–4, 1994, pp. 33–37
56.		 Halberg F, Bingham C, Siegelova J, Fiser B, Dusek J, Prikryl P, Sonkowsky RP, Cornélissen G. “Cancer marker
chronomes” assessed in the light of chronobioethics. Chronobiologia 1994; 21: 327–330
57.	 	 Siegelova J., Fiser B., Al-Kubati M., Dusek J., Cornélissen G., Halberg F. Airway resistance and cardiovascular
parameters during a 24-hour period. In: Proceedings, 3rd
High Tatras International Health Symposium, Preventive
and Clinical Medicine in Changing Europe, Salat D., Badalik L., Krcmery V. (eds.), Sympos, Tatranska
Polianka, Slovak Republic, 1994, pp. 386–391
58.		 Siegelova J., Fiser B., Dusek J., Cornélissen G., Halberg F. Chronobiology of blood pressure in essential hypertension.
Proc. Workshop, Chronobiology in Health and Disease—Control of Cardiovascular and Respiratory
Functions, Medical Faculty, Masaryk University, Brno, Czech Republic, July 2–4, 1994, pp. 13–25
59.	 	 Siegelova J., Fiser B., Dusek J., Cornélissen G., Halberg F. Cosinor analysis of 24-hour variations of respiratory
and cardiovascular values in awake healthy man. Abstract, XIV Martin’s Days of Respiration, September 6–7,
1994, Martin, Czech Rep. (?), p. 6
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60.		 Siegelova J., Fiser B., Dusek J., Halberg F., Cornélissen G. Cosinor analysis of blood pressure in patients
with essential and nephrogenous hypertension. Proc. International Workshop, Sun, Moon and Living Matter,
Mikulecky M. (ed.), Bratislava, Slovakia, June 29–July 1, 1994. Slovak Medical Society, Bratislava, 1994,
pp. ­116–121
61.	 	 Siegelova J., Fiser B., Dusek J., Halberg F., Cornélissen G. Posobeni bdelehu stavu a lehke mentalni zateze
na cirkadianni variabilitu krevniho tlaku a zdravych osob. Ceska Ergonomicka Spolecnost uzemni organizace
Brno a katedra automobilu Vojenske akademie v Brne, Seminar: Cesty Rozvoje a Uplatnovani Ergonomie
a Bezpecnosti Prace v Podminkach Denni Praxe, 25 kvetna 1994, pp. 17–24. [In Czech.]
62.		 Dusek J., Siegelova J., Fiser B., Cornélissen G., Halberg F. Chronobiology of blood pressure in waking man
under light mental load. Scripta medica (Brno) 68: 62–63, 1995
63.	 	 Dusek J., Siegelova J., Nekvasil R., Cornélissen G., Halberg F. Circaseptan rhythm in blood pessure and heart
rate in newborns. Abstract, MEFA ’95 Congress, Brno, Czech Republic, October 24–27, 1995, p. 10
64.		 Dusek J., Siegelova J., Fiser B., Nekvasil R., Cornélissen G., Halberg F. Blood pressure variations in newborns.
Abstract #64, 1st
Congress, Federation of European Physiological Societies, September 9–12, 1995, Maastricht,
The Netherlands. Pflügers Archiv / Eur. J. Physiol. 430 (Suppl.): R24, 1995
65.	 	 Halberg F, Cornélissen G, Johnson D, Wrbsky P, Portela A, Beystrom B, Siegelova J, Fiser B, Dusek J, Nekvasil
R, Syutkina EV, Grigoriev AE, Abramian A, Mitish M, Yatsyk GV, Revilla M, Ardura J, Garcia Alonso L, Bakken
E, Delmore P, Maggioni C, Tarquini B, Mainardi G, Otsuka K, Watanabe Y, Kumagai Y, Wakasugi K, Saito
Yuzo, Tamura K. Chronobiologic environmental optimization starting with neonatal care: opportunities for
health and device industries. Handout, The Physical and Developmental Environment of the High-Risk Infant,
Orlando, Florida, January 19–21, 1995, 70 pp
66.		 Halberg F, Cornélissen G, Raab F, Schaffer E, Siegelova J, Fiser B, Dusek J, Prikryl P, Otsuka K. Automatic
physiologic 7-day monitoring and chronobiology. Jpn J Electrocardiol 1995; 15 (Suppl. 1): S-1-5–S-1-11
67.	 	 Halberg F, Cornélissen G, Siegelova J, Fiser B, Dusek J, Prikryl P, Otsuka K. Automatic physiology 7-day monitoring
and chronobiology. Policlinico (Chrono) 1995; 1 (2): 33–42
68.		Siegelova J, Cornélissen G, Dusek J, Prikryl P, Fiser B, Dankova E, Tocci A, Ferrazzani S, Hermida R,
­Bingham C, Hawkins D, Halberg F. Aspirin and the blood pressure and heart rate of healthy women. Policlinico
(Chrono) 1995; 1 (2): 43–49
69.	 	 Siegelova J., Fiser B., Dusek J., Cornélissen G., Halberg F. Cosinor analysis of 24-hour blood pressure profile
in hypertensives before and after treatment with ACE-inhibitor enalapril. EuroRehab 4: 203–206, 1995
70.	 	 Siegelova J., Fiser B., Dusek J., Cornélissen G., Halberg F. Chronobiology of blood pressure in essential hypertension.
Scripta medica (Brno) 68: 60–61, 1995
71.	 	 Cornélissen G, Halberg F, Johnson D, Gubin D, Gubin G, Otsuka K, Watanabe Y, Kumagai Y, Syutkin V,
Syutkina E, Grigoriev AE, Turti T, Mitish M, Siegelova J, Fiser B, Dusek J, Garcia Alonso L. Blood pressure
and heart rate chronomes, yardsticks of ontogeny and vascular disease risk. Keynote #114, 2nd
World Congress
of Cellular and Molecular Biology, Ottawa, Canada, September 3–7, 1996. Cell Molec Biol 1996; 42 (Suppl.):
S83–S84
72.		 Cornélissen G., Siegelova J., Fiser B., Dusek J., Halberg F. Current limitations and promise of ambulatory
blood pressure monitoring. In: Proceedings, Cardiovascular Coordination in Health and Blood Pressure Disorders,
Medical Faculty, Masaryk University, Brno, Czech Republic, May 24, 1996, Halberg F., Kenner T., Fiser
B., Siegelova J. eds., 1996, pp. 11–13
73.	 	 Dusek J., Siegelova J., Al-Kubati M., Fiser B., Cornélissen G., Halberg F. Blood pressure variability during 24 h
in patients with essential hypertension. Abstract, Aerosols in Diagnosis, Therapy, and Prophylaxis & CardioRespiratory
Relations, International Symposium, High Tatras, Sanatorium Helios, Slovakia, May 14–17, 1996,
p. 19
74.		 Fiser B., Siegelova J., Turti T., Syutkina E.V., Cornélissen G., Grigoriev A.E., Mitish M.D., Abramian A.S.,
Dusek J., Nekvasil R., Al-Kubati M., Muchova L., Halberg F. Neonatal blood pressure and heart rate rhythm:
multiseptan over circadian prominence. Abstract, International Workshop and Teaching Course: Spontaneous
Motor Activity as a Diagnostic Tool, Karl-Franzens-Univ., Graz, Austria, September 11–18, 1996, p. 64
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75.	 	 FiserB,SiegelovaJ,CornélissenG,DusekJ,Al-KubatiM,WatanabeY,HalbergF.Chronometaanalysisofblood
pressure data from drug tests. Abstract, 2nd
Int. Symp. of Chronobiology and Chronomedicine, Shenyang,
China, Sept. 28–Oct. 2, 1996. p. 53–54
76.		 Halberg F, Cornélissen G, Gubin D, Gubin G, Fiser B, Dusek J, Al-Kubati M, Siegelova J. Circadiani, circaseptani,
circasemiseptanique in chronomis seclusorum, præmaturorum, seniumque: in honorem Johannis Penazensis
modo Mendeliano, Goedeliano, Keplerianoque. In: Halberg F, Kenner T, Fiser B, Siegelova J, editors.
Proceedings, Cardiovascular Coordination in Health and Blood Pressure Disorders, Brno, Czech Republic:
Medical Faculty, Masaryk University; May 24, 1996. p. 8–10
77.		 Siegelova J, Dusek J, Fiser B, Nekvasil R, Muchova M, Cornélissen G, Halberg F. Circaseptan rhythm in blood
pressure and heart rate in newborns. Scripta medica (Brno) 1996; 67 (Suppl. 2): 63–70
78.		 Siegelova J., Fiser B., Dusek J., Al-Kubati M., Nekvasil R., Cornélissen G., Halberg F. Blood pressure and
heart rate coordination in newborn: circadian and circaseptan rhythms. Abstract, International Workshop
and Teaching Course: Spontaneous Motor Activity as a Diagnostic Tool, Karl-Franzens-Univ., Graz, Austria,
September 11–18, 1996, p. 63
79.	 	 Siegelova J., Fiser B., Dusek J., Cornélissen G., Halberg F. Limitace ambulantniho monitorovani krevniho
tlaku. In: XII. Pracovni Konference Arterialni Hypertenze a Prevence Kardiovaskularnich Chorob, Abstrakta,
Dum techniky Brno, 1996, p. 10
80.		 Siegelova J., Fiser B., Kadanka Z., Moran M., Dusek J., Al-Kubati M., Cornélissen G., Halberg F. Sleep apnea
syndrome and 24-h blood pressure. Electroenceph. Clin. Neurophysiol. 99: 393, 1996
81.	 	 Siegelova J, Moran M, Fiser B, Kadanka Z, Dusek J, Al-Kubati M, Cornélissen G, Halberg F. Blood pressure
monitoring in healthy subjects, in patients with sleep apnea syndrom[e] and in patients with essential hypertension.
Scripta medica (Brno) 1996; 67 (Suppl 2): 59–62. [In Czech.]
82.		 Siegelova J, Cornélissen G, Halberg F, Fiser B, Dusek J, Al-Kubati M, Machat R, Kumagai Y, Watanabe Y,
Otsuka K. Self-starting cumulative sums for the individualized assessment of antihypertensive response and
optimization by timing. Keynote, 2nd
Int. Symp. of Chronobiology and Chronomedicine, Shenyang, China,
Sept. 28–Oct. 2, 1996. p. 48
83.	 	 Siegelova J., Fiser B., Al-Kubati M., Dusek J., Cornélissen G., Halberg F. Baroreflex heart rate sensitivity in
hypertensives: the role of antihypertensive therapy. In: Proceedings, Cardiovascular Coordination in Health
and Blood Pressure Disorders, Medical Faculty, Masaryk University, Brno, Czech Republic, May 24, 1996,
Halberg F., Kenner T., Fiser B., Siegelova J. eds., 1996, pp. 18–34. [2221]
84.		 Siegelova J., Morán M., Fiser B., Kadanka Z., Dusek J., Al-Kubati M., Halberg F., Cornélissen G. Circadian
variations in blood pressure in patients with sleep apnea and essential hypertension. Abstract PS 103, 23rd
Congress, International Society of Internal Medicine, Manila, Philippines, February 1–6, 1996, p. 159. [2218]
85.	 	 Siegelova J., Morán M., Fiser B., Kadanka Z., Dusek J., Al-Kubati M., Halberg F., Cornélissen G. Circadian
variations in blood pressure in patients with sleep apnea and essential hypertension. Proceedings, 23rd
Congress,
International Society of Internal Medicine, Manila, Philippines, February 1-6, 1996, Aquino A.V., Piedad
F.F., Sulit Y.Q.M. (eds.), Monduzzi Editore, Bologna, 1996, pp. 273–276
86.		 Turti T, Syutkina EV, Cornélissen G, Grigoriev AE, Mitish MD, Abramian AS, Siegelova J, Fiser B, Dusek J,
­Al-Kubati M, Muchova L, Uhlir M, Halberg F. Multiseptan-over-circadian prominence of neonatal blood pressure
and heart rate in Moscow, Russia. Scripta medica (Brno) 1996; 67 (Suppl. 2): 85–92
87.	 	 Baevsky RM, Petrov VM, Cornélissen G, Halberg F, Orth-Gomér K, Åkerstedt T, Otsuka K, Breus T, Siegelova
J, Dusek J, Fiser B. Meta-analyzed heart rate variability, exposure to geomagnetic storms, and the risk of ischemic
heart disease. Scripta medica (Brno) 1997; 70: 199–204
88.		 Gubin D., Cornélissen G., Halberg F., Fiser B., Dusek J., Al-Kubati M., Siegelova J., Gubin G. Aging is accompanied
by increased variability and acircadian dessimination of blood pressure (BP) biorhythms. Proc.
XXXIII Int. Cong. International Union of Physiological Sciences, St. Petersburg, Russia, June 30–July 5, 1997,
­abstract P041.42
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89.	 	 Gubin D, Cornélissen G, Halberg F, Gubin GD, Turti T, Syutkina EV, Grigoriev AE, Mitish MD, Yatsyk GV,
Ikonomov O, Stoynev A, Madjirova N, Siegelova J, Fiser B, Dusek J. Half-weekly and weekly blood pressure
patterns in late human ontogeny. Scripta medica (Brno) 1997; 70: 207–216
90.		Halberg F., Cornélissen G., Watanabe Y., Siegelova J., Fiser B., Dusek J., Al-Kubati M. Chronobiologic
concepts: tempora mutantur et nos mutamur in illis. Scripta medica (Brno) 70: 231–237, 1997
91.	 	 Halberg F., Cornélissen G., Wendt H., Siegelova J., Dusek J., Fiser B. New trends in cosmobiophysics and the
need for a space weather report. Folia Mendeliana 31–32, Supplementum ad Acta Musei Moraviae, Scientiae
naturales LXXXI–II: 13–15,1996/1997 (© 1997)
92.		 Siegelova J., Cornélissen G., Dusek J., Fiser B., Watanabe Y., Otsuka K., Halberg F. Diagnosis and assessment
of treatment effects: a single 24-hour blood pressure (BP) monitoring (ABPM) profile. 5th
International Fair of
Medical Technology and Pharmacy, MEFA Congress, Brno, Czech Republic, November 5–8, 1997, section 6
(Neinvazivni vysetrovaci metody v kardiologii), abstract 8
93.		 Siegelova J., Fiser B., Dusek J., Cornélissen G., Halberg F. Circaseptan variability in blood pressure in newborn.
Abstract #314, International Congress on Chronobiology. Chronobiology int. 14 (Suppl. 1): 158, 1997
94.		 Siegelova J, Fiser B, Dusek J, Halberg F, Cornélissen G. 24-h blood pressure profile in essential hypertension
after verapamil, nitrendipine and enalapril treatment. Scripta medica (Brno) 1997; 70: 373–374
95.	 	 Siegelova J., Fiser J., Kadanka Z., Moran M., Dusek J., Cornélissen G., Halberg F. Syndrom spankove apnoe
a 24-hodinove monitorovani krevniho tlaku. Abstract, XIV konference o arterialni hypertenzi & VI konference
preventivni kardiologie, Plzen, 15.-17. rijna 1997, p. 43
96.		 Siegelova J., Kadanka Z., Moran M., Fiser B., Homolka P., Dobsak P., Dusek J., Cornélissen G., Halberg F.
­24-hour blood pressure profile in patients with sleep apnea syndrome: the effect of therapy. 5th
International
Fair of Medical Technology and Pharmacy, MEFA Congress, Brno, Czech Republic, November 5–8, 1997, sec-
tion 6 (Neinvazivni vysetrovaci metody v kardiologii), abstract 12
97.		 Syutkina EV, Cornélissen G, Grigoriev AE, Mitish MD, Turti T, Yatsyk GV, Pimenov K, Breus TK, Studenikin
MY, Siegelova J, Fiser B, Dusek J, Johnson D, Halberg F. Neonatal intensive care may consider associations of
cardiovascular rhythms with local magnetic disturbance. Scripta medica (Brno) 1997; 70: 217–226
98.		 Siegelova J, Cornélissen G, Dusek J, Fiser B, Watanabe Y, Otsuka K, Halberg F. Diagnosis and assessment
of treatment effects: a single 24-hour blood pressure monitoring profile. Scripta medica (Brno) 1998; 71:
­209–214
99.		 Siegelova J., Fiser B., Dusek J., Cornélissen G., Halberg F. Circadian variability of rate pressure product in
hypertension with enalapril therapy. Abstract, Investigator-Initiated Satellite Symposium to 17th
Scientific
Meeting, International Society of Hypertension: Renin-angiotensin-aldosterone system: Where to block it?,
Prague, Czech Republic, June 4, 1998, p. 6
100.	 Siegelova J., Fiser B., Dusek J., Dobsak P., Cornélissen G., Halberg F. Cirkadianni kolisani kardiovaskularnich
velicin. Abstract, Nove Trendy ve Funkcni Diagnostice a Rehabilitaci, Slavnosti Pracovni Schuze, 75 Let, Brno
27. unora 1998, p. 12
101.	 Siegelova J., Fiser B., Dusek J., Placheta Z., Cornélissen G., Halberg F. Circadian variability of rate pressure
product in essential hypertension with enalapril therapy. Abstract 3, Neinvazivni metody v kardiovaskularnim
vyzkumu, 6th
International Fair of Medical Technology and Pharmacy, MEFA Congress, Brno, Czech Republic,
November 3–4, 1998
102.	 Siegelova J., Kadanka Z., Moran M., Fiser B., Homolka P., Dobsak P., Dusek J., Cornélissen G., Halberg F. 24-h
blood pressure profile in patients with sleep apnea syndrom: the effect of therapy. Scripta medica (Brno) 71:
239–244, 1998
103.	 Siegelova J., Fiser B., Dusek J., Kadanka Z., Moran M., Cornélissen G., Halberg F. Sleep apnea syndrom[e]
and circadian blood pressure variability: the effect of CPAP therapy. Abstract, XVI Martin Days of Respiration
with international participation, Martin, Czech Republic, September 16–17, 1998, p. 26
104.	 Halberg F, Cornélissen G, Schwartzkopff O, Syutkina EV, Grigoriev AE, Mitish MD, Yatsyk GV, Studenikin
MY, Gubin D, Gubin G, Siegelova J, Fiser B, Dusek J, Homolka P, Watanabe Y, Otsuka K, Perfetto F, Tarquini
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R, Delmore P. Spin-offs from blood pressure and heart rate studies for health care and space research (review).
in vivo 1999; 13: 67–76
105.	 Ulmer W., Cornélissen G., Revilla M., Siegelova J., Dusek J., Halberg F. Circadian and circaseptan dependence
of the beta-ATP peak of four different cancer cell cultures: implications for chronoradiotherapy. Abstract 13,
MEFA, Brno, Czech Rep., Nov. 3–6, 1999
106.	 Amiranashvili AG, Cornélissen G, Amiranashvili V, Gheonjian L, Chikhladze VA, Gogua RA, Matiashvili TG,
Paatashvili T, Kopytenko YuA, Siegelova J, Dusek J, Halberg F. Circannual and circadecennian changes in
mortality from cardiovascular causes in Tbilisi, Republic of Georgia (1980–1992). MEFA 8th
International Fair
of Medical Technology and Pharmacy, Brno, Czech Republic, 7–10 Nov 2000, abstract 16
107.	 Cornélissen G, Otsuka K, Chen C-H, Kumagai Y, Watanabe Y, Halberg F, Siegelova J, Dusek J. Nonlinear relation
of the circadian blood pressure amplitude to cardiovascular disease risk. Scripta medica (Brno) 2000; 73:
85–94
108.	 Fiser B, Cornélissen G, Siegelova J, Dusek J, Homolka P, Mazankova V, Halberg F. Increase in stroke deaths
after 1997 in the Czech Republic. MEFA 8th
International Fair of Medical Technology and Pharmacy, Brno,
Czech Republic, 7–10 Nov 2000, abstract 4
109.	 Halberg F, Cornélissen G, Otsuka K, Watanabe Y, Katinas GS, Burioka N, Delyukov A, Gorgo Y, Zhao ZY,
Weydahl A, Sothern RB, Siegelova J, Fiser B, Dusek J, Syutkina EV, Perfetto F, Tarquini R, Singh RB, Rhees
B, Lofstrom D, Lofstrom P, Johnson PWC, Schwartzkopff O, International BIOCOS Study Group. Cross-spectrally
coherent ~10.5- and 21-year biological and physical cycles, magnetic storms and myocardial infarctions.
Neuroendocrinol Lett 2000; 21: 233–258. [Invited presentation, NATO Advanced Study Institute on Space
Storms and Space Weather Hazards, Crete, Greece, June 19–29, 2000.]
110.	 Halberg F, Cornélissen G, Sanchez de la Peña S, Schwartzkopff O, Wall DG, Kysylyczyn J, Sarkozy S, Delmore
P, Borer K, Otsuka K, Siegelova J, Homolka P, Dusek J, Fiser B. [Why and how to implement 7-day/24-hour
blood pressure monitoring.] Addendum 1, Proceedings, 4th
International Symposium of Chronobiology and
Chronomedicine, Yantai, China, Oct. 7–14, 2000, 37 pp. [Translated into Chinese.]
111.	 Halberg F, Cornélissen G, Siegelova J, Fiser B, Dusek J, Otsuka K, Delyukov AA, Gorgo Y, Gubin DG, Gubin
GD, Schwartzkopff O. The Cosmos and CHAT, prompting blood pressure and heart rate monitoring for
Dérer’s week. Bratislavske lekarske listy 2000; 101: 260–271
112.	 Halhuber MJ, Cornélissen G, Müller-Bohn T, Bartter FC, Delea CS, Siegelova J, Dusek J, Schwartzkopff O,
Halberg F. Circadian urinary glucocorticoid and other variation and rhythmic blood pressure coordination.
MEFA 8th
International Fair of Medical Technology and Pharmacy, Brno, Czech Republic, 7–10 Nov 2000,
abstract 27
113.	 Hillman D, Katinas G, Cornélissen G, Siegelova J, Dusek J, Halberg F. About 10-yearly (circadecennnian)
­cosmo-helio-geomagnetic signatures in Acetabularia. MEFA 8th
International Fair of Medical Technology and
Pharmacy, Brno, Czech Republic, 7–10 Nov 2000, abstract 19
114.	 Ikonomov OC, Stoynev AG, Penev PD, Peneva AV, Cornélissen G, Samayoa W, Siegelova J, Dusek J, Halberg F.
Circadian rhythm of blood pressure and heart rate in uncomplicated human pregnancy. Scripta medica (Brno)
2000; 73 (1): 44–55
115.	 Katinas G, Hillman D, Siegelova J, Dusek J, Cornélissen G, Halberg F. About-weekly electrical potential, chloroplast
migration and oxygen production changes of Acetabularia in continuous light. MEFA 8th
International
Fair of Medical Technology and Pharmacy, Brno, Czech Republic, 7–10 Nov 2000, abstract 20
116.	 Siegelova J, Dusek J, Fiser B, Halberg F, Cornélissen G. Biological rhythms in medicine. J Oncol Pharm Practice
2000; 6: 15–16 (www.nature.com/jopp)
117.	Siegelova J, Fiser B, Dusek J, Halberg F, Cornélissen G. Circadian variability of blood pressure. Abstract, Stabilität
und Oszillationen, 8. AKP-Tagung in Weiz bei Graz, 30. 9. 2000 – 3. 10. 2000, Tagung der Gruppe der
Angewandten, Klinischen und Pathologischen Physiologen der Deutschen Physiologischen Gesellschaft gemeinsam
mit der Österreichischen Physiologen Gesellschaft, 2000, p. 16
118.	 Siegelova J, Fiser B, Dusek J, Placheta Z, Cornélissen G, Halberg F. Circadian variability of rate-pressure product
in essential hypertension with enalapril therapy. Scripta medica (Brno) 2000; 73: 69–75
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119.	 Siegelova J, Fiser B, Dusek J, Placheta J, Dobsak P, Svacinova H, Jancik J, Cornélissen G, Halberg F. Baroreflex
sensitivity in “essential hypertension” treated with trandolapril and diltiazem in combination. Abstract 22.11,
APS Conference, Baroreceptor and Cardiopulmonary Receptor Reflexes, Iowa City, IA, August 23–27, 2000.
The Physiologist 2000; 43: 283
120.	 Siegelova J, Homolka P, Dusek J, Fiser B, Cornélissen G, Halberg F. Extracircadian-to-circadian variance
transpositions early and vice versa late in life in the human circulation. Proceedings, 1st
International Symposium,
Workshop on Chronoastrobiology & Chronotherapy (Satellite Symposium, 7th
Annual Meeting, Japanese
Society for Chronobiology), Kudan, Chiyodaku, Tokyo, 11 Nov 2000, pp. 58–60
121.	 Starbuck S, Cornélissen G, Siegelova J, Dusek J, Halberg F. Does religious motivation follow a circadecennian
(about 10.5-year) cycle? MEFA 8th
International Fair of Medical Technology and Pharmacy, Brno, Czech
­Republic, 7–10 Nov 2000, abstract 25
122.	 Nintcheu-Fata S, Cornélissen G, Katinas G, Halberg F, Fiser B, Siegelova J, Masek M, Dusek J. Software for
contour maps of moving least squares spectra. Abstract 15, MEFA 9th
International Fair of Medical Technology
and Pharmacy, Brno, November 6–11, 2001
123.	 Ulmer W, Cornélissen G, Revilla M, Siegelova J, Dusek J, Halberg F. Circadian and circaseptan dependence of
the beta-ATP peak of four different cancer cell cultures: implications for chronoradiotherapy. Scripta medica
(Brno) 2001; 74: 87–92
124.	 Amiranashvili AG, Cornélissen G, Amiranashvili V, Gheonjian L, Chikhladze VA, Gogua RA, Matiashvili TG,
Paatashvili T, Kopytenko YuA, Siegelova J, Dusek J, Halberg F. Circannual and circadecennian stages in mortality
from cardiovascular causes in Tbilisi, Republic of Georgia (1980–1992). Scripta medica (Brno) 2002;
75: 255–260
125.	 Dusek J, Fiser B, Siegelova J, Cornélissen G, Svoboda L, Homolka P, Jancik J, Svacinova H, Mazankova V,
Schwartzkopff O, Halberg F. Vzestup incidence cevni mozkove prihody po r. 1997 v Ceske Republice. Cor et
Vasa 2002; 44: 18
126.	 Fiser B, Cornélissen G, Siegelova J, Dusek J, Homolka P, Mazankova V, Halberg F. Increase in stroke deaths
after 1997 in the Czech Republic. Scripta medica (Brno) 2002; 75: 95–100
127.	 Halberg F, Cornélissen G, Engebretson M, Fiser B, Siegelova J, Dusek J, Katinas G, Schwartzkopff O. Dedicne
biosfericke analogie nesvetelnych solarnich nebo galaktickych cyklu. Abstract, Clovek ve svem pozemskem
a kosmickem prostredi, Upice, 21–23 May 2002, pp. 30–31
128.	 Halberg F, Cornélissen G, Otsuka K, Katinas GS, Schwartzkopff O, Halpin C, Mikulecky M, Revilla M, Siegelova
J, Homolka P, Dusek J, Fiser B, Singh RB. Chronomics* (*the study of time structures, chronomes)
detects altered vascular variabilities constituting risks greater than hypertension: with an illustrative case report.
In: Mitro P, Pella D, Rybar R, Valocik G, editors. Proceedings, 2nd
Congress on Cardiovascular Diseases,
Kosice, Slovakia, 25-27 April 2002. Bologna: Monduzzi Editore; 2002. p. 223–258
129.	 Halberg F, Cornélissen G, Prikryl P, Katinas G, Dusek J, Homolka P, Karpisek Z, Sonkowsky RP, Schwartzkopff
O, Fiser B, Siegelova J, International BIOCOS Project Team. Chronomics complement genomics in
Brno. What Johann Gregor Mendel wished, Jarmilka Siegelova accomplished: Broadening system times and
transdisciplinary time horizons. In: Halberg F, Kenner T, Fiser B, editors. Proceedings, Symposium: The Importance
of Chronobiology in Diagnosing and Therapy of Internal Diseases. Faculty of Medicine, Masaryk
University, Brno, Czech Republic, January 10-13, 2002. Brno: Masaryk University; 2002. p. 7–56
130.	 Halberg F, Cornélissen G, Wall D, Otsuka K, Halberg J, Katinas G, Watanabe Y, Halhuber M, Müller-Bohn T,
Delmore P, Siegelova J, Homolka P, Fiser B, Dusek J, Sanchez de la Peña S, Maggioni C, Delyukov A, Gorgo
Y, Gubin D, Carandente F, Schaffer E, Rhodus N, Borer K, Sonkowsky RP, Schwartzkopff O. Engineering
and governmental challenge: 7-day/24-hour chronobiologic blood pressure and heart rate screening: Part I.
Biomedical Instrumentation & Technology 2002; 36: 89–122
131.	 Halberg F, Cornélissen G, Wall D, Otsuka K, Halberg J, Katinas G, Watanabe Y, Halhuber M, Müller-Bohn T,
Delmore P, Siegelova J, Homolka P, Fiser B, Dusek J, Sanchez de la Peña S, Maggioni C, Delyukov A, Gorgo
Y, Gubin D, Carandente F, Schaffer E, Rhodus N, Borer K, Sonkowsky RP, Schwartzkopff O. Engineering
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and governmental challenge: 7-day/24-hour chronobiologic blood pressure and heart rate screening: Part II.
Biomedical Instrumentation & Technology 2002; 36: 183–197
132.	 Halhuber MJ, Cornélissen G, Bartter FC, Delea CS, Kreze A, Mikulecky M, Müller-Bohn T, Siegelova J, Dusek
J, Schwartzkopff O, Halberg F. Circadian urinary glucocorticoid and rhythmic blood pressure coordination.
Scripta medica (Brno) 2002; 75: 139–144
133.	 Hillman D, Katinas G, Cornélissen G, Siegelova J, Dusek J, Jancik J, Masek M, Halberg F. About-10-yearly (circadecennian)
cosmo-helio-geomagnetic signatures in Acetabularia.Scripta medica (Brno) 2002; 75: 303–308.
134.	 Katinas G, Hillman D, Siegelova J, Dusek J, Svacinova H, Cornélissen G, Halberg F. About-weekly changes
in electrical potential, chloroplast migration and oxygen production in Acetabularia grown under continuous
exposure to light. Scripta medica (Brno) 2002; 75: 309–314
135.	 Katinas G, Nintcheu-Fata S, Cornélissen G, Siegelova J, Masek M, Dusek J, Vlcek J, Halberg F. Moving least
squares spectra scrutinize chronomics in and around us. Abstract 14, Kongres MEFA, Brno, Czech Rep.,
5–8 Nov. 2002
136.	 Yamanaka T, Cornélissen G, Kazuma M, Kazuma N, Murakami S, Otsuka K, Siegelova J, Dusek J, Halberg
F. Further mapping of the natality chronome in Toda City (Japan) Maternity Hospital. Abstract 16, Kongres
MEFA, Brno, Czech Rep., 5–8 Nov. 2002
137.	 Cornélissen G, Halberg F, Bakken EE, Wang ZR, Tarquini R, Perfetto F, Laffi G, Maggioni C, Kumagai Y, Prikryl
P, Homolka P, Dusek J, Siegelova J, Fiser B. Can society afford not to follow a chronobiological approach
to blood pressure screening, diagnosis and treatment? In: Halberg F, Kenner T, Siegelova J, editors. Proceedings,
Symposium, Chronobiological Analysis in Pathophysiology of Cardiovascular System. Brno: Masaryk
University; 2003. p. 75–90. [Dedicated to the 60th
Anniversary of Prof. Bohumil Fiser.]
138.	 Cornélissen G, Halberg F, Otsuka K, Shinagawa M, Kubo Y, Ohkawa S, Fiser B, Siegelova J, Dusek J. Iatrogenic
excessive blood pressure variability (CHAT): implications for chronotherapy. Scripta medica (Brno)
2003; 76: 275–278
139.	 Fiser B, Cornélissen G, Siegelova J, Dusek J, Mazankova V, Halberg F. Spektralni analyza padesatileteno zazmamu
mortality pro cevni Mozkovou prihodu v Ceske Republice. Abstract, XI. vyrocniho sjezdu Ceske kardiologicke
spolecnosti, 11–14 kvetna 2003, Brno. Cor et Vasa 2003; 4 (Suppl): 21
140.	 Halberg F, Cornélissen G, Otsuka K, Maggioni C, Schwartzkopff G, Fiser B, Dusek J, Siegelova J. Chronomics:
the broad scope of monitoring chronomes. A review. Scripta medica (Brno) 2003; 76: 269–273
141.	 Halberg F, Cornélissen G, Stoynev A, Ikonomov O, Katinas G, Sampson M, Wang ZR, Wan CM, Singh RB,
Otsuka K, Sothern RB, Sothern SB, Sothern MI, Syutkina EV, Masalov A, Perfetto F, Tarquini R, Maggioni
C, Kumagai Y, Siegelova J, Fiser B, Homolka P, Dusek J, Uezono K, Watanabe Y, Wu JY, Sonkowsky R,
Schwartzkopff O, Hellbrügge T, Spector NH, Baciu I, Hriscu M, Bakken E. Season’s Appreciations 2002 and
2003. Imaging in time: The transyear (longer-than-the-calendar year) and the half-year. Neuroendocrinol Lett
2003; 24: 421–440
142.	 Katinas GS, Dusek J, Siegelova J, Cornélissen G, Halberg F. Intra-individual variability of the circadian blood
pressure waveform in intermittent treated MESOR-hypertensive CHAT. Abstract #12, MEFA, Brno, Czech
Republic, 04-07 Nov 2003. p. 17
143.	 Kelsey R, Cornélissen G, Kapfer D, Siegelova J, Masek M, Dusek J, Fiser B, Halberg F. Research in practice:
inferential statistical procedures applicable to the individual patient’s response to benetensive treatment. Abstract
#15, MEFA, Brno, Czech Republic, 04–07 Nov 2003. p. 20
144.	 Nintcheu-Fata S, Cornélissen G, Katinas G, Halberg F, Fiser B, Siegelova J, Masek M, Dusek J. Software for
contour maps of moving least-squares spectra. Scripta medica (Brno) 2003; 76: 279–283
145.	 Otsuka K, Cornélissen G, Halberg F, Fiser B, Siegelova J, Sosikova M, Dusek J, Jancik J. Assessment of different
administration schedules of sotalol by electrocardiography. Scripta medica (Brno) 2003; 76: 297–300
146.	 Schwartzkopff O, Halberg F, Cornélissen G, Katinas G, Wang ZR, Kröz M, Hecht K, Tarquini R, Perfetto F,
Maggioni C, Siegelova J, Dusek J, Fiser B, Singh RB, Bakken E. Self-experimentation: dangerous when first
done by a few, now safe for everybody’s health? In: Halberg F, Kenner T, Siegelova J, editors. Proceedings,
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Symposium, Chronobiological Analysis in Pathophysiology of Cardiovascular System. Brno: Masaryk University;
2003. p. 91–104. [Dedicated to the 60th
Anniversary of Prof. Bohumil Fiser.]
147.	Schwartzkopff O, Katinas G, Singh RB, Sanchez de la Pena S, Zhao ZY, Uezono K, Prikryl P, Siegelova J,
Fiser B, Dusek J, Otsuka K, Cornélissen G, Halberg F. Self-surveillance and self-experimentation (SSSE) for
preventing vascular diseases needed to follow established successes of anesthesia and vaccine development.
Abstract #13, MEFA, Brno, Czech Republic, 04–07 Nov 2003. p. 18
148.	 Siegelova J, Cornélissen G, Fiser B, Dusek J, Homolka P, Masek M, Jancik J, Svacinova H, Halberg F. Blood
pressure and heart rate monitoring in humans: the circaseptan and circadian rhythms. Abstract, 3rd
International
Workshop on The Human Circulation: Noninvasive Haemodynamic, Autonomic and Vascular Monitoring,
Graz, Austria, 9–11 May 2003. Clinical Autonomic Research 2003; 13: 60–61
149.	 Siegelova J, Fiser B, Dusek J, Placheta Z, Vlcek J, Svoboda L, Pazdirek J, Cornélissen G, Halberg F. Chronotherapy:
rate-pressure produce in essential hypertension. In: Halberg F, Kenner T, Siegelova J, editors. Proceedings,
Symposium, Chronobiological Analysis in Pathophysiology of Cardiovascular System. Brno: Masaryk
University; 2003. p. 118–121. [Dedicated to the 60th
Anniversary of Prof. Bohumil Fiser.]
150.	 Sothern RB, Cornélissen G, Engel P, Fiser B, Siegelova J, Vlcek J, Dusek J, Halberg F. Chronomics: instrumentation
for monitoring of peak expiratory flow. Scripta medica (Brno) 2003; 76: 313–315
151.	 Watanabe Y, Cornélissen G, Watanabe F, Siegelova J, Dusek J, Halberg F. The trans- (~1.3) year in the blood
pressure of a 10-year-old boy. Abstract 17, MEFA, Brno, Czech Republic, 04–07 Nov 2003. p. 22
152.	 Cornélissen G, Palermo J, Carandente F, Siegelova J, Fiser B, Dusek J, Halberg F. Chronomics: chronome
of suicides in Minnesota (1968–2002). Abstract, Noninvasive methods in cardiology, 2.11.2004, Congress
MEFA, Brno, Czech Republic, 2.–4. 11. 2004, p. 8
153.	 Crawford VLS, Cornélissen G, Fiser B, Dusek J, Siegelova J, Halberg F. Infrannual changes in the incidence
of myocardial infarctions and strokes in Northern Ireland. Abstract, Noninvasive methods in cardiology,
2.11.2004, Congress MEFA, Brno, Czech Republic, 2.–4. 11. 2004, p. 9
154.	 Dusek J, Siegelova J, Fiser B, Brazdova Z, Homolka P, Vank P, Forejt M, Hollan J, Cornélissen G, Halberg
F. Alterations of circadian rhythm in blood pressure by lack of dark: 24-h ambulatory blood-pressure monitoring.
Abstract, Noninvasive methods in cardiology, 2. 11. 2004, Congress MEFA, Brno, Czech Republic,
­2.–4. 11. 2004, p. 16
155.	 Fiser B, Cornélissen G, Otsuka K, Chibisov S, Dusek J, Siegelova J, Halberg F. Blood pressure and heart rate
readings for solar science and health care. Abstract, 2nd
International Conference, Pathophysiology and Contemporary
Medicine, Moscow, Russia, 22–24 April 2004. p. 472–473; and Science without Borders, Transactions
of the International Academy of Science H&E, 2003/2004; 1: 420–421
156.	 Fiser B, Siegelova J, Dusek J, Moudr J, Cornélissen G, Halberg F. Assessment of high blood pressure risk
for stroke chronobiological approach. Abstract, Noninvasive methods in cardiology, 2. 11. 2004, Congress
MEFA, Brno, Czech Republic, 2.–4. 11. 2004, p. 11
157.	 Halberg F, Cornélissen G, Otsuka K, Siegelova J, Homolka P, Fiser B, Dusek J, Sanchez de la Pena S, Schwartzkopff
O, Singh RB. Home ambulatory blood pressure and heart rate monitoring in practice and for science:
transyears and magnetoperiodism vs. photoperiodism. Abstract S8-02, 3rd
Int Congress on Cardiovascular
Disease, Taipei, Taiwan, 26–28 Nov 2004. Int J Cardiol 2004; 97 (Suppl 2): S12
158.	 Halberg F, Cornélissen G, Panksepp J, Schwartzkopff O, Siegelova J, Fiser B, Dusek J. Near-transyears in geophysics
and autism. Abstract, Noninvasive methods in cardiology, 2.11.2004, Congress MEFA, Brno, Czech
Republic, 2.–4. 11. 2004, p. 7
159.	 Katinas GS, Chopra RK, Singh RB, Siegelova J, Fiser B, Dusek J, Cornélissen G, Halberg F. Design for timing
nutriceuticals. Abstract, Noninvasive methods in cardiology, 2. 11. 2004, Congress MEFA, Brno, Czech
Republic, 2.–4. 11. 2004, p. 19
160.	 Siegelova J, Dusek J, Fiser B, Homolka P, Vank P, Cornelissen G, Halberg F. Vztah mezi vekem a cirkadianni
variabilitou krevniho tlaku. Cor Vasa 2004; 46 (4) (Suppl): 81
161.	 Siegelova J, Dusek J, Fiser B, Homolka P, Vank P, Cornélissen G, Halberg F. Rozdily v krevnim tlaku mezi
dnem a noci a vik. Congress of Atherosclerosis, TIGIS, Prague 2004. Abstract, DMEV 2004, Suppl 3, p. 38
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162.	 Siegelova J, Dusek J, Fiser B, Homolka P, Vank P, Cornélissen G, Halberg F. The relationship between age and
circadian blood pressure variation. J Hypertens 2004; 22 (Suppl 2): S210
163.	 Siegelova J, Dusek J, Fiser B, Homolka P, Vank P, Cornélissen G, Halberg F. Rozdily v krevnim tlaku mezi
dnem a noci a vek 26. Abstract, XXI. konference Ceske spolecnosti pro hypertenzi, XIII. konference pracovni
skupiny Preventivni kardiologie CKS, Konference pracovni skupiny Srdecni selhani CKS, Prague, 2004. p. 44
164.	 Siegelova J, Dusek J, Fiser B, Homolka P, Vank P, Cornélissen G, Halberg F. Circadian blood pressure variation
analyzed from 7-day monitoring. Abstract, Noninvasive methods in cardiology, 2.11.2004, Congress MEFA,
Brno, Czech Republic, 2.–4. 11. 2004, p. 12
165.	 Siegelova J, Dusek J, Homolka P, Vank P, Vlcek J, Cornélissen G, Halberg F. The relationship between age
and circadian blood pressure variation. In: Cornélissen G, Kenner R, Fiser B, Siegelova J, eds. Proceedings,
Symposium: Chronobiology in Medicine. Dedicated to the 85th
Anniversary of Professor Franz Halberg. Brno:
Masaryk University; 2004. p. 110–116
166.	 Siegelova J, Homolka P, Cornélissen G, Fiser B, Dusek J, Halberg F. Health watch in Brno, Czech Republic.
Abstract S8-13, 3rd
Int Congress on Cardiovascular Disease, Taipei, Taiwan, 26–28 Nov 2004. Int J Cardiol
2004; 97 (Suppl 2): S15–S16
167.	 Siegelova J, Homolka P, Cornélissen G, Fiser B, Dusek J, Vank P, Masek M, Halberg F. Ambulatory blood
pressure monitoring: Health Watch in Brno, Czech Republic. Abstract, Noninvasive methods in cardiology,
2.11.2004, Congress MEFA, Brno, Czech Republic, 2.–4. 11. 2004, p. 10
168.	 Bhatt MLB, Singh RK, Cornélissen G, Srivastava M, Rai G, Singh R, Halberg Francine, Siegelova J, Fiser B,
Dusek J, Halberg F. Chronoradiotherapy guided by circadian rhythm in tumor temperature. Abstract, Noninvasive
Methods in Cardiology, Brno, Czech Republic, September 14, 2005, p. 19
169.	 Cornélissen G, Delcourt A, Toussaint G, Otsuka K, Watanabe Y, Siegelova J, Fiser B, Dusek J, Homolka P,
Singh RB, Kumar A, Singh RK, Sanchez S, Gonzalez C, Holley D, Sundaram B, Zhao Z, Tomlinson B, Fok B,
Zeman M, Dulkova K, Halberg F. Opportunity of detecting pre-hypertension: worldwide data on blood pressure
overswinging. Biomedicine & Pharmacotherapy 2005; 59 (Suppl 1): S152–S157
170.	 Cornélissen G, Halberg F, Schwartzkopff O, Gvozdjakova A, Siegelova J, Fiser B, Dusek J, Mifkova L, Chopra
RK, Singh RB. Coenzyme-Q10 effect on blood pressure variability assessed with a chronobiological study
design. Abstract, Noninvasive Methods in Cardiology, Brno, Czech Republic, September 14, 2005, p. 10
171.	 Cornélissen G, Schwartzkopff O, Katinas G, Halberg F, Bakken EE, Holley D, Sundaram S, Sanchez S, Gonzalez
C, Delcourt A, Toussaint G, Siegelova J, Fiser B, Dusek J, Homolka P, Zeman M, Dulkova K, Otsuka K,
Watanabe Y, Tomlinson B, Fok B, Zhao ZY, Singh RB, Singh RK, Kumar A, Chibisov SM. Diagnosing blood
pressure overswinging chronomically worldwide. Abstract, III International Conference, Civilization diseases
in the spirit of V.I. Vernadsky, People’s Friendship University of Russia, Moscow, Oct. 10–12, 2005, p. 34–35
172.	 Cornélissen G, Watson D, Mitsutake G, Fiser B, Siegelova J, Dusek J, Vohlidalova L, Svacinova H, Halberg F.
Mapping of circaseptan and circadian changes in mood. Scripta medica 2005; 78: 89–98
173.	 Dusek J, Siegelova J, Homolka P, Fiser B, Masek M, Cornélissen G, Halberg F. Ambulatory blood pressure
monitoring lasting seven days. J Hypertens 2005; 34 (Suppl 2): S154
174.	 Fiser B, Siegelova J, Dusek J, Homolka P, Vank P, Cornélissen G, Halberg F. Seven-day blood pressure monitoring
and casual blood pressure measurement. Abstract, Noninvasive Methods in Cardiology, Brno, Czech
Republic, September 14, 2005, p. 11
175.	 Fiser B, Siegelova J, Dusek J, Moudr J, Cornélissen G, Halberg F. Assessment of high blood pressure risk for
stroke. J Hypertens 2005; 34 (Suppl 2): S151
176.	 Gvozdjakova A, Kucharska J, Cornélissen G, Singh RB, Mikulecky M, Siegelova J, Fiser B, Dusek J, Halberg F.
Coenzyme Q10 and the circadian system of cardiac oxidative phosphorylation in rats. Abstract, Noninvasive
Methods in Cardiology, Brno, Czech Republic, September 14, 2005, p. 24
177.	 Halberg F, Cornélissen G, Otsuka K, Fiser B, Mitsutake G, Wendt HW, Johnson P, Gigolashvili M, Breus T,
Sonkowsky R, Chibisov SM, Katinas G, Siegelova J, Dusek J, Singh RB, Berri BL, Schwartzkopff O. Incidence
of sudden cardiac death, myocardial infarction and far- and near-transyears. Biomedicine & Pharmacotherapy
2005; 59 (Suppl 1): S239–S261
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178.	 Halberg F, Katinas G, Cornélissen G, Schwartzkopff O, Fiser B, Siegelova J, Dusek J, Jancik J. Ambulatory
blood pressure monitoring: the need of 7-day record. Scripta medica 2005; 78: 83–88
179.	 Halberg F, Katinas G, Schwartzkopff O, Siegelova J. Fiser B, Dusek J, Cornélissen G. An about-2-year component
in 15-year, largely half-hourly human blood pressure but not heart rate records. Abstract, Noninvasive
Methods in Cardiology, Brno, Czech Republic, September 14, 2005, p. 7
180.	 Katinas G, Nintcheu-Fata S, Cornélissen G, Siegelova J, Dusek J, Vlcek J, Masek M, Halberg F. Moving leastsquares
spectra scrutinize chronomics in and around us. Scripta medica 2005; 78: 115–120
181.	 Regal P, Cornélissen G, Siegelova J, Fiser B, Dusek J, Halberg F. Chronomics, the site-specific magnetic environment
and an opportunity for the World Health Organization. Abstract, Noninvasive Methods in Cardiology,
Brno, Czech Republic, September 14, 2005, p. 9
182.	 Schwartzkopff O, Cornélissen G, Halpin C, Katinas G, Siegelova J, Fiser B, Dusek J, Halberg F. Untreated
transient longer than 7-day CHAT, circadian hyper-amplitude-tension, in a 7-year perspective. Scripta medica
2005; 78: 75–82
183.	 Schwartzkopff O, Schwartzkopff C, Katinas GS, Siegelova J, Fiser B, Dusek J, Cornélissen G, Halberg F. Chronomes,
not imaginary baselines, are needed as longitudinal reference values. Abstract, Noninvasive Methods
in Cardiology, Brno, Czech Republic, September 14, 2005, p. 8
184.	 Singh RB, Cornélissen G, Kumar A, Bathina S, Siegelova J, Fiser B, Dusek J, Vohlidalova I, Halberg F. Effect
of prayer on heart rate variability in Asian Indians. Abstract, Noninvasive Methods in Cardiology, Brno, Czech
Republic, September 14, 2005, p. 20
185.	 Sonkowsky RP, Cornélissen G, Siegelova J, Fiser B, Dusek J, Masek M, Halberg F. Myriadennian cyclicities
in the tradition of Archimedes and the International System of Units (SI): invitation for comment. Abstract,
Noninvasive Methods in Cardiology, Brno, Czech Republic, September 14, 2005, p. 21
186.	 Watanabe Y, Cornélissen G, Kodera I, Shimizu J, Ohmo G, Siegelova J, Fiser B, Dusek J, Vlcek J, Halberg F.
Chronomics of human blood pressure and heart rate in the Antarctic. Abstract, Noninvasive Methods in Cardiology,
Brno, Czech Republic, September 14, 2005, p. 22
187.	 Yamanaka T, Cornélissen G, Kazuma M, Kazuma N, Murakami S, Otsuka K, Siegelova J, Dusek J, Sosikova M,
Halberg F. Further mapping of the natality chronome, in Toda City (Japan) Maternity Hospital. Scripta medica
2005; 78: 99–106
188.	 Cornélissen G, Delcourt A, Toussaint G, Otsuka K, Watanabe Y, Siegelova J, Fiser B, Dusek J, Homolka P,
Singh RB, Kumar A, Singh RK, Sanchez S, Gonzalez C, Holley D, Sundaram B, Zhao Z, Tomlinson B, Fok B,
Zeman M, Dulkova K, Halberg F. Opportunity of detecting pre-hypertension: worldwide data on blood pressure
overswinging. (Reprint of Biomedicine & Pharmacotherapy 2005; 59 [Suppl 1]: S152–S157. Proceedings,
International Conference on the Frontiers of Biomedical Science: Chronobiology, Chengdu, China, Septem-
ber 24–26, 2006, p. 123–129
189.	 Cornélissen G, Halberg F, Katinas G, Schwartzkopff O, Holley D, Borer K, Homolka P, Siegelova J, Fiser B,
Dusek J, Otsuka K, Yano A, Delcourt A, Toussaint G, Sanchez de la Peña S, Gonzalez C, Zhao Z, Aslanian
N, Singh RB, Kumar A, Tarquini R, Perfetto F. Stroke and other vascular disease prevention by chronomics.
Scripta medica (Brno) 2006; 79 (3): 141–146
190.	 Cornélissen G, Halberg F, Katinas G, Watanabe Y, Sothern RB, Siegelova J, Fiser B, Dusek J, Homolka P, Prikryl
P, Singh RB, Otsuka K, Schwartzkopff O, Refinetti R. Chronotheranostics of MESOR-normotension vs.
circadian overswing, i.e., CHAT. In: Halberg F, Kenner T, Fiser B, Siegelova J, eds. Proceedings, Symposium,
Noninvasive Methods in Cardiology. Brno, Czech Republic: Department of Functional Diagnostics and Rehabilitation,
Faculty of Medicine, Masaryk University; 2006. p. 30–32
191.	 Dusek J, Fiser B, Siegelova J, Holub J, Mazankova V, Cornélissen G, Halberg F. Decrease of myocardial infarction
mortality and seasonal mortality in the Czech Republic in the period from 1994 to 2003. J Hypertension
2006; 24 (Suppl 4): 245
192.	 Dusek J, Siegelova J, Fiser B, Cornélissen G, Holub J, Mazankova V, Halberg F. Mortality data of stroke: ­50-year
record in the Czech Republic. Abstract 367, 10th
Annual Meeting, French Society of Pharmacology, 73rd
An-
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nual Meeting, Society of Physiology, 27th
pharmacovigilance meeting, 54th
APNET Seminar and 4th
CHU CIC
meeting (Corum Montpellier 10–12 April 2006). Fundamental and Clinical Pharmacology 2006; 201: 206
193.	 Dusek J, Siegelova J, Fiser B, Holub J, Mazankova V, Cornélissen G, Halberg F. Pokles celkove a sezonni umrtnosti
pro infarkt myokardu v Ceske Republice v letech 1994–2003. Supplementum Cor Vasa 2006; 48 (4): 21
194.	 Fiser B, Cornélissen G, Siegelova J, Pohanka M, Tarasova M, Barlova B, Nosavcova E, Dusek J, Homolka P,
Erajhi AA, Abais FH, Holub J, Mazankova V, Halberg F. Stroke in the Czech Republic. In: Halberg F, Kenner
T, Fiser B, Siegelova J, eds. Proceedings, Symposium, Noninvasive Methods in Cardiology. Brno, Czech Republic:
Department of Functional Diagnostics and Rehabilitation, Faculty of Medicine, Masaryk University;
2006. p. 55–61
195.	 Fiser B, Siegelova J, Dusek J, Holub J, Mazankova V, Cornélissen G, Halberg F. Spektralni analyza umrtnosti
na infarkt myokardu v Ceske Republice. Supplementum Cor Vasa 2006; 48 (4): 26
196.	 Fiser B, Siegelova J, Dusek J, Holub J, Mazankova V, Cornélissen G, Halberg F. Spectral analysis of the myocardial
infarction mortality data in the Czech Republic. J Hypertension 2006; 24 (Suppl 4): 246
197.	 Halberg F, Cornélissen G, Schwartzkopff O, Katinas G, Siegelova J, Fiser B, Dusek J, Homolka P, Vank P.
Seven day blood pressure measurement: contraversion in single 24-h profiles of blood pressure and heart rate.
In: Halberg F, Kenner T, Fiser B, Siegelova J, eds. Proceedings, Symposium, Noninvasive Methods in Cardiology.
Brno, Czech Republic: Department of Functional Diagnostics and Rehabilitation, Faculty of Medicine,
Masaryk University; 2006. p. 10–26
198.	 Halberg F, Katinas G, Cornélissen G, Otsuka K, Sothern RB, Singh RB, Schwartzkopff O, Siegelova J, Fiser B,
Dusek J, Homolka P, Prikryl P, Refinetti R. Lessons about “loads” learned while detecting and greatly reducing
residual MESOR-hypertension and CHAT. In: Halberg F, Kenner T, Fiser B, Siegelova J, eds. Proceedings,
Symposium, Noninvasive Methods in Cardiology. Brno, Czech Republic: Department of Functional Diagnostics
and Rehabilitation, Faculty of Medicine, Masaryk University; 2006. p. 27–29
199.	 Hillman D, Halberg F, Cornélissen G, Katinas G, Sothern RB, Otsuka K, Singh RB, Siegelova J, Fiser B, Dusek
J, Homolka P, Prikryl P, Schwatzkopff O. Need to standardize data collection and reference values. In: Halberg
F, Kenner T, Fiser B, Siegelova J, eds. Proceedings, Symposium, Noninvasive Methods in Cardiology. Brno,
Czech Republic: Department of Functional Diagnostics and Rehabilitation, Faculty of Medicine, Masaryk
University; 2006. p. 36–38
200.	Katinas G, Halberg F, Cornélissen G, Otsuka K, Singh RB, Siegelova J, Fiser B, Dusek J, Homolka P, Prikryl
P, Schwatzkopff O. Chronobiologic serial sections complement spectra to seek social vs. physical signatures
in human heart rate circaseptans. In: Halberg F, Kenner T, Fiser B, Siegelova J, eds. Proceedings, Symposium,
Noninvasive Methods in Cardiology. Brno, Czech Republic: Department of Functional Diagnostics and Rehabilitation,
Faculty of Medicine, Masaryk University; 2006. p. 39–41
201.	 Rostagno C, Cornélissen G, Halberg F, Tarquini R, Perfetto F, Jozsa R, Siegelova J, Fiser B, Dusek J, Homolka
P, Prikryl P, Bakken EE. Yet another cis-semiannual (cis-halfyear) spectral component in cardiac arrhythmia:
in Italy. Proceedings, International Conference on the Frontiers of Biomedical Science: Chronobiology,
Chengdu, China, September 24-26, 2006, p. 61–63
202.	Schwartzkopff O, Halberg F, Cornélissen G, Katinas G, Sothern RB, Siegelova J, Fiser B, Dusek J, Homolka P,
Prikryl P, Singh RB. Occasional transient CHAT occurs in the MESOR-normotensive individual. In: Halberg
F, Kenner T, Fiser B, Siegelova J, eds. Proceedings, Symposium, Noninvasive Methods in Cardiology. Brno,
Czech Republic: Department of Functional Diagnostics and Rehabilitation, Faculty of Medicine, Masaryk
University; 2006. p. 33–35
203.	 Siegelova J, Dusek J, Fiser B, Homolka P, Vank P, Cornélissen G, Halberg F. Blood pressure variation analyzed
from seven day monitoring. Abstract 366, 10th
Annual Meeting, French Society of Pharmacology, 73rd
Annual
Meeting, Society of Physiology, 27th
pharmacovigilance meeting, 54th
APNET Seminar and 4th
CHU CIC meeting
(Corum Montpellier 10–12 April 2006). Fundamental and Clinical Pharmacology 2006; 201: 205
204.	 Siegelova J, Dusek J, Fiser B, Homolka P, Vank P, Kohzuki M, Cornélissen G, Halberg F. Relationship between
circadian blood pressure variation and age analyzed from 7-day ambulatory monitoring. Abstract PM1-10-05,
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21st
Scientific Meeting, International Society of Hypertension, Fukuoka, Japan, October 15–19, 2006. J Hypertension
2006; 24 (Suppl 6): 122
205.	 Watanabe Y, Katinas G, Cornélissen G, Sothern RB, Siegelova J, Fiser B, Dusek J, Homolka P, Prikryl P, Singh
RB, Schwartzkopff O, Halberg F. Time course of blood pressures over 18 years analyzed separately by day and
by week. In: Halberg F, Kenner T, Fiser B, Siegelova J, eds. Proceedings, Symposium, Noninvasive Methods
in Cardiology. Brno, Czech Republic: Department of Functional Diagnostics and Rehabilitation, Faculty of
Medicine, Masaryk University; 2006. p. 42–46
206.	 Cornélissen G, Halberg F, Bakken EE, Wang Z, Tarquini R, Perfetto F, Laffi G, Maggioni C, Kumagai Y, Homolka
P, Havelkova A, Dusek J, Svacinova H, Siegelova J, Fiser B. Chronobiology of high blood pressure.
Scripta medica (Brno) 2007; 80 (4): 157–166
207.	 Dusek J, Siegelova J, Fiser B, Forejt M, Homolka P, Vank P, Hollan J, Cornélissen G, Halberg F. Blood pressure
and the illumination of bedroom at night. P1.31, 17th
European Meeting on Hypertension, Milan, June 15–19,
2007. J Hypertension 2007; 25 (Suppl 2): S33
208.	 Fiser B, Siegelova J, Dusek J, Pohanka M, Masek M, Barak J, Moudr J, Cornélissen G, Halberg F. Analysis
of baroreflex function by means of mathematical model. In: Halberg F, Kenner T, Fiser B, Siegelova J, eds.
Proceedings, Noninvasive Methods in Cardiology 2007, Brno, Czech Republic, November 11–14, 2007. Brno:
Department of Functional Diagnostics and Rehabilitation, Faculty of Medicine, Masaryk University (ISBN
978 80 7018 463 4); 2007. p. 90–93
209.	 Halberg F, Cornélissen G, Katinas G, Dusek J, Homolka P, Karpisek Z, Sonkowsky RP, Schwartzkopff O,
Fiser B, Siegelova J. Chronomics and genetics. Scripta medica (Brno) 2007; 80 (4): 133–150
210.	 Havelkova A, Siegelova J, Fiser B, Mifkova L, Chludilova V, Pochmonova J, Vank P, Pohanka M, Dusek J,
Cornélissen G, Halberg F. Physiotherapy and circadian blood pressure variability. In: Halberg F, Kenner T,
Fiser B, Siegelova J, eds. Proceedings, Noninvasive Methods in Cardiology 2007, Brno, Czech Republic, November
11-14, 2007. Brno: Department of Functional Diagnostics and Rehabilitation, Faculty of Medicine,
Masaryk University (ISBN 978 80 7018 463 4); 2007. p. 113–120
211.	 Havelkova A, Siegelova J, Fiser B, Mifkova L, Chludlikova V, Pochmonova J, Vank P, Pohanka M, Dusek J,
Cornélissen G, Halberg F. Circadian blood pressure variability and exercise therapy. Scripta medica (Brno)
2007; 80 (5): 191–196
212.	 Siegelova J, Dusek J, Fiser B, Homolka P, Vank P, Masek M, Havelkova A, Cornélissen G, Halberg F. Circadian
blood pressure variation analyzed from 7-day monitoring. In: Halberg F, Kenner T, Fiser B, Siegelova J, eds.
Proceedings, Noninvasive Methods in Cardiology 2007, Brno, Czech Republic, November 11–14, 2007. Brno:
Department of Functional Diagnostics and Rehabilitation, Faculty of Medicine, Masaryk University (ISBN
978 80 7018 463 4); 2007. p. 75–89
213.	 Siegelova J, Dusek J, Fiser B, Homolka P, Vank P, Masek M, Havelkova A, Cornélissen G, Halberg F. The relationship
between circadian blood pressure variation and age analysed from 7-day monitoring. Scripta medica
(Brno) 2007; 80 (4): 179–187
214.	 Halberg F, Cornélissen G, Siegelova J, Fiser B, Dobsak P, Kenner T, Placheta Z, Dusek J, Homolka P, Al-Kubati
M, Schwartzkopff O, Blagonravov MB, Chibisov SM, Agarwal RK. Blood pressure or, rather, blood pressure
variability disorders, VVDs, discussed in Brno on October 6, 2008. Bulletin of People’s Friendship University
of Russia: Series Medicine 2008; (7): 26–30
215.	 Halberg F, Cornélissen G, Otsuka K, Sanchez de la Peña S, Schwartzkopff O, Watanabe Y, Pati AK, Wall DG,
Delmore P, Borer K, Beaty LA, Nolley ES, Adams C, Siegelova J, Homolka P, Dusek J, Fiser B, Prikryl P. Why
and how to implement 7-day/24-hour blood pressure monitoring? Int J Geronto-Geriatrics 2005; 8 (1): 1–31.
[Dated 2005 but published in June 2008.]
216.	 Halberg F, Cornélissen G, Otsuka K, Watanabe Y, Singh RB, Revilla M, Sanchez de la Pena S, Gonzalez C,
Siegelova J, Homolka P, Dusek J, Zeman M, Singh RK, Johnson D, Fiser B. Home C-ABPM for preventive and
curative health care and transdisciplinary science. World Heart J 2008; 1 (3): 233–261
217.		 Halberg F, Cornélissen G, Siegelova J, Fiser B, Dobsak P, Kenner T, Placheta Z, Dusek J, Homolka P, Al-Kubati
M, Schwartzkopff O, Blagonravov MB, Chibisov SM, Agarwal RK. Blood pressure or, rather, blood pressure
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variability disorders, VVDs, discussed in Brno on October 6, 2008. Bulletin of People’s Friendship University
of Russia: Series Medicine 2008; (7): 26–30
218.	 Halberg F, Schwartzkopff O, Cornélissen G, Hardeland R, Müller-Bohn T, Katinas G, Revilla MA, Beaty L,
Otsuka K, Jozsa R, Zeman M, Csernus V, Hoogerwerf WA, Nagy G, Stebelova K, Olah A, Singh RB, Singh RK,
Siegelova J, Dusek J, Fiser B, Czaplicki J, Kumagai Y, Chibisov SM, Frolov VA. Vaskuläres Variabilitäts-Syndrom
(VVS) und andere Chronomik 2005–2007. In: Hardeland R, ed. Sonderdruck aus Abhandlungen der
Leibniz-Sozietät der Wissenschaften, Band 23: Facetten der Chronobiologie. Berlin: trafo verlag; 2008.
p. ­89–154
219.	 Siegelova J, Fiser B, Havelkova A, Dobsak P, Dusek J, Pohanka M, Cornélissen G, Halberg F. Ambulatory arterial
stiffness index in patients monitored for 6 consecutive days. In: Halberg F, Kenner T, Fiser B, Siegelova J,
eds. Proceedings, Noninvasive Methods in Cardiology, Brno, Czech Republic, October 4–7, 2008. p. 233–237.
Proceedings volume downloadable free of charge from http://web.fnusa.cz/files /kfdr2008/sbornik_2008.pdf
[3133]
220.	 Siegelova J, Fiser B, Havelkova A, Dobsak P, Pohanka M, Dusek J, Cornélissen G, Halberg F. Seven-day ambulatory
blood pressure monitoring and ambulatory arterial stiffness index. Scripta medica (Brno) 2008; 81 (3):
181–184
221.	 Halberg F, Cornélissen G, Otsuka K, Siegelova J, Fiser B, Dusek J, Homolka P, Sanchez de la Pena S, Singh RB,
BIOCOS project. Extended consensus on means and need to detect vascular variability disorders (VVDs) and
vascular variability syndromes (VVSs). Leibniz-Online Nr. 5, 2009 (http://www.leibniz-sozietaet.de/journal).
35 pp, AND World Heart J
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CLINICAL APPLICATION OF CARDIO-ANKLE VASCULAR INDEX
(CAVI) AS A MARKER OF ARTERIAL WALL STIFFNESS
KOHJI SHIRAI, 1
NORIO SATO
Division of Vascular Function, Internal Medicine, Sakura Hospital, Tōho University Chiba, Japan, 1
Fukuda Denshi Co.,
Tokyo, Japan
PRINCIPLE OF CAVI
The Cardio-Ankle Vascular Index (CAVI) is a new indicator of the stiffness of arteries from the origin of the aorta to
the ankle of the lower leg. The method to measure CAVI is illustrated in Fig.1.
Figure 1.
A subject is placed in supine position and electrocardiogram and heart sound are monitored. PWV between heart
and ankle is obtained by L/T where L is the distance from the aortic valve to the ankle, and T is the time during which
PWV propagates from the aortic valve to the ankle (or the sum of tb and tba in place of t’b and tba, because t’b and tb
are theoretically equal: tba is the time between the rise of the brachial pulse wave and the rise of the ankle pulse wave,
tb is the time between the aortic valve’s closing sound and the notch of the brachial pulse wave, and t’b is the time
between the aortic valve’s opening sound and the rise of the brachial pulse wave). The scale conversion from PWV to
CAVI is performed by the following formula:
CAVI = a [{2ρ × 1/(SBP − DBP)} × {In (SBP/DBP) × PWV2
}] + b
where SBPand DBPare systolic and diastolic blood pressure values, respectively, PWV is the pulse wave velocity between
heart and ankle, ρ is blood density, and a and b are constants. This equation was derived from Bramwell-Hill’s
equation and stiffness parameter ß (1). Scale conversion constants are determined so as to match CAVI with PWV
by Hasegawa’s method (2). CAVI, a stiffness and arteriosclerosis indicator of thorax, abdomen, common iliac, femoral
and tibial arteries, was measured by VaSera VS-1500 manufactured by Fukuda-Denshi Company, LTD (Tokyo,
Japan). CAVI is essentially independent of blood pressure at a measuring time (Fig. 2).
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Figure 2.
This was first confirmed in the study by Shirai K. et al (2011) using adrenergic β1 receptor-blocking agent in humans
(3). When metoprolol a selective β1-blocking agent was administered, blood pressure decreased (probably due to
the decrease in cardiac contraction) and also the pulse wave velocity (PWV). At this time CAVI remained constant
(Fig. 3, left). When α-blocker doxazosin was administered (Fig. 3, right), CAVI decreased as well as PWV. These
results indicated that CAVI reflects the smooth muscle cell contracture. Then, it is suggested that CAVI is composed
of both organic functional stiffness.
Fig. 3
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NONINVASIVE METHODS IN CARDIOLOGY 2012
CAVI IN VARIOUS ARTERIOSCLEROTIC DISEASES
The association between serum lipid levels and atherosclerotic disease, namely coronary heart disease, has been
established through the findings from several epidemiological studies such as the Seven Countries Study (4) or Multiple
Risk Factor Intervention Trial Study (5). Nakamura et al. (2008) reported that the number of stenotic coronary
vessels correlates with CAVI in patients with suspected ischemic coronary disease who took a coronary angiogra-
phy (6). Namekata et al. reported that abnormally high PWV was significantly associated with 4.5 or greater value
of the ratio of total cholesterol to high density lipoprotein (HDL) cholesterol implying that abnormal lipid imbalance
is a risk factor of arterial stiffness and arteriosclerosis (7). Aging is the strongest risk factor of arteriosclerosis. With
increasing age the CAVI value of both men and women becomes higher (Fig.4).
Figure 4. Differences in average CAVI scores by age between males (blue line) and females (green line) among
CVD risk-free individuals based on results shown in Table 2 (Vertical bars indicate standard deviation).
CAVI value is approximately 0.5 higher in men than women (equivalent to 10 years of age). A recent report supports
such an association by showing that age-specific average CAVI scores among persons with hypercholesterolemia
and hypertriglyceridemia of ages 40 and over were significantly greater than those among CVD risk-free persons
for the same age-specific groups (8). This same study have shown that age-specific average CAVI scores of all CVD
high-risk persons combined were significantly higher than those of the CVD risk-free group after 40 years of age
indicating that the overall arteriosclerosis status of the CVD high-risk group was significantly worse than that of
the CVD risk-free group. Because no difference in average CAVI scores between the two groups was detected before
40 years of age, effective CAVI screening might be recommended for people age 40 and over. CAVI can demonstrate
the true effects of blood pressure on the properties of arterial wall. CAVI declines with valsartan, olmesartan, and
candesartan among the angiotensin II receptor blockers (ARBs). Comparison between ARB and calcium channel
blockers showed, that olmesartan improves CAVI much more than amlodipine despite equivalent decrease in blood
pressure (9). This was the first time to demonstrate the effects of blood pressure decreasing drugs on arterial stiffness
using by CAVI only. CAVI shows a higher value during acute phase of increased glucose level and also in chronic
hyperglycemia. CAVI decreases by controlling HbA1c using drugs such as insulin, glicranide, and DPP-4 inhibitor.
It seems that CAVI might be a good marker of blood glucose control in routine clinical practice. Diabetes mellitus
is proven to be a risk factor for cardiovascular disease (10). It was reported that cardiovascular risk among diabetic
subjects was 5 times higher than among non-diabetics and PWV values were associated with fasting glucose levels
among diabetics (11). An odds ratio for having abnormally high PWV among diabetics is also reported to be 3.66
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NONINVASIVE METHODS IN CARDIOLOGY 2012
(p < 0.001) as compared to non-diabetics (7). These results also confirm significantly higher average age-specific
CAVI scores among persons with hyperglycemia after 40 years of age than those among CVD risk-free persons.
Higher values of CAVI were found in subjects with dyslipidemia (12). However, CAVI is not necessarily high in familial
hypercholesterolemia (LDL-receptor deficiency). In the initial stages of arteriosclerosis in hypercholesterolemia,
fatty streak are present but the arteries do not stiffen and CAVI might not be elevated. Stiffness of the arterial wall
increases only when chronic inflammatory reaction occurs. Administration of pitavastatin reduces CAVI (13). CAVI
value is high in smokers and smoking cessation reduces CAVI in few months (14). Kato et al. (2011) showed that
high CAVI values in patients with sleep apnea syndrome (15) could be decreased after administration of continuous
positive pressure assisting therapy (CPAP). It is possible to conclude that all of the cardiovascular risk factors are
integrated into the smooth muscle cells layer in the artery wall, resulting in an elevation of CAVI (Fig.5).
Figure 5.
Our preliminary and unpublished data also showed that the incidence of death (in 5 years) in subjects with CAVI
value under 9 was significantly lower compared to 506 high risk patients with CAVI over 9.
CONCLUSION AND FUTURE OF CAVI
VaSera VS-1500, which was used in above mentioned studies, was designed to measure CAVI scores independent of
blood pressure and CAVI scores represent the extent of arteriosclerosis between the aortic valve and the ankle. CAVI
scores allows to evaluate the extent of arteriosclerosis in the major arteries between the aortic valve and the ankle,
to screen persons with subclinical stage of CVD, and provide an opportunity to modify diet and lifestyle to improve
CAVI scores as reported by Satoh et al (2008). Thus, the use of CAVI scores potentially leads to savings on high treatment
costs and to prolonging many productive lives (16). CAVI is not only a good surrogate marker of arteriosclerosis
but also reflects actual compliance of the artery. Analysis of vascular functions using CAVI will develop a new field
in clinical medicine.
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NONINVASIVE METHODS IN CARDIOLOGY 2012
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atherosclerosis. Circ J 2008; 72: 598–604
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atherosclerotic risk factors among Japanese Americans in Seattle, U.S.A. Jpn J Pub Health 1997; 44: 942–951
8.	 Namekata T, Suzuki K, Ishizuka N, Shirai K. Establishing baseline criteria of cardio-ankle vascular index as
a new indicator of arteriosclerosis: a cross-sectional study BMC Cardiovasc Disord 2011; 11: 51
9.	 Miyashita Y, Saiki A, Endo K et al. Effects of olmesartan, an angiotensin II receptor blocker, and amlodipine,
a calcium channel blocker, on Cardio-Ankle Vascular Index (CAVI) in type 2 diabetic patients with hypertension.
J Atheroscler Thromb 2009; 16(5): 621–6
10.	 Assmann G, Schulte H. The Prospective Cardiovascular Munster (PROCAM) study: prevalence of hyperlipidemia
in persons with hypertension and/or diabetes mellitus and the relationship to coronary heart disease. Am
Heart J 1988; 116: 1713–1724
11.	 Christensen T, Neubauer B. Arterial wall stiffness in insulin-dependent diabetes mellitus. An in vivo study. Acta
Radiol 1987; 28: 207–208
12.	Soska V, Dobsak P, Dusek L et al. Cardio-ankle vascular index in heterozygous familial hypercholesterolemia. J
Atheroscler Thromb 2012; 19(5): 453–61
13.	 Miyashita Y, Endo K, Saiki A et al. Effects of pitavastatin, a 3-hydroxy-3-methylglutaryl coenzyme a reductase
inhibitor, on cardio-ankle vascular index in type 2 diabetic patients. J Atheroscler Thromb 2009; 16(5): 539–45.
14.	Noike H, Nakamura K, Sugiyama Y et al. Changes in cardio-ankle vascular index in smoking cessation.
J ­Atheroscler Thromb 2010; 17(5): 517–25
15.	 Kato M, Kumagai T, Naito R et al. Change in cardio-ankle vascular index by long-term continuous positive airway
pressure therapy for obstructive sleep apnea. J Cardiol 2011; 58(1): 74–82
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independent of blood pressure, in obesity and metabolic syndrome. Hypertens Res 2008; 31(10): 1921–30
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NONINVASIVE METHODS IN CARDIOLOGY 2012
CIGARETTE SMOKING AND THE CARDIO-ANKLE
VASCULAR INDEX (CAVI) OF ARTERIAL STIFFNESS:
A REPORT FROM CZECH POPULATION DATASET
PETR DOBSAK, A
VLADIMIR SOSKA, B
ONDREJ SOCHOR, MICHAELA FRANTISOVA, B
VLASTIMIL
RACEK, PAVEL HOMOLKA, PAVEL VANK, MICHAELA SOSIKOVA, C
LADISLAV DUSEK L., C
JIRI JARKOVSKY,
D
MARIE NOVAKOVA, JARMILA SIEGELOVA
Department of Physiotherapy and Department of Sports Medicine and Rehabilitation, Faculty of Medicine, Masaryk
University, St. Ann’s University Hospital in Brno, Czech Republic
a
Department of Biochemistry, Faculty of Medicine, Masaryk University, Brno, Czech Republic, b
2nd
Department of
Internal Medicine, St. Ann’s University Hospital in Brno and Masaryk University, Brno, Czech Republic, c
Institute of
Biostatistics and Analyses, Faculty of Medicine, Masaryk University, Brno, Czech Republic, d
Institute of Physiology,
Faculty of Medicine, Masaryk University, Brno, Czech Republic
ABSTRACT
This study focused on the effects of chronic smoking on the elasticity of large arteries in healthy smokers (349 males,
291 females) and nonsmokers (1.089 males, 400 females). Mean age range was 20–40 years. Arterial stiffness was
measured by the device VaSera®
1500 (Fukuda Denshi Co., Tokyo, J) and expressed as cardio-ankle vascular index
(CAVI). Statistical analysis showed a significantly higher CAVI in chronic smokers of both sexes than in healthy
controls (P < 0.01). It is possible to conclude that long-term cigarette smoking increases significantly global arterial
stiffness and thus represents also a higher risk of future cardiovascular event.
KEY WORDS
arterial stiffness; cardio-ankle vascular index (CAVI); smoking
INTRODUCTION
Tobacco smoking has been proven to be a major risk factor in the development and progression of cardiovascular
diseases. (1). Chronic smoking increases arterial stiffness (AS) and this may play a crucial role in the development
of hypertension and arteriosclerosis (2). High AS (recognized as an independent predictor of cardiovascular death)
is characterized by reduced capacity of arterial vascular tree and strong increase of pulse pressure and shear stress
(3, 4). Therefore, quick and simple non-invasive monitoring of AS is considered as very valuable approach in the early
prevention of the onset of cardiovascular diseases. The traditional, still widely used method for early detection of the
arteriosclerotic process is the measurement of brachio-ankle pulse wave velocity (baPWV – 5, 6). Parameter baPWV
provides precise data but is strongly influenced by actual changes of blood pressure (BP). This means that its assessment
and interpretation is sometimes difficult and inaccurate. Only few years ago Japanese scientists developed
and introduced into clinical praxis a new method for non-invasive measurement of AS. This method is based on the
parameter which defines arterial wall stiffness called cardio-ankle vascular index (CAVI). CAVI measures the pulsewave
velocity (PWV) from heart to ankles and blood pressure and reflects the elastic features of the arterial wall
between aorta and great peripheral arteries (7). Several reports clearly demonstrated that CAVI is associated with
the development of atherosclerosis in large arteries (8, 9). CAVI has one unique advantage – contrary to baPWV, its
value is not influenced by BP at the time of measurement (10). However, the vast majority of available data regarding
the use of CAVI was done by the Japanese authors and currently there is only minimal experience with CAVI
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NONINVASIVE METHODS IN CARDIOLOGY 2012
measurement in European populations. The aim of this study was to assess the values of parameter CAVI in healthy
non-smokers and their comparison with chronic smokers in Czech population sample.
PATIENTS AND METHODS
Recruitment of healthy volunteers was carried out in St.Anna Faculty Hospital in Brno by a campaign in radio and
newspapers. In total, 1434 (743 men; 691 women) volunteers (age range 20 to 40 years) accepted to participate in the
study. The smoking habits and the health status were assessed by a simple questionnaire. Then, the subjects were divided
into 2 groups: a) group smokers, and b) controls. Smoking male subjects (n = 349) smoked on average 10 cigarettes/day
for 8.5 ± 4.2 years; the smoking females (n = 291) smoked on average 6 cigarettes/day for 6.1 ± 2.4 years.
None of the subjects from both groups had hypertension, diabetes mellitus or cardiovascular disease. CAVI in both
groups was measured by VaSera®
1500 device (Fukuda Denshi Co, Tokyo, Japan) using standard protocol published
previously (11). Examination was performed in supine position. Four pressure cuffs were placed on limbs, 1 microphone
(phonocardiogram) above upper margin of sternum and 2 ECG leads on both upper limbs. CAVI was automatically
calculated according to following formula:
CAVI = a [{2ρ x 1/(SBP – DBP)} x ln {(SBP/DBP) x PWV2
]} + b
(ρ = blood density; a and b = constants)
In order to minimize adverse effects of cuff inflation on blood flow dynamics, the pulse waves were recorded only
when the cuffs were inflated to the pressure lower than the diastolic one (50mmHg). Blood pressure (BP) on limbs
was measured by oscillometric method; values of systolic BP (SBP), diastolic BP (DBP) and pulse pressure (PP) were
obtained from record of BP on right brachial artery. Subjects with ankle-brachial index (ABI) lower than 0.9 were
excluded from this study.
Statistical analysis was performed by the Institute of Biostatistics and Analyses (Faculty of Medicine, Masaryk University
Brno, Czech Republic) using SPSS 19.0.1 (IBM Corporation, 2010). The differences between smokers and
nonsmokers were analyzed using one-way ANOVA followed by Tukey post-hoc test and expressed as mean ± SD. The
value of P < 0.05 was considered as significant.
All patients signed informed consent to participate in the study. The study was approved by the local Ethics Committee
and conforms to the principles outlined in the Declaration of Helsinki (revised 2000) and to the GCP guidelines
of the European Community.
RESULTS
The mean CAVI value in chronic male smokers was significantly higher (Fig. 1) than in male controls (8.1 ± 2.6 vs.
7.2 ± 2.9; P < 0.01).
Similar results were found also when compared smoking and nonsmoking females (Fig. 2): the mean value of CAVI
in female smokers was significantly higher than in female controls (7.3 ± 3.8 vs. 6.4 ± 2.5; P < 0.05).
There were no significant differences in systolic (SBP) and diastolic (DBP) blood pressure at the time of measurement
between groups of male smokers (SBP was 128.3 ± 7 and DBP 82.7 ± 6 mmHg; NS) and male controls (SBP
was 130.2 ± 5 and DBP 85.2 ± 7 mmHg; NS). Similar finding was also observed in the female smokers (SBP was
125.6 ± 8 and DBP 77.1 ± 5 mmHg; NS) and female controls (SBP was 126.9 ± 7 and DBP 75.5 ± 7 mmHg; NS).
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NONINVASIVE METHODS IN CARDIOLOGY 2012
0
2
4
6
8
10
12
male smokers male non-smokers
MeanCAVI
P < 0.01
Figure 1. Comparison of CAVI value in male smokers and non-smokers (mean ± SD).
0
2
4
6
8
10
12
female smokers female non-smokers
MeanCAVI
P < 0.05
Figure 2. Comparison of CAVI value in female smokers and non-smokers (mean ± SD).
DISCUSSION
There is no doubt that cigarette smoking compromises the stability of the vessel wall, resulting in arterial stiffening.
A number of pathophysiological mechanisms responsible for the increased arterial stiffness by chronic inhalation of
tobacco smoke were identified. Fundamental is the effect of nicotine which stimulates central nervous system and
enhances the release of catecholamines from sympathetic ganglia. The permanent presence of high plasmatic level
of these vasoconstrictory substances can lead to impaired nitric oxide production and underlies the progression of
endothelial dysfunction (12, 13).
The present brief report has shown a significant effect of chronic cigarette smoking on the increase of arterial stiffness
of large arteries assessed by parameter CAVI. Furthermore, we have demonstrated that the deleterious effect
of chronic smoking is present in relatively young people (20–40 years) regardless of their gender. Our results per-
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NONINVASIVE METHODS IN CARDIOLOGY 2012
formed in Czech population sample suggest also that the hemodynamic consequences of chronic smoking may have
been underestimated. Arterial stiffness is now widely recognized as a more sensitive prognostic factor of vascular
events than either systolic or diastolic BP alone in adult populations. Smoking in the younger population, particularly
in women, is still very frequent in many member countries of the European Union. An additional comparison of the
CAVI values in smokers with preliminary interim standards for the Czech healthy population showed that elasticity
of arteries in smokers (both male and female) corresponds to healthy subjects about 10 years older. From this point
of view it is likely, that female gender do not play any protective role on vascular system in long-term smoking. On
the other hand, early and accurate detection of arterial elasticity changes provides also an opportunity for adequate
intervention, such as lifestyle modification.
Results of this study confirm the previous observations comparing smokers and non-smoking controls. Kool et al.
(1993) showed that smoking decreases arterial elasticity of large elastic and medium-sized peripheral arteries (14).
Another study reported an acute decrease of the compliance of radial artery after smoking of only 1 cigarette (15).
Inhalation of cigarette smoke provokes deep disturbances in vascular function of central and peripheral vessels (16,
17). McVeigh et al. (1997) demonstrated strong abnormalities in the brachial artery pressure waveforms in chronic
smokers (18). Moreover, cigarette smoking in older subjects without atherosclerosis is associated with rise of stiffness
in carotid arteries (19). Similarly to the present study, also Kubozono et al. (2011) reported that chronic cigarette
smokers have abnormal values of the CAVI and baPWV parameters (20). One most recent trial demonstrated
that there is a significant association between the number of cigarettes smoked per day and arterial stiffness measured
by CAVI (21). However, these harmful effects are not definite and could be reversed by smoking cessation (22).
CONCLUSION
According to the presented results chronic smokers have significantly worse arterial stiffness than non-smokers.
This finding means also that long-term smoking increases the arterial wall stiffness and global cardiovascular risk.
One of the main outcomes for clinical praxis is that CAVI was proven to be a valuable parameter for assessment of
arterial stiffness caused by smoking. Therefore, regular CAVI monitoring in active smokers may help to popularize
and enhance smoking cessation.
ACKNOWLEDGEMENT
This study was supported by Fukuda Denshi Co., Tokyo, Japan.
REFERENCES
1.	 Jacobs DR, Adachi H, Mulder I et al. Cigarette smoking and mortality risk: twenty-five year follow up of the
Seven Countries Study. Arch Intern Med 1999; 733–740
2.	 Ockene IS, Miller NH. Cigarette smoking, cardiovascular disease, and stroke: A statement for healthcare professionals
from the American Heart Association: American Heart Association Task Force on Risk Reduction.
Circulation 1997; 96: 3243–3247
3.	 Boutouyrie P, Tropeano AI, Asmar R et al. Aortic stiffness is an independent predictor of primary coronary
events in hypertensive patients: a longitudinal study. Hypertension 2002; 39: 10–15
4.	 Dernellis J, Panaretou M. Aortic stiffness is an independent predictor of progression to hypertension in nonhypertensive
subjects. Hypertension 2005; 45: 426–31
5.	 Yamashina A, Tomiyama H, Takeda K, et al. Validity, reproducibility, and clinical significance of noninvasive
brachial-ankle pulse wave velocity measurement. Hypertens Res 2002; 25: 359–64
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NONINVASIVE METHODS IN CARDIOLOGY 2012
6.	 Munakata M, Ito N, Nunokawa T, Yoshinaga K. Utility of automated brachial ankle pulse wave velocity measurements
in hypertensive patients. Am J Hypertens 2003; 16: 653–7
7.	 Yambe T, Yoshizawa M, Saijo Y, et al. Brachio-ankle pulse wave velocity and cardio-ankle vascular index (CAVI).
Biomed Pharmacother 2004; 58: 95–8
8.	 Nakamura K, Tomaru T, Yamamura S, Miyashita Y, Shirai K, Noike H. Cardio-ankle vascular index is a candidate
predictor of coronary atherosclerosis. Circ J 2008; 72: 598–604
9.	 Izuhara M, Shioji K, Kadota S et al. Relationship of cardio-ankle vascular index (CAVI) to karotid and coronary
arteriosclerosis. Circ J 2008; 72: 1762–1767
10.	 Shirai K, Utino J, Otsuka K, Takata M. A novel blood pressure independent arterial wall stiffness parameter;
cardio-ankle vascular index (CAVI). J Atheroscler Thromb 2006; 13: 101–107
11.	 Takaki A, Ogawa H, Wakeyama T et al. Cardio-ankle vascular index is a new noninvasive parameter of arterial
stiffness. Circ J 2007; 71: 1710–1714
12.	Powell JP. Vascular damage from smoking: disease mechanisms at the arterial wall. Vasc Med 1998; 3: 21–28
13.	 Van den Berkmortel FWPJ, Wollersheim H, van Langan H, de Boo T, Thien T. Dynamic vessel wall properties
of large conduit arteries in habitual cigarette smokers. Eur J Intern Med 1999; 10: 159–156
14.	Kool MJ, Hoeks AP, Struijker Boudier HA, Reneman RS, Van Bortel LM. Short and long-term effects of smoking
on arterial wall properties in habitual smokers. J Am Coll Cardiol 1993; 22: 1881–1886
15.	 Giannattasio C, Mangoni AA, Stella ML, Carugo S, Grassi G, Mancia G. Acute effects of smoking on radial
artery compliance in humans. J Hypertens 1994; 12: 691–696
16.	Yufu K, Takahashi N, Okada N et al. Influence of systolic blood pressure and cigarette smoking on endothelial
function in young healthy people. Circ J 2009; 73: 174–178
17.	 Ambrose JA, Barua RS. The pathophysiology of cigarette smoking and cardiovascular disease: An update. J Am
Coll Cardiol 2004; 43: 1731–1737
18.	McVeigh G, Morgan DJ, Finkelstein SM, Lemay LA. Vascular abnormalities associated with long-term cigarette
smoking identified by arterial waveform analysis. Am J Med 1997; 102: 227–231
19.	 Liang YL, Shiel LM, Teede H et al. Effects of blood pressure, smoking and their interaction on carotid artery
structure and function. Hypertension 2001; 37: 6–11
20.	Kubozono T, Miyata M, Ueyama K et al. Acute and chronic effects of smoking on arterial stiffness. Circ J 2011;
75(3): 698–702
21.	 Hata K, Nakagawa T, Mizuno M et al. Relationship between smoking and a new index of arterial stiffness, the
cardio-ankle vascular index, in male workers: a cross-sectional study. Tob Induc Dis 2012; 10(1): 11
22.	Noike H, Nakamura K, Sugiyama Y et al. Changes in cardio-ankle vascular index in smoking cessation.
J ­Atheroscler Thromb 2010; 17: 517–525
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NONINVASIVE METHODS IN CARDIOLOGY 2012
DAY-TO-DAY VARIABILITY OF 24-HOUR MEAN BLOOD
PRESSURE IN MAN: SEVEN-DAY AMBULATORY
BLOOD PRESSURE MONITORING
JARMILA SIEGELOVA, ALENA HAVELKOVA, MICHAL POHANKA, JIRI DUSEK, LEONA DUNKLEROVA,
PETR DOBSAK, *GERMAINE CORNELISSEN, *FRANZ HALBERG
Department of Physiotherapy, Dept. of Sport Medicine and Rehabilitation, Faculty of Medicine, Masaryk University,
Brno, St. Ann’s University Hospital in Brno, Czech Republic
*University of Minnesota, USA
Dedicated to the 93rd
anniversary of Prof. Franz Halberg
INTRODUCTION
Ambulatory blood pressure monitoring has an important place in defining abnormal pattern of blood pressure. Clinical
measurement of blood pressure will continue to be useful for screening and management of suspected and true
hypertension, ambulatory blood pressure monitoring provides considerable added value towards accurate diagnosis
and provision of the optimal care in uncompleted hypertension as well as for patients with moderate or severe cardiovascular
risk. The cardiovascular risk is based on assessment of all major risk factors, age, sex, waist circumferences,
BMI, family history, blood lipids, glucose metabolism, style of life (Guidelines 2007).
In previous studies Halberg et al. (2009, 2010, 2011, 2012) and Siegelova et al. (2006, 2011) have shown the differences
in repeated ambulatory blood pressure monitoring, therefore we started with the ambulatory blood pressure
monitoring lasting seven consecutive days.
Johansson et al. in Finn-home study (2010) used the 7-day home blood pressure monitoring to demonstrate the
prognostic significance of home BP and heart rate variability. Several studies indicate that home BP measurement
offers better prognostic value than office BP. Results of our laboratory suggest the drawback of 24-hours ambulatory
blood pressure monitoring.
METHODS
Thirty subjects (18 males, 12 females), twenty one years to seventy three years old, were recruited for seven-day
blood pressure monitoring. Medical Instruments A and D (Japan) were used for ambulatory blood pressure monitoring
(oscillation method). One-hour means of systolic (SBP) and diastolic blood pressure (DBP) were evaluated,
where night-time was considered from midnight to 06.00 h and day-time from 10.00 to 22.00 h, avoiding the transitional
periods. Mean day-time and mean night-time SBP and DBP were evaluated every day.
RESULTS
To compare 24-hour mean and 7-day means the Bland-Altman plots were constructed (Fig. 1, Fig. 2, Fig. 3, Fig. 4).
The ± 1.96 standard deviation of the difference (mmHg) among the seven-day mean and every day means was 12.43
for SBP-day, 13.86 for SBP-night, 8.57 for DBP-day and 10.82 for DBP-night. Taking into account the Guidelines
for Management of Hypertension (2007) all values are too large to make possible a reliable guidance of indication
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NONINVASIVE METHODS IN CARDIOLOGY 2012
for treatment based on 24-hour mean values of blood pressure. According to this the threshold for definition of hypertension
for systolic blood pressure is 140 mmHg in the office or clinic. Ambulatory blood pressure monitoring
values are lower, 125–130 mmHg during 24 hours, 130–135 mmHg during day and 120 mmHg during night. The
corresponding values for diastolic blood pressure are 90 mmHg in the office and clinic, 80 mmHg during 24 hours,
85 mmHg during day and 75 mmHg during night. The values for home measurement are the same as for ambulatory
blood pressure monitoring during day.
Taking 135 mmHg of day-time systolic pressure as a threshold for indication to treatment, then 13 patients (43 %)
were under this value every day and nobody was over this value every day. 17 patients (57 %) were one day indicated
for treatment and the other day not.
Similarly, if 120 mmHg of night-time systolic pressure is the threshold, then 10 subjects (33 %) were indicated one
day for treatment and the other day not.
Corresponding value of threshold for diastolic day-time pressure is 85 mmHg, thus 22 patients (73 %) were one day
indicated for treatment and the other day not and for night diastolic pressure of 70 mmHg 24 patients (80 %) were
indicated one day for treatment and the other day not. Only one patient (3 %) was indicated for treatment every day
on the DBP night basis.
CONCLUSION
Those data demonstrate large day-to-day SBP and DBP mean day-time and mean night-time variability and suggest
that long time home BP monitoring is preferable method for diagnosis and treatment of hypertension.
Support: GM-13981 (FH), University of Minnesota Supercomputing Institute (GC, FH)
SBP day
-30
-20
-10
0
10
20
30
90 100 110 120 130 140
7-day mean (mmHg)
Diferencebetwen24-hoursmeanand7daymean(mmHg)
1.1. BlandBland--Altman plotAltman plot:: Comparisons between 7Comparisons between 7--day means and 24day means and 24--hour means of SBPhour means of SBP
during dayduring day.. TheThe ±±1.96 standard deviations of the difference are indicated (dashed1.96 standard deviations of the difference are indicated (dashed line).line).
Figure 1. Bland-Altman plots. Comparisons between 7-days means and 24-hours means of SBP during day. The ± 1.96 standard
deviations of the difference are indicated (dashed line).
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NONINVASIVE METHODS IN CARDIOLOGY 2012
SBP night
-30
-20
-10
0
10
20
30
90 100 110 120 130 140
7-day mean (mmHg)
Diferencebetwen24-hoursmeanand7daymean(mmHg)
2.2. BlandBland--Altman plotAltman plot:: Comparisons between 7Comparisons between 7--day means and 24day means and 24--hour means of SBPhour means of SBP
during nightduring night.. TheThe ±±1.96 standard deviations of the difference are indicated (dashed1.96 standard deviations of the difference are indicated (dashed line).line).
Figure 2. Bland-Altman plots. Comparisons between 7-days means and 24-hours means of SBP at night. The ± 1.96 standard
deviations of the difference are indicated (dashed line).
DBP day
-30
-20
-10
0
10
20
30
55 65 75 85 95 105
7-day mean (mmHg)
Diferencebetwen24-hoursmeanand7daymean(mmHg)
3.3. BlandBland--Altman plotAltman plot:: Comparisons between 7Comparisons between 7--day means and 24day means and 24--hour means of DBPhour means of DBP
during day. Theduring day. The ±±1.96 standard deviations of the difference are indicated (dashed1.96 standard deviations of the difference are indicated (dashed line).line).
Figure 3. Bland-Altman plots. Comparisons between 7-days means and 24-hours means of DBP during day. The ± 1.96 standard
deviations of the difference are indicated (dashed line).
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NONINVASIVE METHODS IN CARDIOLOGY 2012
DBP night
-30
-20
-10
0
10
20
30
55 65 75 85 95 105
7-day mean (mmHg)
Diferencebetwen24-hoursmeanand7daymean(mmHg)
4.4. BlandBland--Altman plotAltman plot:: Comparisons between 7Comparisons between 7--day means and 24day means and 24--hour means of DBPhour means of DBP
during night. Theduring night. The ±±1.96 standard deviations of the difference are indicated (dashed1.96 standard deviations of the difference are indicated (dashed line).line).
Figure 4. Bland-Altman plots. Comparisons between 7-days means and 24-hours means of DBP during night. The ± 1.96 standard
deviations of the difference are indicated (dashed line).
REFERENCES
1.	 Halberg F,Cornelissen G,Hillman D,Beaty lA,Hong S, Schwarzkoppf O, Watanabe Y,Otsuka K,Siegelova
J.Chronobiologically interpreted ambulatory blood pressure monitoring in health and disease. Global Adv
Health Med 2012; 1 (2): 66–123
2.	 Halberg F, Cornelissen G, Katinas GS, Watanabe Y, Siegelova J. Follow-up to the Cornelissen-series: Inheritance
of form in space from parents and of form in time from the cosmos: From Brno’s Mendel and Siegelova,
respectively. Cosmic inheritance rules.in eds. 3. Halberg F, Kenner T, Fiser B, Siegelova J. Noninvasive methods
in cardiology 2009. Masaryk University, Brno. 2009, p. 13–39, ISBN 978-80-7013-501-3
3.	 Siegelova J, Fiser B. Day-today variability of 24-h mean values of SBP and DBP in patients monitored for 7 consecutive
days. J Hypertens, 2011; 29, 4: 818–819
4.	 Halberg F, Cornelissen G, Otsuka K, Siegelova J, Fiser B, Dusek J, Homolka P, Sanches de la Pena S, Singh RB
and the BOCOS project. Extended consensus on means and need to detect vascular variability disorders and
vascular variability syndrome. World Heart J 2010; 2,4: 279–305 (cf. Leibnitz-online Nr.5 ,2009, http: www2huberlin.de/Leibnitz-sozietaet/journal/archive_5_09.html.
35 pp)
5.	 Halberg F, Cornelissen G, Dusek J, Kenner B, Kenner A, Schwarzkoppf O, Siegelova J. Bohumil Fiser
(*22. 10. 1943 – 21. 3. 2011):Chronobiologist, Emeritus Head of the Physiology Department at Masaryk University
(Brno, Czech Republic), Czech Minister of Health, and Executive Board Member of World Health Organization:
His Legacies for Public and Personal Health Care. World Heart J 2011; 3, 1: 63–77
6.	 Johansson JK, Niiranen TJ, Puukka PJ, Jula AM. Factors affecting variability of home-measured blood pressure
and heart rate: the Finn-home study. J Hypertens, 2010; 28: 1836–1845
7.	 Siegelova J, Dusek J, Fiser B, Homolka P, Vank P, Kohzuki M, et al. Relationship between circadian blood pressure
variation and age analyzed from 7-day ambulatory monitoring. J Hypertens, 2006; 24 (Suppl. 6): 122
8.	 2007 Guidelines for the management of arterial hypertension: The task force for the management of arterial
hypertension of the European Society of Hypertension (ESH) and of the European Society of Cardiology (ESC).
J Hypertens, 2007; 25: 1105–1187
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NONINVASIVE METHODS IN CARDIOLOGY 2012
SEVEN-DAY AMBULATORY BLOOD PRESSURE
MONITORING: BLOOD PRESSURE VARIABILITY
AT REST AND DURING EXERCISE
JARMILA SIEGELOVA, ALENA HAVELKOVA, JIRI DUSEK, MICHAL POHANKA, LEONA DUNKLEROVA,
PAVEL VANK, PETR DOBSAK, GERMAINE CORNELISSEN*, FRANZ HALBERG*
Department of Physiotherapy, Department of Sport Medicine and Rehabilitation, Faculty of Medicine,
Masaryk University, St. Ann’s University Hospital in Brno, CZ
*University of Minnesota, USA
Dedicated to the 80th
anniversary of Prof. Thomas Kenner
INTRODUCTION
Because the diagnosis of hypertension is generally based on casual measurement of blood pressure in general practitioner
office and these values of blood pressure are higher than values of ambulatory blood pressure monitoring, the
table of blood pressure thresholds for definition of hypertension with different types of measurement is included in
the Guidelines for Management of Hypertension (2007).
According to this table the threshold for systolic blood pressure is 140 mmHg in the office or clinic, 125–130 mmHg
during 24 hours, 130–135 mmHg during day and 120 mmHg during night.
The corresponding values for diastolic blood pressure are 90 mmHg in the office and clinic, 80 mmHg during
24 hours, 85 mmHg during day and 75 mmHg during night.
The values for home measurement are the same as for ambulatory monitoring during day.
The condition for reliability of diagnosis is low day-to-day variation of night-time and day-time pressure values.
Table 1.
JJ HypertensionHypertension 20072007
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NONINVASIVE METHODS IN CARDIOLOGY 2012
In the presentation in 2010 we have shown that variations of night-time and day-time blood pressure during 7-day
continuous ambulatory monitoring are large. In 31 healthy subjects at rest we have shown at daytime and at night
big differences given in Fig. 1, 2, 3, 4.
Seven-day monitoring SBP day
0
20
40
60
80
100
120
140
160
1,
3,
5,
7,
9,
11,
13,
15,
17,
19,
21,
23,
25,
27,
29,
Patient No
DaytimemeanSBPmmHg
Figure 1. The variability of one-daytime SBP values during 7-day monitoring. The patients were ordered according mean 7-day SBP
(patient No 1: 107 mmHg, patient No 30: 131 mmHg; median value: 123 mmHg). One-day mean values (point) and 7-day mean
values (dash) are indicated.
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NONINVASIVE METHODS IN CARDIOLOGY 2012
Seven-day monitoring SBP night
0
20
40
60
80
100
120
140
160
180
1,
3,
5,
7,
9,
11,
13,
15,
17,
19,
21,
23,
25,
27,
29,
Patient No
NighttimemeanSBPmmHg
Figure 2. The variability of one-nighttime SBP values during 7-day monitoring. The patients were ordered according mean 7-day SBP
(patient No 1: 107 mmHg, patient No 30: 131 mmHg; median value: 123 mmHg). One-day mean values (point) and 7-day mean
values (dash) are indicated.
Seven-day monitoring DBP day
0
20
40
60
80
100
120
1,
3,
5,
7,
9,
11,
13,
15,
17,
19,
21,
23,
25,
27,
29,
Patient No
DaytimemeanDBPmmHg
Figure 3. The variability of one-daytime DBP values during 7-day monitoring. The patients were ordered according mean 7-day SBP
(patient No 1: 107 mmHg, patient No 30: 131 mmHg; median value: 123 mmHg). One-day mean values (point) and 7-day mean
values (dash) are indicated.
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NONINVASIVE METHODS IN CARDIOLOGY 2012
Seven-day monitoring DBP night
0
10
20
30
40
50
60
70
80
90
100
1,
3,
5,
7,
9,
11,
13,
15,
17,
19,
21,
23,
25,
27,
29,
Patient No
NighttimemeanDBPmmHg
Figure 4. The variability of one-nighttime DBP values during 7-day monitoring. The patients were ordered according mean 7-day
SBP (patient No 1: 107 mmHg, patient No 30: 131 mmHg; median value: 123 mmHg). One-day mean values (point) and 7-day mean
values (dash) are indicated.
THE PURPOSE OF THE STUDY
The aim of the study was to compare 24-hour profile of 7-day blood pressure monitoring at rest and during exercise.
SUBJECTS
We examined 21 men, healthy subjects, mean age 29 ± 4.9 years (from 23 to 39).
For exercise training we used bicycle ergometer Kettler, type X7, Germany, 2× during week, constant load 120 W,
lasting 60 min. Every exercise unit was composed from warm-up period 3 min, load 54 min and cool-down period 3
min.
METHODS
The subjects were recruited for seven-day blood pressure monitoring. Medical Instruments (A&D, Japan) were used
for ambulatory blood pressure monitoring (oscillation method). One-hour means of systolic and diastolic blood pressure
were evaluated.
Mean day-time and mean night-time systolic and diastolic pressures were evaluated every day and we calculated
mean systolic and diastolic blood pressure for seven days.
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NONINVASIVE METHODS IN CARDIOLOGY 2012
Figure 5. Seven-day ambulatory blood pressure monitoring in one man
Figure 6. Medical Instruments (A&D, Japan) – ambulatory blood pressure monitoring
RESULTS
The healthy subjects (men) were ordered according mean 7-day SBP (subject No 1: 107 mmHg, subject No 21:
121 mmHg; median value: 121 mmHg).
The variability of one-daytime SBP values during 7-day monitoring is seen in Fig. 7 at rest and in Fig. 8 during
exercise.
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NONINVASIVE METHODS IN CARDIOLOGY 2012
100
105
110
115
120
125
130
135
140
145
150
0 2 4 6 8 10 12 14 16 18 20 22
MEN
SBP[mmHg]
MEAN 24 h interval
Figure 7. The variability of 24-hour mean systolic blood pressure (black points) and 7-day mean systolic blood pressure (red line)
at rest in 21 healthy subjects.
100
105
110
115
120
125
130
135
140
145
150
0 2 4 6 8 10 12 14 16 18 20 22
MEN
SBP[mmHg]
MEAN Cycling 8 - 12 h Cycling 12 - 16 h Cycling 16 - 20 h
Figure 8. The variability of 24-hour mean systolic blood pressure (points in color) and 7-day mean systolic blood pressure (red line)
during exercise in 21 healthy subjects.
The variability of one-daytime DBP values during 7-day monitoring is seen in Fig. 9 at rest and in Fig. 10 during
exercise.
Mean 7-day DBP (subject No 1: 61 mmHg, subject No 21: 85 mmHg; median value: 70 mmHg).
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NONINVASIVE METHODS IN CARDIOLOGY 2012
50
55
60
65
70
75
80
85
90
0 2 4 6 8 10 12 14 16 18 20 22
MEN
DBP[mmHg]
MEAN 24 h interval
Figure 9. The variability of 24-hour mean diastolic blood pressure (black points) and 7-day mean diastolic blood pressure (red line)
at rest in 21 healthy subjects.
50
55
60
65
70
75
80
85
90
0 2 4 6 8 10 12 14 16 18 20 22
MEN
DBP[mmHg]
MEAN Cycling 8 - 12 h Cycling 12 -16 h Cycling 16 - 20 h
Figure 10. The variability of 24-hour mean diastolic blood pressure (points in color) and 7-day mean diastolic blood pressure
(red line) during exercise in 21 healthy subjects.
DISCUSSION
Seven-day ambulatory blood pressure monitoring demonstrates large day-to-day variability of blood pressure at rest.
Our studies indicate with blood pressure monitoring that longer monitoring, preferably for 7 days, is recommended.
In our presentation we show a large variability of 24-hour profile at rest in 5 days and in 2 days with exercise. The
variability day-to-day in 24-hour profile was presented at rest and during exercise in 21 healthy subjects. During
exercise, even that these data were measured only 2 days we observed similar variability as it was described at rest
before.
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NONINVASIVE METHODS IN CARDIOLOGY 2012
Hypertension is currently diagnosed mostly by means of a single measurement or a few measurements during few
consecutive examinations. This practice can be associated with over 40 % false diagnoses due in part to large variability
in blood pressure as such and in response to external factors.
It is clear that 24-hour monitoring is better than a single measurement or a few measurements, but for avoiding misdiagnosis
is not sufficient. Our results show that 7-day blood pressure monitoring is the best way for blood pressure
real values and it is in agreement with the results of BIOCOS project, under the guidance of professor Halberg and
professor Cornélissen.
Self-measurement of blood pressure at home can also provide very important blood pressure values that, when averaged
over a period of a few days, are more reproducible and predict the presence and progression of organ damage
as well as the risk of cardiovascular events better than office values. Home blood pressure measurement for suitable
periods can be recommended before and during the treatment also because this relatively cheap procedure may improve
patient adherence to treatment.
CONCLUSION
From the results we can conclude that 24-hour blood pressure profile at rest and during exercise varies day-to-day
and we recommend the 7-day blood pressure monitoring. The education for long-lasting self-monitoring is the best
approach for management of hypertension.
Support: GM-13981 (FH), University of Minnesota Supercomputing Institute (GC, FH)
REFERENCES
1.	 E O’Brien, J Sheridan and K O’Malley, Dippers and non-dippers, Lancet 332 (1988), p.397
2.	 T Ohkubo, A Hozawa and J Yamaguchi et al., Prognostic significance of the nocturnal decline in blood pressure
in individuals with and without high 24-h blood pressure: the Ohasama study, J Hypertens 20 (2002),
pp. ­2183–2189
3.	 TW Hansen, J Jeppesen, F Rasmussen, H Ibsen and C Torp-Pedersen, Ambulatory blood pressure monitoring
and mortality: a population-based study, Hypertension 45 (2005), pp. 499–504
4.	 E Ingelsson, K Björklund, L Lind, J Ärnlöv and J Sundström, Diurnal blood pressure pattern and risk of congestive
heart failure, JAMA 295 (2006), pp. 2859–2866
5.	 G Mancia, R Facchetti, M Bombelli, G Grassi and R Sega, Long-term risk of mortality associated with selective
and combined elevation in office, home, and ambulatory blood pressure, Hypertension 47 (2006), pp. 846–853
6.	 P Verdecchia, C Porcellati and G Schillaci et al., Ambulatory blood pressure. An independent predictor of prognosis
in essential hypertension, Hypertension 24 (1994), pp. 793–801
7.	 José Boggia, Yan Li, Lutgarde Thijs et al. Prognostic accuracy of day versus night ambulatory blood pressure:
a cohort study. Lancet 370 (2007), p.1219–1229
8.	 The Task Force for the Management of Arterial hypertension of the European Society of Hypertension (ESH)
and of the European Society of Cardiology (ESC). 2007 Guidelines for the Management of Arterial Hypertension.
J Hypertension 2007, 25:1105–1187
9.	 J. Siegelová, J. Dusek, B. Fiser, P. Homolka, P. Vank, M. Kohzuki, G. Cornellisen, F. Halberg. Relationship between
circadian blood pressure variation and age analyzed from 7-day ambulatory monitoring. J Hypertension,
2006, vol. 24, Suppl. 6, p. 122
10.	 Redón J, Vicente A, Alvarez V et. al. Circadian rhythm variability of arterial pressure: methodological aspects
for the measurement. Med Clin, 1999 112:258–289
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NONINVASIVE METHODS IN CARDIOLOGY 2012
11.	 Cornélissen G, Delcour A, Toussain G et al. Opportunity of detecting pre-hypertension: world wide data on
blood pressure overswinging. Biomedicine and Pharmacotherapy 59 (2005) S152–S157
12.	Management Committee, Australian National Blood Pressure Study: The Australian Therapeutic Trial in Mild
Hypertension. Lancet 1980, (June 14)i(8184):1261–7
13.	 Zarnke KB, Feagan BG, Mahon JL et al. A randomized study comparing a patient-directed hypertension management
strategy with usual office-based care. Am J. Hypertension 1997, 10: 58–67
14.	Halberg F,Cornelissen G,Hillman D,Beaty lA,Hong S, Schwarzkoppf O, Watanabe Y,Otsuka K,Siegelova
J.Chronobiologically interpreted ambulatory blood pressure monitoring in health and disease. Global Adv
Health Med 2012;1(2): 66–123
15.	 Halberg F, Cornelissen G, Katinas GS, Watanabe Y, Siegelova J. Follow-up to the Cornelissen-series: Inheritance
of form in space from parents and of form in time from the cosmos: From Brno’s Mendel and Siegelova,
respectively. Cosmic inheritance rules.in eds. 3.Halberg F, Kenner T,Fiser B, Siegelova J. Noninvasive methods
in cardiology 2009. Masaryk University, Brno. 2009, p. 13–39, ISBN 978-80-7013-501-3
16.	Siegelova J, Fiser B. Day-today variability of 24-h mean values of SBP and DBP in patients monitored for 7 consecutive
days. J Hypertens, 2011; 29, 4: 818–819
17.	 Halberg F, Cornelissen G, Otsuka K, Siegelova J, Fiser B, Dusek J, Homolka P, Sanches de la Pena S, Singh
RB and the BOCOS project. Extended consensus on means and need to detect vascular variability disorders
and vascular variability syndrome. World Heart J 2010; 2, 4: 279–305 (cf. Leibnitz-online Nr. 5 ,2009, http:
www2hu-berlin.de/Leibnitz-sozietaet/journal/archive _5_09.html. 35 pp)
18.	Halberg F, Cornelissen G, Dusek J, Kenner B, Kenner A, Schwarzkoppf O, Siegelova J. Bohumil Fiser
(*22. 10. 1943 – 21. 3. 2011): Chronobiologist, Emeritus Head of the Physiology Department at Masaryk University
(Brno, Czech Republic), Czech Minister of Health, and Executive Board Member of World Health Organization:
His Legacies for Public and Personal Health Care. World Heart J 2011; 3,1: 63–77
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NONINVASIVE METHODS IN CARDIOLOGY 2012
FATHER OF CHRONOBIOLOGY:
PROF. DR. FRANZ HALBERG, 93 YEARS OF AGE
JARMILA SIEGELOVA
Dept. of Physiotherapy and Rehabilitation, Dept. of Sportsmedicine and Rehabilitation, Faculty of Medicine,
Masaryk University, St. Ann’s University Hospital in Brno, Brno
Franz Halberg, M.D., Dr. h.c. (Montpellier), Dr. h.c. (Ferrara), Dr. h.c. (Tyumen), Dr. h.c. (Brno), Dr. h.c. (L‘Aquila),
Dr. h.c. (People‘s Friendship University of Russia, Moscow), Professor of Laboratory Medicine and Pathology, Physiology, Biology,
Bioengineering and Oral medicine, Director, Halberg Chronobiology Center, University of Minnesota, Mayo Mail Code 8609,
Dept of Laboratory Medicine, Minneapolis Campus 420 Delaware Street SE, Minneapolis, MN 55455, USA
Franz Halberg is a founder of modern chronobiology. Unlike other famous scientists devoting there activities mostly
to presentation of honorary lectures at international scientific conferences Prof Halberg continues in scientific work.
This fact demonstrates the list of his scientific papers on WEB of Science which contains 1172 scientific papers, Science
Citation Report of Franz Halberg contains 13874 citations, and his H-index is 53.
Prof Halberg suffers by the fact, that his ideas overrun the development of science for tens of years. He suggested
the ambulatory 24 hours blood monitoring in 1948. We feel honored to have had the possibility of cooperation with
Professor Halberg since 1980s. In the year 2000, Prof. Franz Halberg from University of Minnesota, USA, received
the degree of honorary doctor of Masaryk University Brno. The first scientific study using the Halberg’s method in
Czech Republic was published in 1993. Also the treatment of oncology diseases on the chronobiological basis started
many years after Halberg suggestion. The last Halberg proposal for diagnosis of vascular variability disorders on the
basis of several day ambulatory blood pressure and heart rate monitoring or on the basis of several days lasted selfmonitoring
is nowadays not broadly accepted; despite it enables the risk stratification of hypertensive patients. The
risk-stratification guided treatment is more effective than the treatment based on diagnosis only.
I and my colleges from Masaryk University Brno wish professor Halberg good health necessary to continue his scientific
work for many years. I also wish scientific community to accept all Franz Halberg ideas as quickly as possible,
because it is an interest of patients all over the world. Ad multos annos!
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NONINVASIVE METHODS IN CARDIOLOGY 2012
SELECTED PUBLICATIONS
1.	 Halberg F, Cornélissen G, Siegelova J, Fiser B, Dobsak P, Kenner T, Placheta Z, Dusek J, Homolka P, Al-Kubati
M, Schwartzkopff O, Blagonravov MB, Chibisov SM, Agarwal RK. Blood pressure or, rather, blood pressure
variability disorders, VVDs, discussed in Brno on October 6, 2008. Bulletin of People’s Friendship University of
Russia: Series Medicine 2008; (7): 26–30
2.	 Halberg F, Cornélissen G, Otsuka K, Sanchez de la Peña S, Schwartzkopff O, Watanabe Y, Pati AK, Wall DG,
Delmore P, Borer K, Beaty LA, Nolley ES, Adams C, Siegelova J, Homolka P, Dusek J, Fiser B, Prikryl P. Why
and how to implement 7-day/24-hour blood pressure monitoring? Int J Geronto-Geriatrics 2005; 8 (1): 1–31.
[Dated 2005 but published in June 2008.]
3.	 Halberg F, Cornélissen G, Otsuka K, Watanabe Y, Singh RB, Revilla M, Sanchez de la Pena S, Gonzalez C,
Siegelova J, Homolka P, Dusek J, Zeman M, Singh RK, Johnson D, Fiser B. Home C-ABPM for preventive and
curative health care and transdisciplinary science. World Heart J 2008; 1 (3): 233–261
4.	 Halberg F, Cornélissen G, Siegelova J, Fiser B, Dobsak P, Kenner T, Placheta Z, Dusek J, Homolka P, Al-Kubati
M, Schwartzkopff O, Blagonravov MB, Chibisov SM, Agarwal RK. Blood pressure or, rather, blood pressure
variability disorders, VVDs, discussed in Brno on October 6, 2008. Bulletin of People’s Friendship University of
Russia: Series Medicine 2008; (7): 26–30
5.	 Halberg F, Schwartzkopff O, Cornélissen G, Hardeland R, Müller-Bohn T, Katinas G, Revilla MA, Beaty L,
Otsuka K, Jozsa R, Zeman M, Csernus V, Hoogerwerf WA, Nagy G, Stebelova K, Olah A, Singh RB, Singh RK,
Siegelova J, Dusek J, Fiser B, Czaplicki J, Kumagai Y, Chibisov SM, Frolov VA. Vaskuläres Variabilitäts-Syndrom
(VVS) und andere Chronomik 2005–2007. In: Hardeland R, ed. Sonderdruck aus Abhandlungen der LeibnizSozietät
der Wissenschaften, Band 23: Facetten der Chronobiologie. Berlin: trafo verlag; 2008. p. 89–154
6.	 Siegelova J, Fiser B, Havelkova A, Dobsak P, Dusek J, Pohanka M, Cornélissen G, Halberg F. Ambulatory arterial
stiffness index in patients monitored for 6 consecutive days. In: Halberg F, Kenner T, Fiser B, Siegelova J,
eds. Proceedings, Noninvasive Methods in Cardiology, Brno, Czech Republic, October 4–7, 2008. p. 233–237.
Proceedings volume downloadable free of charge from http://web.fnusa.cz/files/ kfdr2008/sbornik_2008.pdf
[3133]
7.	 Siegelova J, Fiser B, Havelkova A, Dobsak P, Pohanka M, Dusek J, Cornélissen G, Halberg F. Seven-day ambulatory
blood pressure monitoring and ambulatory arterial stiffness index. Scripta medica (Brno) 2008; 81 (3):
181–184
8.	 Halberg F, Cornélissen G, Otsuka K, Siegelova J, Fiser B, Dusek J, Homolka P, Sanchez de la Pena S, Singh RB,
BIOCOS project. Extended consensus on means and need to detect vascular variability disorders (VVDs) and
vascular variability syndromes (VVSs). Leibniz-Online Nr. 5, 2009 (http://www.leibniz-sozietaet.de/journal).
35 pp, AND World Heart J
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NONINVASIVE METHODS IN CARDIOLOGY 2012
DYSPHAGIA AFTER STROKE
PETR KONECNY (1,2,3), MILAN ELFMARK (3,5), STANISLAV HORAK (3), JARMILA SIEGELOVA (2),
PETR DOBSAK (2), TOMAS KADLCIK (4), MARCELA CHARVATOVA (4), JARMILA SKOTAKOVA (4)
Department of Rehabilitation, The Mercifil Brothers’ Hospital in Brno, Department of Physioterapy and Rehabilitation,
­Masaryk University, Brno, Department of Rehabilitation, Palacky University Olomouc, Department of Radiology,
The ­University Hospital Brno, Department of Natural Sciences in Kinanthropology, Palacky University Olomouc
ANNOTATION
Swallowing disorders are often found in patients after stroke.
These problems can be cured using targeted orofacial rehabilitation. This cure can be documented by instruments
measuring changes in swallowing during the following prospective clinical study.
Introduction
Dysphagia, a disorder in swallowing solid or liquid food, occurs very often in bulbar or pseudobulbar syndrome in
patients after stroke in about 40–60 percent of cases (1). Orofacial rehabilitation is very significant in this context,
with an impact not only on the treatment of eating disorders, but also on other orofacial functions (facial expressions,
speech), general health and overall quality of life (2, 3).
Methods
A prospective pilot study evaluating the effect of orofacial rehabilitation (focusing mainly on treatment of hyoid
muscles) in 9 patients after stroke with dysphagia. Evaluation was performed using videofluoroscopy (VFSS) by
measuring the duration of each phase of swallowing (Fig. 1). Measurements were performed at the beginning (before
orofacial rehabilitation) and 8 weeks (after orofacial rehabilitation). The measured values ​​were statistically processed
and evaluated using the Wilcoxon test, with the level of statistical significance of p < 0.050.
Results
Based on the comparison of the time differences (R) in swallowing phases before and after orofacial rehabilitation,
there were found significant differences in the parameters OTT (Oral transport time) R = 0.071 ± 0.027, p = 0.008
(Graph 1.), PTT (Pharyngeal transit time) R = 0.217 ± 0.087, p = 0.008 (Graph 2.), VPL (Velopharyngeal lock)
R = 0.0260 ± 0.0028, p = 0.043 (Graph 3.), RBS (Rastatter Biodynamik Score – time of the maximum elevation of
the hyoid bone) R = 0.089 ± 0.074, p = 0.012 (Graph 4.).
Conclusion
After the 8-week rehabilitation of the hyoid bone muscles during orofacial rehabilitation there ocured improvment
in food swallowing in dysphagic patients after stroke as well as in transport times of individual stages of swallowing
measured using VFSS.  
Based on the obtained results it can be stated that the orofacial rehabilitation is of great importance in the treatment
of swallowing disorders in patients after stroke.
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NONINVASIVE METHODS IN CARDIOLOGY 2012
before after
0,35
0,40
0,45
0,50
0,55
0,60
0,65
0,70
0,75
0,80
0,85
Graph 1. Oral transit time(OTT) before and after orofacial rehabilitation.
before after
0,15
0,20
0,25
0,30
0,35
0,40
0,45
0,50
0,55
0,60
0,65
Graph 2. Pharyngeal transit time (PTT) before and after orofacial rehabilitation.
before after
0,02
0,04
0,06
0,08
0,10
0,12
0,14
0,16
Graph 3. Velopharyngeal lock (VPL) before and after orofacial rehabilitation.
141
NONINVASIVE METHODS IN CARDIOLOGY 2012
before after
0,10
0,12
0,14
0,16
0,18
0,20
0,22
0,24
0,26
0,28
0,30
0,32
0,34
0,36
Graph 4. RBS – rastatter biodynamik score before and after orofacial rehabilitation.
Figure 1. Videofluoroscopy (VFSS)
REFERENCES
1.	 Kalita Z. Acute stroke. Prague: Maxdorf; 2006
2.	 Konecny P, Elfmark M, Urbanek K. Facial paresis after stroke and its impact on patients’ facial movement and
mental status. J Rehabil Med. 2011 Jan; 43(1): 73–5
3.	 Pettersen R, Dahl T, Wyller TB. Prediction of long-term functional outcome after stroke rehabilitation.
Clin ­Rehabil. 2002; 2: 149–159
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NONINVASIVE METHODS IN CARDIOLOGY 2012
AD MULTOS ANNOS SANOS
PROF. MUDR. JARMILA SIEGELOVA, DRSC.
FRANZ  HALBERG, GERMAINE CORNELISSEN AND OTHILD SCHWARTZKOPFF
Halberg Chronobiology Laboratory, University of Minnesota, Minneapolis,
USA for the international project on the Biosphere and the Cosmos, BIOCOS
For a young woman celebrating her 70th
birthday,
with the good wishes of the international community to continue contributing for much longer.
Ten years ago (1), the late prof. MUDr. Bohumil Fiser, CSc., then Czech minister of health and board member
of WHO, and your colleague and friend, not only remembered Jarmilka, but as one who grew up with her scientifically
and shared many aspects of her professional life, he commented on her achievements in great detail.
He emphasized the basic fact that “a week rhythm in circulatory quantities which results from natural regularities
and not from evolution of the society, was documented by her as a 7-day fluctuation of blood pressure
and pulse rate in new-borns at the Teaching Hospital Brno” and that this circaseptan, with an amplitude greater
than the circadian “is synchronized by the moment of birth and is independent of week days.” In addition to
being an independent investigator second to none, as Bohumil recognized, I can attest to his emphasis that she
has been a productive member of an international team, and the first physician-scientist to introduce chronobiologically
interpreted blood pressure monitoring to Europe and thus again, like a fellow Brunensian,
Johann Gregor Mendel, opened a normal range, a diversity in time. While Mendel’s pea patch led to the science of di-
versityinspace,Jarmilkaagainplacedhercityandcountryattheforefrontofbreakthroughssothatnolongeris“physiological”
equated to “random” in the normal range at least for blood pressure, as is still the case with each laboratory
result remaining time-unqualified. Her chronobiologically interpreted blood pressure monitoring serves to discover
newvariabilitydisorders,tostartwithcircadianvascularanomalies.Infradianalterationsofvariabilityanddiagnoses
in other areas than the blood circulation will indubitably follow if, as we hope, her university grants her the opportunity
to continue what she not only started, but developed in a tradition of Brunensian contributions to the circulation
of blood, and in the tradition of doing on herself what she intended for others. When she arrived in Minnesota with
Bohumil and her dear colleague Jiri Dusek, no sooner then were they in town from the airport that they all donned
two instruments and showed on themselves the extent to which results agreed. This attitude was introduced by Jan
Evangelista Purkyne, who studied digitalis on himself. To complete the list that Bohumil started, based on a tetea-tete
with Prof. Cornélissen, the two were instrumental in a design that allowed Jarmilka the demonstration that
aspirin has different effects at different circadian stages, a featin chronotherapy second to none, promptly published
by the American Medical Association. We hope the list continues.
REFERENCE
1.	 Fiser B. Personal report: Prof. MUDr. Jarmila Siegelova, DrSc., a woman celebrating her 60th
birthday. In: Halberg
F, Kenner T, Fiser B, editors. Proceedings, Symposium: The Importance of Chronobiology in Diagnosing
and Therapy of Internal Diseases. Faculty of Medicine, Masaryk University, Brno, Czech Republic, January
10–13, 2002. Brno: Masaryk University; 2002. p. 5–6. [Dedicated to the 60th
Anniversary of Professor Jarmila
Siegelova.]
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NONINVASIVE METHODS IN CARDIOLOGY 2012
Professor Franz  Halberg and Professor Germaine Cornélissen – Videoconference, January 12, 2012
Dr. Othild Schwartzkopff, Prof. Franz  Halberg, Dr. Jiří Dušek, Prof. Thomas Kenner,
Brigitte Kenner, Prof. Jarmila Siegelová – Videoconference, January 12, 2012
144
NONINVASIVE METHODS IN CARDIOLOGY 2012
SUN’S AND EARTH’S MAGNETISM:
FEATURES OF COMMUNICABLE DISEASE ETIOLOGY
FRANZ HALBERG*, SHIYU HONG, LYAZZAT GUMAROVA, GERMAINE CORNÉLISSEN
Halberg Chronobiology Center, University of Minnesota, Minneapolis, MN, USA
KEYWORDS:
diphtheria, helio- and geomagnetism, infectious diseases, space weather, wavelet analysis
Running head: Cycles in communicable disease incidence
INTRODUCTION
The association of human health and disease with space weather was the topic of a long series of presentations at
a recent meeting in Moscow and was also dealt with at earlier conferences (1, 2), with focus on non-communicable
diseases.
METHODS
By meta-analyses of data published by Alexander Leonidovich Chizhevsky in the 20th
century dating back to the span
from 1860 to 1910 (3), we here add evidence (from cross-wavelet coherence) (4) for an association of terrestrial and
solar magnetism with several infectious diseases that were common in the past.
RESULTS
Figure1(top)showsawaveletoftheincidencepatternofdiphtheriaandcroup(pooled)inDenmarkfrom­1860–1910.
An about 12.4-year component is seen to characterize the incidence pattern; it is within the cone of influence. Another
component with a period (t) of about 29.5 years is outside this cone. Both components are validated and are within
the CIs (95% confidence intervals) of the nonlinearly extended cosinor, applied to the same time series on diphtheria
and croup (not shown) and, earlier to many other records on human affairs in health and disease (5).
Wavelets of Wolf numbers, WN (Figure 1, middle), and of the antipodal geomagnetic index aa (Figure 1, bottom)
show maxima corresponding to the anticipated ~11.7-year cycle, also seen from the spectra plotted vertically next
to the color key. The numbers indicate the period length (in years) corresponding to local maxima in amplitudes;
but the color code matters most. The wavelet of aa also reveals the presence of an about 22.1-year component differing
from the smaller about 19.7-year peaklet observed for WN. Both these peaks are less prominent than the about
­29.5-year peak found for diphtheria and croup.
Figure 2 shows cross-wavelet transforms (left) and coherence displays (right) of WN (top) and aa (bottom) with
diphtheria and croup. The 11.7-year t within the cone of influence stands out in association with both WN and aa
in the cross-wavelets. An added large peak at 24.2 years is seen in association with aa. Peaklets are seen at ~23 and
~44 years in association with WN. Strong coherences around 10.4 (WN) or 11.0 (aa) years inside the cone of influence
and additional strong coherences outside this cone around 23.4 (aa) or less intensely around 22.1 (WN) years
are interesting. Added coherences around 5.5 years and at still shorter ts in association with WN are intermittently
145
NONINVASIVE METHODS IN CARDIOLOGY 2012
Figure 1. Wavelet analyses of incidence pattern of two infectious diseases (pooled) centuries ago (top row), of Wolf sunspot numbers
(middle), and of the antipodal geomagnetic index aa (bottom), with peaks indicated by color (key), and by numbers at the maxima
in the spectrum (right, next to the color key) show a putative reflection of past and/or present solar variability. © Halberg.
8
Wavelet Analysis of Diphtheria and Croup Incidence in Denmark (top) with
Wolf Numbers (middle) andAntipodal Geomagnetic Index (aa) (bottom),
1860 - 1910
4
32
16
8
1
1/8 0 20000
8
4
32
16
8
1
1/8 0 10000
Wolf Numbers (WN)
Period(Years)
1
4
32
16
8
0.5
0 0 1
Antipodal Geomagnetic Index (aa)
Period(Years)
12.4
29.5
11.7
19.7
5.2
11.7
22.1
1860 1870 1880 1890 1900 1910
Time (Calendar Years)
Diphtheria and Croup Incidence in DenmarkPeriod(Years)
146
NONINVASIVE METHODS IN CARDIOLOGY 2012
11.7
CrosswaveletTransforms(leftcolumn)&Coherence(rightcolumn)ofDiphtheriaandCroupIncidencein
DenmarkwithWolfNumber(WN)andAntipodalGeomagneticIndex(aa),1860-1910
8
4
32
16
8
1
1/8
100000
WN
Period(Years)
23.4
44.1
1
4
32
16
8
0.5
0
10
5.5
10.4
22.1
WN
Period(Years)
8
4
32
16
8
1
1/8
02000186018701880189019001910
Time(CalendarYears)
186018701880189019001910
Time(CalendarYears)
aa
Period(Years)
11.7
24.8
1
4
32
16
8
0.5
001
3.5
11.0
5
23.4
5
aa
Period(Years)
Figure2.Cross-wavelettransformsshowastrongassociationoftheincidenceoftwoinfectiousdiseases(pooled)withWNandaaataperiod,t,of11.7
yearswithintheconeofinfluence.Coherence(right)isalsofoundwithintheconeofinfluenceat10.4and11.0years.Thesetsarealsonearthosevalidated
fortheincidenceofdiphtheriaandcroupbytheextendednonlinearcosinor(notshown)thatsuggeststhestatisticalsignificanceofdifferencesamong
thetwoaspectsofsolarandearthmagnetism’sassociationwithrampantpandemics,somewithintheconeofinfluence.©Halberg.
147
NONINVASIVE METHODS IN CARDIOLOGY 2012
statistically significant (as seen from black contours). Again, there is a difference in spectral location between WN
and aa, the overall peak occurring around 3.5 years for aa.
COMMENT
Among para-annual components, solar wind speed, a measure of interplanetary magnetism, and aa share some
frequencies but differ at others (6). Here we find that, in the decadal range, both WN and aa, gauging solar and terrestrial
magnetism, respectively, shared coherence (within the cone of influence) with the main cycle characterizing
communicable diseases, such as diphtheria and croup, in the past when they were pandemic. Just as helio-, interplanetary
or geomagnetism can influence sudden cardiac death (6), they also influenced communicable diseases,
probably via the host, whose steroidal defense shows a proven decadal cycle (6) and by the invading microorganism,
whose mutations can also undergo a similar cycle mirroring that of sunspots (6). Cycles in the sun’s and the earth’s
magnetism are features of both communicable and noncommunicable disease etiology and, in both cases, are geographically,
selectively assorted, shown elsewhere (6).
Support: GM-13981 (FH), University of Minnesota Supercomputing Institute (GC, FH).
REFERENCES
1.	 Proceedings, Space Weather Effects on Humans in Space and on Earth, Moscow, 4–8 June 2012. Moscow:
Space Research Institute RAS; 2012. 176 pp
2.	 Otsuka K. (Ed.) Proceedings, 1st
–5th
International Symposium Workshops on Circadian Rhythms and Clinical
Chronotherapy, 11 Nov 2000, 17 Nov 2001, 9 Nov 2002, 8 Nov 2003, 6 Nov 2004, Tokyo, Japan. Biomed &
Pharmacother: 2001; 55 (Suppl 1): 7s–190s; 2002; 56 (Suppl 2): 231s–382s; 2003; 57 (Suppl 1): 1s–198s; 2004;
58 (Suppl 1): S1–S188; 2005; 59 (Suppl 1): S1–S261; Mikulecky M. (Ed.) The Moon and Living Matter. Kosice,
Slovakia, September 23–25, 1993. Bratislava: Slovak Medical Society; 1993. 97 pp; Sun, Moon and Living Matter.
Bratislava, Slovakia, June 28 – July 1, 1994. Bratislava: Slovak Medical Society; 1994. 159 pp; Chronobiology
& Its Roots in the Cosmos. High Tatras, Slovakia, September 2–6, 1997. Bratislava: Slovak Medical Society;
1997. 287 pp
3.	 Chizhevsky AL. The terrestrial echo of solar storms. Moscow: “Mysl”; 1976. 349 pp
4.	 Grinsted A, Moore JC, Jevrejeva S. Application of the cross wavelet transform and wavelet coherence to geophysical
time series. Nonlinear Processes in Geophysics 2004; 11: 561–566
5.	 Halberg F, Cornélissen G, Sothern RB, Czaplicki J, Schwartzkopff O. Thirty-five-year climatic cycle in heliogeophysics,
psychophysiology, military politics, and economics. Izvestiya, Atmospheric and Oceanic Physics 2010;
46 (7): 844–864. (Back-translation from Geophysical Processes and Biosphere 2009; 8 [2]: 13–42.)
6.	 Halberg F, Cornélissen G, Gumarova L, Halberg Francine, Ulmer W, Hillman D, Siegelova J, Watanabe Y,
Hong S, Otsuka K, Wu J, Lee JY, Schwartzkopff O, Wendt H. Integrated and as-one-goes analyzed physical,
biospheric and noetic monitoring: Preventing personal disasters by self-surveillance may help understand natural
cataclysms: a chronousphere (chrono-noösphere). IC GEOCHANGE, 106 pp, in press
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CELEBRATION OF A LIFETIME’S ACHIEVEMENTS
IN CARDIOVASCULAR CHRONOMICS. A TRIBUTE TO FRANZ
HALBERG ON THE OCCASION OF HIS 93RD
BIRTHDAY
GERMAINE CORNELISSEN
Halberg Chronobiology Center University of Minnesota, USA
DEDICATION
By adding TIME to the existing body of knowledge in all of biology and medicine, and by recognizing the crucial role
this new element was to play in all matters of life, Franz Halberg developed the new science of chronobiology. By
insisting on an inferential statistical foundation, a microscopy in time was born. By adding a telescopy in time with a
methodical scrutiny of non-photic as well as photic environmental influences on biota, chronomics flourished.
Born on July 5, 1919 in Romania, Franz studied the adrenal as a university assistant in post-World War II Innsbruck,
Austria. He did so at Harvard Medical School, where he held a World Health Organization fellowship in clinical
endocrinology in 1948. In 1949, he moved to the University of Minnesota, which saw his breakthrough experiments
that led to the important discovery that circadian rhythms are partly endogenous and can be manipulated by environmental
synchronizers, notably the lighting and feeding schedules. His results were published in 1969 in a citation
classic (1). By 1958, Franz had recognized the important role played by the cell’s RNA and DNA cycles, which he
was first to demonstrate as complementing the hypothalamic-pituitary-adrenal system as mediator of photic inputs.
His work earned him numerous awards. Apart from holding professorships in Laboratory Medicine and Pathology,
Physiology, Biology, Bioengineering and Oral Medicine at the University of Minnesota, he received honorary doctorates
from the University of Montpellier (France), Ferrara (Italy), Tyumen (Siberia), Brno (Czech Republic), L’Aquila
(Italy), and most recently People’s Friendship University of Russia (Moscow, Russia). At over 93 years of age and still
active 7 days a week in the Center named after him at the University of Minnesota, he is one of the last recipients of
a lifetime career award from the National Institutes of Health. His achievements in the new field of chronomics also
earned him the O.Yu. Schmidt Medal and diploma for outstanding merits in development of geophysics, the first
such award given to a non-physicist.
In over 3,400 published titles in cooperation with colleagues from all five continents, major accomplishemts of Franz
include the following highlights. First, rhythms are not trivial as they can tip the scale between health and disease and
even between life and death. Second, after suggesting the hypothalamus mediated light information, Franz fought
from the start the idea that the suprachiasmatic nuclei were “the” master clock. After a debate that lasted more than
a decade, Franz’s view has been vindicated now that modern molecular biological techniques have shown the presence
of oscillators in practically every cell, in the brain as well as in the periphery. Third, as the crowning of a distinguished
career, Franz’s early vision that rhythms were not trivial but rather constituted the founding block of life
itself is being unveiled by findings that alterations in clock genes are not only responsible for alterations in circadian
rhythms but are fundamentally involved in a host of diseased conditions from addiction and cancer to cardiovascular
disease. Last but not least, his mapping of a much broader time structure includes cycles with frequencies covering
10 orders of magnitude, aligned between biology and physics by means of an armamentarium of analytical procedures,
including a remove-and-replace approach extended from endocrinology to a true transdisciplinary endeavor.
Franz’s most recent work addresses wide-ranging applications from the optimization of individualized health care
to concerns for the health of societies. Toward this goal, the automatic monitoring of vital signs, as a start of blood
pressure and heart rate, serves the multiple purposes of enlarging the scope of Humboldt’s purely physical monitoring
into an endeavor advancing both the biomedical field and physics in a truly unified science and leading to a noo-
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sphere that is organized by a novel spectrum of congruent cycles in us and around us, photic cycles and non-photic
(unseen) ones, some of the latter already mapped transdisciplinarily.
ABSTRACT
Cardiovascular disease is one of the leading causes of death. An elevated blood pressure is widely recognized as a factor
associated with an increased cardiovascular disease risk. Several outcome studies based on automatic aroundthe-clock
monitoring of blood pressure and heart rate have shown that alterations of the variability in these variables,
notably those related to their circadian pattern also increase risk, even more so than a high blood pressure itself. Vascular
Variability Anomalies (VVAs), and when they persist, Vascular Variability Disorders (VVDs) are introduced,
as are methods to detect them and to determine optimal treatment times.
INTRODUCTION
In 1733, blood pressure was first directly measured in an artery by the English naturalist, the Reverend Stephen
Hales (2). An Austrian physician, von Basch (1876), then developed a convenient and simple way of measuring blood
pressure by connecting a small balloon to either a mercury column or sometimes an aneroid manometer. The balloon
was placed over the artery in the wrist and compressed until the pulsation of the artery in the wrist below the
balloon was obliterated. The pressure at which the pulsation disappeared gave a reasonably accurate measurement
of systolic pressure. He soon realized that the higher the systolic blood pressure, the greater the risk of stroke and
kidney disease (2). The term “sphygmomanometer” comes from the Greek “sphygmós” (pulse) and the scientific
word “manometer” (pressure meter). The device was invented by Samuel Siegfried Karl Ritter von Basch in 1881 (3),
extensively tested by Ignaz Zadek (4, 5). By 1881, data from Zadek were available to assess periodicities of about 24,
84 and 168 hours (6), Figure 1.
Figure 1. Original data collected by Ignaz Zadek on one of his patients. A composite model consisting of cosine curves with periods
of 24 and 84 hours fitted to the data is also shown (left). All three components with periods of 24, 84, and 168 hours are statistically
significant by population-mean cosinor, the small number of subjects (4) notwithstanding (right). © Halberg (with permission).
In 1904, Theodore C Janeway of Johns Hopkins University (Baltimore), the opinion leader of his time, wrote “… it is
essential that a record of the pressure be made at frequent intervals at some time previous [presumably to an examination],
to establish the normal level and the extent of the periodic variations. When this is done, it may be possible to
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demonstrate changes of small extent, which, lacking this standard, for comparison, would be considered within the
limits of normal variation.” (7). By 1974, Frederic C Bartter wrote “By conventional standards, this patient is clearly
normotensive every morning. Yet the blood pressure determined each day at 6 in the afternoon provides especially
convincing evidence that this patient is a hypertensive. ... My plea today is that information contained in such curves
[cosinor fits] become a routine minimal amount of information accepted for the description of a patient’s blood pressure.
The analysis of this information by cosinor should become a routine. It is essential that enough information be
collected to allow objective characterization of a periodic phenomenon, to wit, an estimate of M [the time structure or
chronome-adjusted mean, or MESOR] … an estimate of [the amplitude] A itself, and finally an estimate of acrophase,
φ [a measure of timing]. In this way, a patient can be compared with himself at another time, or under another treatment,
and the patient can be compared with a normal or with another patient.” (8). As seen from Figure 2, the largeamplitude
circadian variation in blood pressure readily accounts for the diverging diagnoses made by the two physicians
who saw the same patient at different times of the day, as also illustrated in the abstract (Figure 2, bottom).
Figure 2. Original data from FC Bartter on his patient who was diagnosed as normotensive by the physician who examined
him in the morning and as hypertensive by the physician who saw him in the afternoon. Data collected around the clock when
he was hospitalized at the US National Institutes of Health readily account for the discrepant diagnoses in view of the largeamplitude
circadian variation in his blood pressure. The circadian-stage dependence of the diagnosis of high blood pressure
is illustrated in the abstract (bottom right) when it is based on single casual measurements during office hours interpreted by
fixed limits. Indeed, the circadian rhythm in blood pressure can, in itself, even in the absence of measurement error, result in
contradictory diagnoses. Computations are based on a 24-hour cosine curve with an amplitude of 20 mmHg (slightly above the
upper 95% prediction limit in clinically healthy adults) and an acrophase of −240 ° (4 PM). © Halberg (with permission).
Blood pressure first became easy to measure in 1896 when an Italian physician, Riva Rocci, developed what we
would now recognize as a conventional mercury sphygmomanometer with a cuff around the arm, which was inflated
until the pulsation of the artery could no longer be felt. A few years later, Nicolai Korotkoff, a Russian army surgeon
(1904), realized that by listening with a stethoscope below the cuff over the artery at the elbow, characteristic sounds
were heard at the systolic pressure, but also at the lower pressure (diastolic) when the heart relaxes. It became very
easy to measure both systolic and diastolic pressure accurately with a stethoscope (2).
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CONTRIBUTIONS BY FRANZ HALBERG VIEWED FROM A HISTORICAL
PERSPECTIVE
Using a mercury sphygmomanometer, Franz directed several studies on school children in Minnesota (9, 10), Connecticut
(11) and Arkansas (12), complemented later by investigations elsewhere in the USA (13, 14). He convinced
colleagues abroad to conduct similar studies, notably in Italy (15) and Portugal (16). These investigations provided
the first hint of the importance to assess the circadian amplitude of blood pressure to gauge cardiovascular disease
risk. They all corroborate results observed in the experimental laboratory on the stroke-prone Okamoto rat, where
the 24-hour amplitude increased before the average did (17).
Under the leadership of Franz Halberg, a large Minnesota-Kyushu study (18) took place in which blood pressure was
measured automatically around-the-clock with an analog device, the arteriosonde. Dots on a moving paper had to be
converted from position to mmHg and date/time. Frequent calibrations were required to assure the accuracy of both
time and blood pressure readings. Nevertheless, important information could be collected non-invasively on human
subjects during both sleep and wakefulness, and circadian rhythm parameters could be associated with cardiovascular
disease risk and hormonal determinations obtained around-the-clock concomitantly. The MESOR of diastolic
blood pressure and cardiovascular disease risk assessed by questionnaire were both found to correlate negatively
with the circannual amplitude of aldosterone, Figure 3 (18). The data also served to build the first individualized
time-specified reference values (chronodesms), Figure 4.
Figure 3. Negative correlation of the circannual amplitude of circulating aldosterone versus the circadian MESOR
of diastolic blood pressure of clinically healthy women at different risks of developing breast cancer (left) and
versus their cardiovascular disease risk assessed by questionnaire (right) (18).© Halberg (with permission).
A fully automatic portable if not quite yet ambulatory blood pressure became available in the 1980s, developed by
Masayuki Shinoda in Komaki, Japan. Franz and his wife Erna used it extensively and were first to obtain longitudinal
records of around-the-clock measurements over several weeks. The data thus collected led to important new findings.
First, an increase in blood pressure around mid-sleep was documented and validated in inferential statistical
terms (19), followed by a steeper increase after awakening, Figure 5. Second, the circadian rhythm in blood pressure
was shown to persist during bedrest (20), in keeping with an earlier study by Reinberg et al. (21). Third, the data
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served to outline some important sampling requirements. The need to monitor for more than a single 24-hour span
became obvious from the large gain in accuracy of the estimation of circadian characteristics when prolonging the
record length from 24 to 48 hours (22).
Figure 4. Individualized chronodesm (time-specified reference values) for diastolic blood pressure. Reference standars were
established on the basis of data collected in 1976. Only few values obtained in 1980 are outside the limits, indicating that
the diastolic blood pressure of this subject did not change markedly within these 4 years. © Halberg (with permission).
Figure 5. Small but statistically significant increase in blood pressure around mid-sleep (dashed vertical line)
before the larger per-awakening increase (solid vertical line) in a clinically healthy woman. Result on all data (left)
is validated when data set is split into two halves (middle and right) (19). © Halberg (with permission).
A similar model of an automatic portable device also became available for neonatal monitoring. A larger circadian
amplitude of blood pressure in babies with a positive than in those with a negative family history of high blood pressure
and/or related cardiovascular disease was in keeping with results from self-measurements in school children
(23). As further neonatal data accumulated, the result had to be qualified, the failure to detect a difference in data
collected a few years later (24) eventually accounted for by the modulation of circadian neonatal blood pressure
characteristics by an about 11-year cycle similar to variations seen in solar activity (25). Neonatal blood pressure
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monitoring in Italy, where the late Brunetto Tarquini cooperated with Franz, led to the discovery of a prominent
about-weekly variation overshadowing the circadian variation at birth. The finding, originally made on the basis of
transverse data, Figure 6 (26) was later confirmed on longer individual records (27). Circaseptans in neonatal blood
pressure were found to be influenced by geomagnetics in cooperation with Elena V Syutkina (28), whereas in Brno,
Jarmila Siegelova provided evidence for a partly built-in week (29), supported by data collected in the intensive care
unit both in the Czech Republic (30) and in Minnesota (31), Figure 7.
Figure 6. About-weekly variation in neonatal systolic blood pressure, first assessed on the basis of hybrid data, each baby
being monitored for about 2 days but starting at different times after birth (26). © Halberg (with permission).
As different kinds of ambulatory devices became available, records could be obtained from clinically healthy people
of all ages. Franz was instrumental in furthering the methodology needed to determine reference values in health
that are time-specified to account for the circadian variation, while also recognizing the desirability to qualify the
reference standards by gender, age and ethnicity. New, more relevant questions could be addressed, such as whether
circadian rhythm characteristics were within or outside acceptable limits, and whether a profile over time was deviating
from time-specified norms. If so, the extent and timing of excess were found to constitute valuable information
for guiding the timing of anti-hypertensive medication, information obtained by chronobiologically-interpreted
ABPM and summarized in a computer-generated form, the sphygmochron (32–35).
VASCULAR VARIABILITY ANOMALIES (VVAS), DISORDERS (VVDS) AND
SYNDROMES (VVSS)
One important lesson learned from longitudinal records of around-the-clock measurements of blood pressure and
heart rate is the large day-to-day variability in circadian characteristics found for a large majority of people. The
presence of about-weekly changes in blood pressure and their relevance to mental health (36) led to the requirement
of monitoring for at least one week and to repeat the monitoring when abnormality is detected (35). This precaution
is taken to reduce the number of false positives and false negatives, so that only those patients in need of medication
receive it at the most opportune time. Indeed, transient abnormality during a day or two may often occur and has
been related to strain (37, 38).
As noted above, abnormality of circadian characteristics can occur within the physiological range. Hence, an elevated
blood pressure (MESOR-hypertension) is only one of several different kinds of VVAs. It is detected when
the patient’s blood pressure MESOR is above the upper 95% prediction limit for clinically healthy peers matched by
gender and age. Today’s treatment is focused primarily on lowering an excessive blood pressure MESOR, without
any consideration of the circadian amplitude or acrophase. Outcome studies (39–43) have shown, however, that
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an excessive circadian amplitude of blood pressure (CHAT, brief for Circadian Hyper-Amplitude-Tension) is also associated
with an increased cardiovascular disease risk, even in MESOR-normotension. It is thus important to make
sure that medication taken to lower the blood pressure MESOR does not do so by bringing about CHAT, since this
would amount to trade one risk factor for another, perhaps an even worse one. In a clinical trial on the chronotherapy
of Hyzaar (44), the same dose of the same medication given to the same patient was shown to either exacerbate
CHAT or to eliminate it, depending solely on the circadian stage of its administration (45), Figure 8. Decreasing an
Figure 7. Documentation of the heritability of the circaseptan component by intra-class correlation coefficient,
comparing the intra- versus the inter-twin pair variability in the nonlinearly assessed circaseptan period, for
data on diastolic blood pressure (top), heart rate (middle), and body weight (bottom), recorded in the neonatal
intensive care unit of the University of Minnesota. For these three variables, the circaseptan period was more
similar between the twins in a pair than among twin pairs (31). © Halberg (with permission).
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excessive circadian amplitude of blood pressure has been shown indirectly to reduce adverse outcomes (46). An odd
acrophase of blood pressure but not of heart rate has also been associated with an increased cardiovascular disease
risk, using the left ventricular mass index as a proxy outcome measure (43), Figure 9. This VVA is known as blood
pressure ecphasia.
Figure 8. In this chronotherapy trial, patients automatically measured their systolic and diastolic blood pressure and heart
rate around-the-clock at 30-minute intervals for 7 days, first without Hyzaar and thereafter after at least one month on
Hyzaar administered at a given circadian stage, at awakening and 3, 6, 9, 12 and 15 hours after awakening, with monitoring
during the last week on a given timed treatment. In the case of this patient (Su, M, 67y), the presence of CHAT in the
absence of treatment is exacerbated when Hyzaar is taken 6 hours after awakening, but it is alleviated when the same dose
of Hyzaar is taken in the evening, 12 hours after awakening (45). Data from Y Watanabe. © Halberg (with permission).
Whereas the relation to cardiovascular disease risk is mostly linear for the MESOR, it is strongly nonlinear in the
case of the circadian amplitude of blood pressure, as it is for pulse pressure and the standard deviation of heart rate
(47). Values above 60 mmHg for pulse pressure and below 7.5 beats/min for the standard deviation of heart rate have
been associated with an increased cardiovascular disease risk. An excessive pulse pressure and a deficient heart rate
variability are two other VVAs. Ecfrequentia is another VVA, seldom diagnosed but consistently found in an extensively
studied case of recurring adynamia (48).
The urgent need to diagnose VVDs, ascertaining that they are not transient VVAs, stems from results of outcome
studies showing the drastic increase in cardiovascular risk when one or several VVDs are present and complicate
MESOR-hypertension, Figure 10 (35, 45). Uncomplicated MESOR-hypertension was associated with less a morbid
event within 6 years in less than 10 % of the patients. With each additional VVD complicating MESOR-hypertension,
the percentage of patients suffering an adverse event increased dramatically, reaching 100 % when all VVDs tested
in the study were present concomitantly.
CONCLUDING REMARKS
Just like splitting the atom released much energy, entering the normal range to resolve lawful variability yields valuable
new information. This can be achieved by physiologic monitoring, collecting data around the clock for a week or
longer and by analyzing the data chronobiologically, interpreting the results in the light of time-specified reference
values qualified by gender and age.
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Figure 9. Left Ventricular Mass Index (LVMI), used as a surrogate outcome measure, available from all 1179
untreated participants in this study, is compared among patients classified in terms of circadian characteristics
assessed by cosinor. Results are comparison by 1-way ANOVA overall (All) and separately for women (F) and men
(M). LVMI values are greatly elevated when diastolic ecphasia or CHAT is diagnosed (corresponding to abnormal
circadian patterns of diastolic blood pressure). Data from CH Chen. © Halberg (with permission).
Figure 10. Results from an outcome study in a clinic population of 297 patients (39, 40). Blood pressure and heart rate of each
subject were monitored around the clock for 2 days at 15-minute intervals at the start of study. Each record was analyzed
chronobiologically and results interpreted in the light of time-specified reference limits qualified by gender and age. On this
basis, the following VVAs were diagnosed: MESOR-hypertension, excessive pulse pressure (EPP), CHAT, and deficient heart
rate variability (DHRV) and their incidence related to outcomes (cerebral ischemic attack, coronary artery disease, nephropathy,
and/or retinopathy). Outcomes, absent at the start of study in these non-diabetic patients, were checked every 6 months for
6 years, to estimate the relative risk associated with each VVA alone or in combination with 1, 2, or 3 additional VVAs. Among the
176 patients with MESOR-hypertension, 103 (34.7 % of the whole study population of 297 patients) had no other VVA, 55 (18.5 %)
had one additional VVA (EPP, CHAT, or DHRV), 15 (5.1%) and 3 (1.0%) had two or three additional VVAs. In the latter group,
all 3 patients had a morbid outcome within 6 years of the monitoring. Data from K Otsuka. © Halberg (with permission).
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The fact that not all drugs have a similar effect on the circadian characteristics of blood pressure, and that the same
dose of the same drug can have different effects on the same patient as a function of when (at what circadian stage
in relation to awakening) it is administered, the optimal time differing from patient to patient, it is important to individualize
chronotherapy. To that effect, N-of-1 studies (49) are essential, as are statistical procedures applicable
to the individual patient, such as parameter tests (50) and cumulative control charts (CUSUM) (51). Part of the individualization
of treatment and treatment timing is directly linked to the chronodiagnosis, that is the kind of VVD
detected for a given patient. Intuitively, a patient with most blood pressure excess by night should not be treated the
same way as a patient with most blood pressure excess by day, even when their 24-hour average value is similar. This
combination of chronotherapy and chronodiagnosis has been referred to as chronotheranostics (52).
A major argument often put forward against this vision of Franz Halberg relates to cost. The status quo indeed has
the monitoring performed under the physician’s care. This needs not be the case, however. The patient with diabetes
is taught how to measure blood glucose and to adjust the dose of insulin accordingly. Blood pressure monitoring is
much easier and it is not invasive. As discussed in an extensive consensus document under Franz’s direction (35),
monitoring could become part of self-help in healthcare. Physicians can be spared much of the routine monitoring
that can be relegated to the patients themselves until a VVD is detected and confirmed. He has visualized the development
of a website to render this possible.
Figure 11. Wobbliness of the transyear component (with a period of about 1.3 years) is observed for both solar wind speed (top) and
the systolic blood pressure of an elderly man (bottom) in gliding spectra computed with an interval of 8 years displaced by 1-month
increments in the frequency range of one cycle in 2.5 years to 2.5 cycles per year with a 0.05 harmonic increment. Results suggest
that the transyear may be partly built-in while also being influenced by space weather (53). © Halberg (with permission).
An enormous dividend can also be reaped from the physiological monitoring, also included in the website visualized
by Franz. It consists of the rigorous study of environmental influences from near and far. Coperiodisms, that is
shared frequencies, have already been documented and are part of an emerging atlas. Examples include the partly
resonant, partly inherited transyear (about 1.3-year cycle) of his own systolic blood pressure in relation to the solar
wind (Figure 11) and the possible use of systolic blood pressure to assess congruence between space weather and
human physiology (Figure 12), mental functions showing an even greater association than two physical variables,
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solar wind speed and the antipodal index of geomagnetic disturbance aa, known to have similar time structures in
the frequency window investigated (53, 54).
Support: GM-13981 (FH), University of Minnesota Supercomputing Institute (GC, FH).
Figure 12. Human mental functions (vigor, mood and 1-minute time estimation) are as closely associated with our cosmos as
is the well-known association of the sun’s and the earth’s magnetism (extreme lower right). Systolic blood pressure monitoring
for preventive health maintenance provides data that, as a dividend, may serve to monitor the cosmos and its influence on societal
diseases by testing the likelihood that congruence (correspondence of common cycles in and around us) is due to chance. Anticipated
influence of the antipodal index of geomagnetic disturbance aa (top) and of the non-photic environment (gauged by solar wind speed,
an approximation of interplanetary magnetism) on human psychophysiology was assessed by means of the congruence of periods of
their spectral components (defined by overlap of the 95% confidence intervals of the periods, in the frequency range of one cycle in
2.5 years to 3 cycles per year). The biological data stem from 40 years of self-measurements of oral temperature (Temp), systolic
blood pressure (SBP), diastolic blood pressure (DBP) and heart rate (HR) and of ratings of mood and vigor and the estimation of
1-minute by counting (1MTE), performed about 5 times a day by a clinically healthy man (RBS). Congruences (assessed by means of
odds ratios based on the noncentral hypergeometric distribution) found for 1MTE and for several other variables more than equal
that of the known association of helio- and geo-magnetism (bottom, last column on right of dashed vertical line). Mental functions
show higher congruence than somatic functions. Among the latter, systolic blood pressure is responsive, perhaps constituting
a seemingly acceptable proxy for the mental functions. P-values are based on the non-central Fisher hypergeometric distribution,
with 95% confidence intervals computed using Fisher’s exact test, used since the null hypothesis was rejected in some, yet not all
cases (53, 54). © Halberg (with permission).
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Halberg E, Halberg F. The Florence Children’s Blood Pressure Study. A chronobiologic approach by multiple
self-measurements. Clin Exper Hypertension: Theory and Practice 1985; A7: 355–359
16.	Johns KL, Halberg F, Cornelissen G, März W. Chronobiology at the American International School in Lisbon,
Portugal. In: Halberg F, Reale L, Tarquini B, editors. Proc. 2nd
Int. Conf. Medico-Social Aspects of Chronobiology,
Florence, Oct. 2, 1984. Rome: Istituto Italiano di Medicina Sociale, 1986: 367–384
17.	 Halberg J, Halberg E, Hayes DK, Smith RD, Halberg F, Delea CS, Danielson RS, Bartter FC. Schedule shifts,
life quality and quantity modeled by murine blood pressure elevation and arthropod lifespan. Int J Chronobiol
1980; 7: 17–64
18.	Halberg F, Cornelissen G, Sothern RB, Wallach LA, Halberg E, Ahlgren A, Kuzel M, Radke A, Barbosa J,
Goetz F, Buckley J, Mandel J, Schuman L, Haus E, Lakatua D, Sackett L, Berg H, Wendt HW, Kawasaki T,
Ueno M, Uezono K, Matsuoka M, Omae T, Tarquini B, Cagnoni M, Garcia Sainz M, Perez Vega E, Wilson D,
Griffiths K, Donati L, Tatti P, Vasta M, Locatelli I, Camagna A, Lauro R, Tritsch G, Wetterberg L. International
geographic studies of oncological interest on chronobiological variables. In: Kaiser H. (Ed.) Neoplasms—Comparative
Pathology of Growth in Animals, Plants and Man. Baltimore: Williams and Wilkins; 1981. p. 553–596
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19.	 Halberg E, Halberg F, Shankaraiah K. Plexo-serial linear-nonlinear rhythmometry of blood pressure, pulse and
motor activity by a couple in their sixties. Chronobiologia 1981; 8: 351–366
20.	Stadick A, Bryans R, Halberg E, Halberg F. Circadian cardiovascular rhythms during recumbency. In: Tarquini
B. (Ed.) Social Diseases and Chronobiology: Proc. III Int. Symp. Social Diseases and Chronobiology, Florence,
Nov. 29, 1986. Bologna: Società Editrice Esculapio; 1987. p. 191–200
21.	 Reinberg A, Ghata J, Halberg F, Gervais P, Abulker C, Dupont J, Gaudeau C. Rythmes circadiens du pouls, de
la pression artérielle, des excrétions urinaires en 17-hydroxycorticostéroïdes, catécholamines et potassium chez
l’homme adulte sain, actif et au repos. Ann Endocrinol (Paris) 1970; 31: 277–287
22.	Halberg F, Scheving LE, Lucas E, Cornelissen G, Sothern RB, Halberg E, Halberg J, Halberg Francine, Carter
J, Straub KD, Redmond DP. Chronobiology of human blood pressure in the light of static (room-restricted)
automatic monitoring. Chronobiologia 1984; 11: 217–247
23.	Halberg F, Cornelissen G, Bingham C, Tarquini B, Mainardi G, Cagnoni M, Panero C, Scarpelli P, Romano S,
März W, Hellbrügge T, Shinoda M, Kawabata Y. Neonatal monitoring to assess risk for hypertension. Postgrad
Med 1986; 79: 44–46
24.	Halberg F, Cornelissen G, Bakken E. Caregiving merged with chronobiologic outcome assessment, research
and education in health maintenance organizations (HMOs). Progress in Clinical and Biological Research
1990; 341B: 491–549
25.	Syutkina EV, Cornelissen G, Mitish M, Narogan MV, Surgyk AV, Krylova OS, Masalov A, Schwartzkopff O,
Halberg F. he neonate, a particularly sensitive magnetoreceptor? Population rhythms reveal cycles. In: Proceedings,
Natural Cataclysms and Global Problems of the Modern Civilization, Istanbul, 19–21 September 2011.
London: SWB International Publishing House; 2012. Pp. 254–259
26.	Cornelissen G, Halberg F, Tarquini B, Mainardi G, Panero C, Cariddi A, Sorice V, Cagnoni M. Blood pressure
rhythmometry during the first week of human life. In: Tarquini B. (Ed.) Social Diseases and Chronobiology:
Proc. III Int. Symp. Social Diseases and Chronobiology, Florence, Nov. 29, 1986. Bologna: Società Editrice
Esculapio; 1987. p. 113–122
27.	Watanabe Y, Nintcheu-Fata S, Katinas G, Cornelissen G, Otsuka K, Hellbrügge T, Schwartzkopff O, Bakken E,
Halberg F. Methodology: partial moving spectra of postnatal heart rate chronome. Neuroendocrinol Lett 2003;
24 (Suppl 1): 139–144
28.	Syutkina EV, Cornelissen G, Grigoriev AE, Mitish MD, Turti T, Yatsyk GV, Pimenov K, Breus TK, Studenikin
MY, Siegelova J, Fiser B, Dusek J, Johnson D, Halberg F. Neonatal intensive care may consider associations of
cardiovascular rhythms with local magnetic disturbance. Scripta medica (Brno) 1997; 70: 217–226
29.	Siegelova J, Cornelissen G, Schwartzkopff O, Halberg F. Time structures in the development of children. Neuroendocrinol
Lett 2003; 24 (Suppl 1): 126–131
30.	Cornelissen G, Siegelova J, Halberg F. Blood pressure and heart rate dynamics during pregnancy and early
extra-uterine life: Methodology for a chrononeonatology. In: Halberg F, Kenner T, Fiser B. (Eds.) Proceedings,
Symposium: The Importance of Chronobiology in Diagnosing and Therapy of Internal Diseases. Faculty of
Medicine, Masaryk University, Brno, Czech Republic, January 10–13, 2002. Brno: Masaryk University; 2002.
p. 58–96
31.	 Cornelissen G, Engebretson M, Johnson D, Otsuka K, Burioka N, Posch J, Halberg F. The week, inherited in
neonatal human twins, found also in geomagnetic pulsations in isolated Antarctica. Biomed & Pharmacother
2001; 55 (Suppl 1): 32s–50s
32.	Carandente F, Halberg F. Chronobiology of blood pressure in 1985. Chronobiologia 1984; 11, 343 pp
33.	 Cornelissen G, Otsuka K, Halberg F. Blood pressure and heart rate chronome mapping: a complement to the human
genome initiative. In: Otsuka K, Cornélissen G, Halberg F. (Eds.) Chronocardiology and Chronomedicine:
Humans in Time and Cosmos. Tokyo: Life Science Publishing; 1993. p. 16–48
34.	Cornelissen G, Halberg F, Bakken EE, Singh RB, Otsuka K, Tomlinson B, Delcourt A, Toussaint G, Bathina
S, Schwartzkopff O, Wang ZR, Tarquini R, Perfetto F, Pantaleoni GC, Jozsa R, Delmore PA, Nolley E. 100 or
30 years after Janeway or Bartter, Healthwatch helps avoid “flying blind”. Biomed & Pharmacother 2004; 58
(Suppl 1): S69–S86
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35.	 Halberg F, Cornelissen G, Otsuka K, Siegelova J, Fiser B, Dusek J, Homolka P, Sanchez de la Pena S, Singh RB,
BIOCOS project. Extended consensus on means and need to detect vascular variability disorders (VVDs) and
vascular variability syndromes (VVSs). Leibniz-Online Nr. 5, 2009 (http://www2.hu-berlin.de/leibniz-sozie-
taet/journal/archiv_5_09.html)
36.	Yamanaka G, Otsuka K, Hotta N, Murakami S, Kubo Y, Matsuoka O, Takasugi E, Yamanaka T, Shinagawa M,
Nunoda S, Nishimura Y, Shibata K, Saitoh H, Nishinaga M, Ishine M, Wada T, Okumiya K, Matsubayashi K,
Yano S, Ishizuka S, Ichihara K, Cornelissen G, Halberg F. Depressive mood is independently related to stroke
and cardiovascular events in a community. Biomed & Pharmacother 2005; 59 (Suppl 1): S31–S39
37.	 Halberg F, Cornelissen G, Otsuka K, Katinas GS, Schwartzkopff O, Halpin C, Mikulecky M, Revilla M, Siegelova
J, Homolka P, Dusek J, Fiser B, Singh RB. Chronomics detects altered vascular variabilities constituting
risks greater than hypertension: with an illustrative case report. In: Mitro P, Pella D, Rybar R, Valocik G.
(Eds.) Proceedings, 2nd
Congress on Cardiovascular Diseases, Kosice, Slovakia, 25–27 April 2002. Bologna:
­Monduzzi Editore; 2002. p. 223–258
38.	Halberg F, Cornelissen F, Halberg Francine, Kessler T, Otsuka K. Measuring mental strain by duration of blood
pressure overswing (CHAT): case report. World Heart J 2010; 2 (2): 141–167
39.	 Otsuka K, Cornelissen G, Halberg F. Predictive value of blood pressure dipping and swinging with regard to
vascular disease risk. Clinical Drug Investigation 1996; 11: 20–31
40.	Otsuka K, Cornelissen G, Halberg F, Oehlert G. Excessive circadian amplitude of blood pressure increases risk
of ischemic stroke and nephropathy. J Medical Engineering & Technology 1997; 21: 23–30
41.	 Halberg F, Cornelissen G, International Womb-to-Tomb Chronome Initiative Group: Resolution from a meeting
of the International Society for Research on Civilization Diseases and the Environment (New SIRMCE Confederation),
Brussels, Belgium, March 17–18, 1995: Fairy tale or reality? Medtronic Chronobiology Seminar #8,
April 1995, 12 pp. text, 18 figures. http://www.msi.umn.edu/~halberg/
42.	Cornelissen G, Halberg F, Otsuka K, Singh RB. Separate cardiovascular disease risks: circadian hyper-amplitude-tension
(CHAT) and an elevated pulse pressure. World Heart J 2008; 1 (3): 223–232
43.	 Cornelissen G, Halberg F, Otsuka K, Singh RB, Chen CH. Chronobiology predicts actual and proxy outcomes
when dipping fails. Hypertension 2007; 49: 237–239. doi:10.1161/01.HYP.0000250392.51418.64
44.	Watanabe Y, Cornelissen G, Halberg F, Beaty L, Siegelova J, Otsuka K, Bakken EE. Harm vs. benefit from
losartan with hydrochlorothiazide at different circadian times in MESOR-hypertension or CHAT. In: Halberg F,
Kenner T, Fiser B, Siegelova J. (Eds.) Proceedings, Noninvasive Methods in Cardiology, Brno, Czech Republic,
October 4–7, 2008. p. 149–167
45.	 Halberg F, Cornelissen G, Wilson D, Singh RB, De Meester F, Watanabe Y, Otsuka K, Khalilov E. Chronobiology
and chronomics: detecting and applying the cycles of nature. Biologist 2009; 56 (4): 209–214
46.	Shinagawa M, Kubo Y, Otsuka K, Ohkawa S, Cornelissen G, Halberg F. Impact of circadian amplitude and
chronotherapy: relevance to prevention and treatment of stroke. Biomed & Pharmacother 2001; 55 (Suppl 1):
125s–132s
47.	 Cornelissen G, Otsuka K, Chen C-H, Kumagai Y, Watanabe Y, Halberg F, Siegelova J, Dusek J. Nonlinear relation
of the circadian blood pressure amplitude to cardiovascular disease risk. Scripta medica (Brno) 2000;
73: 85–94
48.	Halberg F, Cornelissen G, Hillman D, Ilyia E, Cegielski N, el-Khoury M, Finley J, Thomas F, Brandes V, Kino T,
Pappadoupoulou A, Chrousos GP, Costella JF, Mikulecky M. Multiple circadian periods in a lady with recurring
episodes of adynamic depression: case report. In: Halberg F, Kenner T, Fiser B, Siegelova J. (Eds.) Noninvasive
Methods in Cardiology, October 17, 2011, Brno, Czech Republic. Brno: Faculty of Medicine, Masaryk University.
p. 45–67
49.	 Halberg F, Cornelissen G, Singh RB, Gvozdjakova A, Otsuka K, Beaty L, Katinas G, Hermida R, Ayala D,
Czaplicki J. Chronobiology, chronomics and N-of-1 tests of timing coenzyme Q10. In: Gvozdjakova A. (Ed.) Mitochondrial
Medicine: Mitochondrial Metabolism, Diseases, Diagnosis and Therapy. Dordrecht: Kluwer; 2008.
p. 55–92
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50.	 Bingham C, Arbogast B, Cornélissen Guillaume G, Lee JK, Halberg F. Inferential statistical methods for estimating
and comparing cosinor parameters. Chronobiologia 1982; 9: 397–439
51.	 Cornelissen G, Halberg F, Hawkins D, Otsuka K, Henke W. Individual assessment of antihypertensive response
by self-starting cumulative sums. J Medical Engineering & Technology 1997; 21: 111–120
52.	Cornelissen G, Halberg F. Chapter 11: Treatment with open eyes: markers-guided chronotheranostics. In: Youan
BC. (Ed.) Chronopharmaceutics: Science and Technology for Biological Rhythm-Guided Therapy and Prevention
of Diseases. Hoboken, NJ: Wiley; 2009. p. 257–323
53.	 Halberg F, Cornelissen G, Grambsch P, McCraty R, Beaty L, Siegelova J, Homolka P, Hillman DC, Finley J,
Thomas F, Kino T, Revilla M, Schwartzkopff O. Personalized chronobiologic cybercare; other chronomics’
progress by transdisciplinary cycles’ congruences: Season’s Appreciations 2009. J Appl Biomed 2011; 9: 1–34.
54.	Cornelissen G, Grambsch P, Sothern RB, Katinas G, Otsuka K, Halberg F. Congruent biospheric and solarterrestrial
cycles. J Appl Biomed 2011; 9: 63–102
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WHAT IS THE BEST TIME TO EXERCISE?
R. B. SINGH1
, FRANZ HALBERG2
, JARMILA SIEGELOVA3
, GERMAINE CORNELISSEN2
1
Halberg Hospital and Research Institute, Moradabad, India
2
Halberg Chronobiology Center, University of Minnesota, Minneapolis, MN, USA
3
Masaryk University, Brno, Czech Republic
Exercise is an easily accessible and inexpensive approach to improve cardiovascular health, control weight gain, and
increase survival chances after a morbid event such as a myocardial infarction. It is, however, sometimes associated
with untoward effects in vulnerable subjects. A contributory factor may be heart rate variability, which in the
long-term is increased in association with exercise, but may be decreased in the short-term during exercise and the
recovery span after exercise.
The same daily dose of the same medication administered to the same patient has different effects on the circadian
pattern of blood pressure depending on when it is administered (1, 2). This circadian stage-dependent effect of a
given treatment has been observed with both pharmacologic and non-pharmacologic interventions. Whereas an
elevated blood pressure is a known cardiovascular disease risk factor, other alterations of the circadian patterns of
blood pressure and heart rate have also been related to an increased cardiovascular disease risk, including too large
a circadian amplitude of blood pressure (3).
As part of a healthy lifestyle or for rehabilitation purposes, exercise is currently practiced at times of convenience
rather than pertinence. To examine whether the timing of exercise can be optimized on an individual basis, a ­68-year
old man measured his blood pressure and heart rate around the clock at 30-min intervals with an ambulatory monitor
(TM-2421, A&D, Tokyo, Japan) for spans of 4–7 days during which he exercised at different times (around 06.00,
09.00, 12.00, 15.30, and 18.00). Each day’s data as well as each record as a whole was analyzed by cosinor to obtain
estimates of the MESOR (M, rhythm-adjusted mean), and 24-hour amplitude and acrophase (phase of fitted model’s
maximum) (4). Results were assigned to the clock hour of exercise during the given span to yield new time series
amenable to cosinor analysis (4), complementing the one-way analysis of variance, the main effect being timing of
exercise.
Systolic and diastolic blood pressures were predictably higher during the span when exercise was performed daily
around noon as compared to spans when it was done earlier or later in the day, Figure 1. On the average, their daily
MESORs were 9.5 or 7.1 mmHg higher when exercise was done around 15.30 (SBP) or noon (DBP) by comparison to
06.00 in the morning. The circadian amplitude of heart rate was also predictably larger (by a factor of about 2) when
exercise was performed around noon (P = 0.042 by cosinor).
The immediate response of blood pressure and heart rate to graded exercise was also circadian stage-dependent in
an earlier study on four marathon runners. The smallest blood pressure response occurred around mid-day, larger
decreases observed when exercise was done earlier or later in the day (5). Exercise by a 46-year old man was associated
with an increase in the circadian amplitude of blood pressure that was more pronounced when exercise was
done in the evening than in the morning, in his case leading to an abnormal circadian pattern potentially carrying an
increased cardiovascular disease risk, as recorded by one of us (JS).
Depending on whether the circadian pattern of blood pressure at the outset tends to have too large an amplitude or
not, exercise should be timed to reduce both long-term and short-term blood pressure without bringing about an
abnormal variability in blood pressure that may be harmful. Ambulatory monitoring interpreted chronobiologically
can serve for the optimization of the timing of exercise on an individual basis.
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Figure 1.
Support: GM-13981 (FH), University of Minnesota Supercomputing Institute (GC, FH)
REFERENCES
1.	 Halberg F, Cornelissen G, Wilson D, Singh RB, De Meester F, Watanabe Y, Otsuka K, Khalilov E. Chronobiology
and chronomics: detecting and applying the cycles of nature. Biologist 2009; 56 (4): 209–214
2.	 Youan BC. (Ed.) Chronopharmaceutics: Science and Technology for Biological Rhythm-Guided Therapy and
Prevention of Diseases. Hoboken, NJ: Wiley; 2009 (see pp. xvii–xxxii, 217–255, and 257–323)
3.	 Halberg F, Cornelissen G, Otsuka K, Siegelova J, Fiser B, Dusek J, Homolka P, Sanchez S, Singh RB, BIOCOS
Project. Extended consensus on need and means to detect Vascular Variability Disorders (VVDs) and Vascular
Variability Syndromes (VVSs). World Heart J 2010; 2(4): 279–305
4.	 Cornelissen G, Halberg F. Chronomedicine. In: Armitage P, Colton T. (Eds.) Encyclopedia of Biostatistics,
2nd
 ed. Chichester, UK: John Wiley & Sons Ltd; 2005. p. 796–812
5.	 Levine H, Saltzman W, Yankaskas J, Halberg F. Circadian state dependent effect of exercise upon blood pressure
in clinically healthy men. Chronobiologia 1977; 4: 129–130
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CHRONOMIC CLOUD SYSTEM FOR CHRONORISKINTERPRETED
AMBULATORY BLOOD
PRESSURE MONITORING (C-ABPM)?
YINJING GUO1
, GERMAINE CORNELISSEN2
, BING WU2
, LARRY A. BEATY3
, CHRIS ADAMS3
,
EL ­NOLLEY3
, JINYI WU2
, FRANZ HALBERG2
1
Shandong University of Science and Technology, Shandong, China
2
Halberg Chronobiology Center, University of Minnesota, Minneapolis, MN, USA
3
Phoenix Group of IEEE Engineers, Minneapolis, MN, USA
1. DEFINITIONS
Chronobiology is the study of chronomes (biological time structures), including rhythms documented, among others,
in Minnesota, Table 1 (1–3). Chronomics is the study of ongoing interactions among biological and environmental
chronomes, the latter from near and far, Table 2 (2, 3).
2. CLOUD COMPUTING: STATUS QUO (4–30)
Cloud computing involves a high-efficiency computing model utilizing resources on the Internet in a (cloud) center
providing services for, e.g., an application layer, a platform layer and an infrastructure layer, which should overcome
problems encountered in the conventional fragmented status quo of information technology (IT) systems. Clouds
should emphasize IT aggregation, optimization, dynamic allocation and streamlining and easy automatic recovery
of information at preset intervals for repeated passes over the same data resources, aiming at cost savings in information
technology, reducing energy consumption and improving the efficiency of a national and eventually of an
international multilingual data center yet to be created.
3. HISTORY
Cloud computing steps follow major prior developments from mainframe computers before and after 1965, to the
personal computer which first became popular around 1980, and the Internet revolution which began around 1995.
Cloud computing began around 2010. Every such technological change led to significant turmoil and change in the
competitive landscape between enterprise, industry or even countries, with the Internet revolution to some extent
taking advantage of the American/information superhighway/ strategy. Whether or not there is an about (~) 15-year
periodicity in the foregoing computational developments constitutes a possibility attributed to Lou Gerstner, former
chief executive officer of IBM.
An ~15-year cycle has been reported in the blood circulation of some individuals (2, 3), further as a physical global
solar cycle (31) and one in interplanetary magnetism [in data linearly showing a 17-year cycle (32) that upon nonlinear
analysis became an ~15-year cycle (3)]. Thus far in health care, cloud computing aims at increasing efficiency in
what is already being done today in terms of diagnosing deviations from an assumed static “physiologic range” that
is ignored by target values, e.g., for acceptable blood pressures.
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4. OUTLOOK
The chronomic cloud’s aim is to resolve the dynamics of the currently neglected range as a new diagnostic realm in
which strain from all sources, including the heretofore-unassessed load of space weather (2, 3), is resolved, Table 3.
Lawful changes within the physiological range include cycles of different frequencies, many of them shared with the
environment. They serve for an assessment of health vs. an elevated risk of illness (Figure 1). Diagnosis of circadian
risk elevation (Figure 2) already allows the institution of timely non-pharmacological and/or pharmacological timed
treatment for a true primary prevention during apparent wellness. Resolving variability within the physiological
range can be compared with the splitting of the atom (Figure 3). Just as the latter released much new energy, valuable
information becomes available in medicine and biology more broadly. Intervention before the fait accompli of disease
leads to the paradox of an improved health care system at a reduced cost (Figure 4) (33, 34).
INFRADIAN DIVISION OF LABOR IN TIME BY DIFFERING PERIODS
Figure 1. Infradian cycles mapped in a clinically healthy man open a new infradian region of a transdisciplinary
spectrum of cycles, of basic interest in themselves and invaluable for new diagnoses, since they characterize
sudden cardiac death and suicide among other conditions. Original data of Dr. Robert Sothern. © Halberg.
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Figure 2. It is not enough to diagnose a high blood pressure, that is more reliably measured
as an elevation of the mean (or MESOR), as MESOR-hypertension. When other anomalies
(see Figure 5) coexist, there is a great undiagnosed risk of a morbid event. © Halberg.
Figure 3. Splitting, i.e., resolving normality into measurable characteristics has a precedent in physics. Just as atomic
fission and fusion changed physics, chronobiology and chronomics change a unified science. © Halberg.
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Figure 4. More for less (right) from chronobiology and chronomics, i.e., more by cyber-aided cheaper
self-surveillance (right) than from visits to care providers and hospitals (left). © Halberg.
5. SYSTEM FUNCTIONS
•	 For patients with chronobiologically analyzed ambulatory blood pressure and heart rate records (C-ABPM) to
detect anomalies in an “as-one-goes” strain test. This is a first, most cost-effective step with diverse important
dividends (35, 36), eventually to be followed by ambulatory blood oxygen saturation recording, running electrocardiograms,
electroencephalograms, and other physiological functions to be added step-by-step.
•	 Expert systems through chronobiology and chronomics may automatically realize diagnoses of an elevated disease
risk, such as circadian vascular variability anomalies, cVVAs (Figure 5), eventually to be followed by the
detection of extracircadian anomalies complementing cVVAs (35, 36; cf. 3, 4).
•	 Global positioning would automatically indicate an individual’s position on an electronic map of the service center,
automatically navigate and deploy medical services personnel when needed.
•	 Establish a massive electronic patient database and use data mining technologies for psychophysiology, anthropometry,
epidemiology and sociology, to obtain earliest signs of emerging epidemics and track the source of the
outbreak, in addition to providing information for further improved diagnoses and basic data for medical services
and all other human affairs dealt with by a centralized website (Figure 6) in an international data center.
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Figure 5. Abstract description of Vascular Variability Anomalies, VVAs. A double product (systolic blood pressure x heart
rate/100) above 100 is another VVA not here shown. Consequences of coexisting VVAs are summarized in Figure 2. © Halberg.
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Figure 6. The many dividends from a chronomic cloud system with a website in a data center for service in self-surveillance to
individuals, as background for care givers and for research on natural and human-made cataclysm prevention and/or evasion, all
by one as-one-goes lifetime’s strain test, aligned with results, among others, from space weather stations, health departments’
epidemiology, police departments’ information on crime rates and economics for research in a unified science. © Halberg.
6. BEYOND A CHINESE CHRONOBIOLOGIC-CHRONOMIC CLOUD
Every crisis, financial or other, gave birth to some new technology, which in turn was a tremendous impetus to help the
economy, especially industry, get out of the crisis.
 Premier Wen
In Wuxi in August 2009, Premier Wen of China reportedly (by YG) said that there were at least three things to do as
soon as possible:
a. 	 Combine applications of medical, social and environmental monitoring systems with third- and fourth-generation
cellphone systems;
b. 	 Accelerate the development of cloud computing in major national science and technology centers;
c. 	 Establish a central national information center (“Sensoring China”).
At this point, cloud computing officially entered the public eye in the People’s Republic. Subsequently, Premier Wen
also mentioned on many occasions that China has put the Internet and cloud computing into its future development
plans. The time may come when this may be a principal export market from China.
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NONINVASIVE METHODS IN CARDIOLOGY 2012
7. DISCUSSION
A project on The BIOsphere and the COSmos, BIOCOS, currently ongoing worldwide on a minuscule scale (2, 3),
nonetheless:
a. 	 Provides information revealing that C-ABPM detects an individual’s circadian VVAs and thus can gauge emotional
and other loads as a strain test;
b. 	 Predicts, by population monitoring, risks greater than a high blood pressure in the form of VVAs (Figure 5);
c. 	 Shows that a high blood pressure average, a circadian VVA in itself, changes the risk of a morbid event from ~8
to 100% in this study when coexisting with other cVVAs, detected only by C-ABPM, (Figure 5);
d. 	 Detects prediabetes; and thus, by a and c above
e. 	 Predicts a premetabolic syndrome;
f. 	 Documents that systolic blood pressure can be a proxy gauging the effect of interplanetary and terrestrial magnetism;
and
g. 	 Indicates that systolic blood pressure can also monitor the pre-earthquake environment (2, 3).
8. CONCLUSION
Koop et al. (37) visualize a cyber-health care for 2026 to achieve cost-effectively what is being done today. Preparations
for their system could be implemented by C-ABPM earlier, perhaps by a cloud system communicating with
a website. As a first step, C-ABPM for severe disease, such as stroke prevention, notably for the elderly, could serve as
an initial application since BIOCOS has provided concept validation, except for the cellphone link.
Support: GM-13981 (FH), University of Minnesota Supercomputing Institute (GC, FH)
REFERENCES
1.	 Halberg F. Chronobiology. Annu Rev Physiol 1969; 31: 675–725
2.	 Halberg F, Cornelissen G, Katinas GS, Hillman D, Otsuka K, Watanabe Y, Wu J, Halberg Francine, Halberg J,
Sampson M, Schwartzkopff O, Halberg E. Many rhythms are control information for whatever we do: an autobiography.
Folia anthropologica 2012; 12: 5–134. http://ttk.nyme.hu/blgi/Knyvek%20kiadvnyok/FOLIA%20
ANTHROPOLOGICA/folia12.pdf
3.	 Halberg F, Cornelissen G, Gumarova L, Halberg Francine, Ulmer W, Hillman D, Siegelova J, Watanabe Y, Hong
S, Otsuka K, Wu J, Lee JY, Schwartzkopff O, Wendt H. Integrated and as-one-goes analyzed physical, biospheric
and noetic monitoring: Preventing personal disasters by self-surveillance may help understand natural cataclysms:
a chronousphere (chrono-noösphere). London: SWB International Publishing House; 2012. 106 pp,
in press
4.	 He C, Fan X, Li Y. Toward ubiquitous healthcare services with a novel efficient cloud platform. IEEE Trans
Biomed Eng 2012 Oct 5. [Epub ahead of print] PMID: 23060318
5.	 Savage GT, van der Reis L. A Dutch and American commentary on IT in health care: roundtable discussions on
IT and innovations in health care. Adv Health Care Manag 2012; 12: 61–74
6.	 Viana-Ferreira C, Ferreira D, Valente F, Monteiro E, Costa C, Oliveira JL. Dicoogle Mobile: a medical imaging
platform for Android. Stud Health Technol Inform 2012; 180: 502–506
7.	 Vida MM, Lupse OS, Stoicu-Tivadar L, Bernad E. Flexible solution for interoperable cloud healthcare systems.
Stud Health Technol Inform 2012; 180: 280–284
8.	 Karthikeyan N, Sukanesh R. Cloud based emergency health care information service in India. J Med Sys0 2012;
36(6): 4031–4036
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TABLES
Table 1. Minnesota contributions leading to chronobiology (Annu Rev Physiol 1969; 31: 675–725) resolving biological
time structures, including circadian (Z Vitamin-, Hormon-u Fermentforsch 1959; 10: 225–296) and other rhythms
1. The partly genetic basis of circadian rhythm characteristics and their uncertainties initially documented by differences in
extent of within-day change of circulating eosinophil cell counts, among inbred strains of mice (1950) (Proc Soc exp Biol 1950;
75: 846–847) and by periods in core temperature, differing from their environmental 24-hour counterparts after blindness,
“free-running” (Am J Physiol 1954; 179: 229–255). Human hereditary aspects of about (~) 24-hour and ~7-day cycles
documented on twins (Biomed & Pharmacother 2001; 55 [Suppl 1]: 32s–50s).
2. The importance of the adrenal cortical cycle: documented by a “remove” (and replace) approach (1951: Journal-Lancet
[Minneapolis] 1951; 71: 312–319; Journal-Lancet [Minneapolis] 1953; 73: 20–3; Postgrad Med 1958; 24, 349–3582).
3. Light and feeding schedules, competing environmental synchronizers of circadian rhythms, mealtime dominating on a restricted
diet (1953: Am J Physiol 1953; 174: 109–122).
4. Timing in the cell: RNA and DNA are strongly circadian periodic; RNA synthesis precedes DNA formation in the cell cycle,
describing what really happens in time in cellular transcription. Also, that a rhythm in cell membrane phospholipid peaks
before RNA formation (1958; Proc Soc exp Biol (NY) 1958; 97, 897–900). First hint that RNA may also precede DNA in
evolution.
5. Importance of hypothalamus traced from the eyes as transducers of lighting regimen effects on circadian period of adrenal
cortex over the pituitary to the CNS (1954: In: Withrow RB, Ed. Photoperiodism and Related Phenomena in Plants and Animals.
Ed. Publ. No. 55. Washington DC: AAAS; 1959. p. 803–878; many subsequent articles) and to the cell. (The suprachiasmatic
nucleus, part of the hypothalamus, was identified later, and its then-claimed importance as sole timer was debunked by
1958 and subsequently (Chronobiologia 1979; 6: 405–424; Anat Rec 1974; 180: 47–52). The long-denied timing mechanisms
in the periphery, denied for decades, are also now accepted.
6. Timing for the body as a whole: different, including opposite effects of the same hormones (growth hormone, ACTH, TSH)
or (e.g., anti-cancer) drugs, or of the same number of calories, depending only on the circadian timing of administration (1973;
Experientia [Basel] 1973; 29: 909–934; Peptide chronomics. In: Kastin A, Ed. Handbook of Biologically Active Peptides. Amsterdam:
Elsevier; 2006. p. 1529–1564).
7. Circadian rhythms tip the scale between life and death in response to many stimuli: physical stimulus (noise) (1955: Proc
Soc exp Biol (NY) 1955; 88: 169–173); whole-body irradiation (Haus E, Halberg F, Loken MK, in Scheving LE, Halberg F,
Pauly JE, Eds. Chronobiology, Proc. Int. Soc. for the Study of Biological Rhythms, Little Rock, Ark. Stuttgart: Georg Thieme
Publishers/Tokyo: Igaku Shoin Ltd.; 1974. p. 115–122); chemical (alcohol) (J appl Physiol 1959; 14, 878–880); biochemical
(endotoxin) (J clin Endocrinol 1955; 15: 887); drug (ouabain) (Fed Proc 1959; 18: 63), culminating in the doubling of the
2-year survival rate in patients with advanced perioral cancers (Guest Lecture, Proc. 30th
Ann. Cong. Rad., January 1977, PostGraduate
Institute of Medical Education and Research, Chandigarh, India, 8 pp; J Exp Therapeutics Oncol 2003; 3: 223–260).
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NONINVASIVE METHODS IN CARDIOLOGY 2012
8. Circadian rhythmicity in a prokaryote (without a nucleus), originally strongly contradicted by a committee on the molecular
basis of circadian rhythms (Report of the Dahlem Workshop on the Molecular Basis of *Circadian Rhythms, Berlin, November
3–7, 1975. Berlin: Dahlem Konferenzen, 1976: 462 pp); that partly endogenous rhythms are found in all life (Proc MN Acad
Sci 1961; 29: 227–239) is now universally accepted.
9. A broad set of statistical methods and programs for detecting, validating, quantifying and comparing (always with uncertainties
estimated) rhythms, trends and chaos starting with the linear and nonlinear cosinor (in von Mayersbach H, Ed.
The Cellular Aspects of Biorhythms, Springer Verlag, NY, 1967, pp. 20–48; cf. Acta med rom 1980; 18: 399–440).
10. Discovery of an (eventually long) list of periods in addition to about-daily (circadian) periods, starting with the biological
near-week, followed by discovery of the corresponding geomagnetic near-week followed by numerous other infradian periods
(1965: Acta endocrinol 1965; 50 [Suppl 103]: 5–54; University of Minnesota/Medtronic Chronobiology Seminar Series, #1,
December 1991), leading from chronobiology, a figurative microscopy in time, to chronomics, a figurative telescopy in time.
Table 2. Minnesotan contributions to chronomics, resolving transdisciplinary geo-bio-noospheric coperiodisms
leading to a unified science and art* (Biomed & Pharmacother 2004; 58 [Suppl 1]: S150–S187)
1. A set of methods and programs resolving, with uncertainties, coexisting multiple, sometimes spectrally neighboring periods,
τ, with non-overlapping CIs (95% confidence intervals) of , revealing and mapping non-stationarity in time and
space (including the transient disappearance of an aeolian nonphotic component in certain spectral or geographic locations).
2. Congruences defined by overlapping CIs of period, τ, and/or phase, , e.g., within the organism (division of labor in time),
within the environment (e.g., Kp vs. Wolf numbers, geo- vs. heliomagnetism) or external-internal congruences (e.g., blood
pressure and geomagnetism) at a given 
3. New internal-external congruent CIs of s define coperiodisms, some found first in living matter and next in the abiotic
environment, others vice versa, constituting a transdisciplinary spectrum with component τs of a near-week, an about
(~)  2-week, ~1-month, ~5-month (quinmensal), semiannual, circannual, near- and far-transannual, diennian, septennian,
decadal, ~15–17-year, paradecadal, paradidecadal, paratridecadal (BEL, Bruckner-Egeson-Lockyer, near
30–40-years), ­~50-year (semicentennian), transsemicentennian, semimillennian and myriadennian components.
4. Partial endogenicity, genetic coding supported by τs with nonoverlapping CIs in and around us (free-run), and by “after single
stimulus” manifestation (“induction”)
5. Brain (pineal and suprachiasmatic nucleus, SCN) (mediating) or heart, circulation and cell (reflecting) non-photic environmental
effects (shown by SCN ablation or magnetic storm effects).
6. Nonphotic spectral components in populations of eukaryotes and prokaryotes (decadals in bacterial mutations).
7. Selective assortment (SA) of τs (or s) among and within individuals, in organ systems, variables, cycle characteristics
­(MESOR vs. amplitude), and in their lock-ins (of , e.g., of 17-ketosteroids with Kp and urine volume not with Kp but possibly
with Wolf numbers)
8. SA of τs in different variables of the same population or of phases at a fixed  in different populations.
9. Nonphotics can tip the scale between little or none versus many infections, sudden cardiac death, suicide and terrorism.
10. Odds ratios for the number of shared frequencies between human mental functions and either helio- or geo- magnetism more
than match the association of helio- and geo-magnetism to each other.
*Rules learned from decades-long longitudinal studies of populations and of individuals analyzed globally and locally, glocally
in space and time, as a method as well as a map, updated progressively at intervals determined by the cycles detected and
pergressively surveilled in serial sections and their sequential analysis in repeated passes over the accumulating data for resolution of
changes in characteristics of each cycle in individuals, eventually from womb to tomb and in populations beyond the human lifespan
CHOICES IN DEALING WITH RESPECT TO PERSONAL, SOCIETAL (HUMAN-MADE) AND NATURAL DISASTERS
1. 	 We currently try, but may not be able, to respond to each cataclysm after it occurs,
whether it is a massive stroke, a crime, a terrorist attack or an earthquake;
2. 	 we can assess currently conventional risk factors and try to reduce their impact according to
visits with a care provider, but fly blind with respect to vascular and other variability disorders
that cannot be detected by a single or 24-hour spotcheck, or alternatively;
3. 	 the individual and society can survey the time structure of personal health by, first, vascular monitoring and
society can implement a system using the physiological data aligned with those from epidemiological and
Table 1: continue
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NONINVASIVE METHODS IN CARDIOLOGY 2012
social monitoring, with the tools of a temporal microscope (chronobiology) and telescope (chronomics),
to assess one’s position by comparing a personalized with a corresponding gender-age-ethnicity-matched
chronousphere providing reference standards as glocal maps via an international website.
Of particular interest are far-transyears, mostly between 1.2 and 1.9 years, which drift in frequency or phase and wax and
wane in amplitude to the point of disappearance and reappearance. So do near-transyears, longer than 1 year but shorter
than 1.2 years, found after their detection in biology in solar and terrestrial magnetism and other counterparts, just as
we found the geomagnetic near-week in Kp, validated by Roederer and extended to aa by Vladimirsky as a counterpart
to a set of biological near-weeks, most of which differ from precisely one week and may hence be partly built-in.
Table 3. Chronobiological and chronomic concepts, tools and long-term goals
Time structures (chronomes) around us are aligned with chronomes in us, by chronomics (figurative telescopy in time),
complementing chronobiology, the study of the mechanisms and applications of biological chronomes, complementary genomes,
a figurative microscopy in time (1)*
* Numbers in ( ) indicate bibliographical references; numbers in [ ] indicate endnotes.
View of: I. Current homeostatic
response physiology
II. Time-structural (chronome)
physiology
Utility of II
1. Definition of normalcy,
e.g., health
Negative: absence of abnormality,
e.g., of disease [1, 2].
Curtain of ignorance on
everyday physiology outside
the normal range of reference
values
Positive: parametric and nonparametric
assessment (cf. 9).
Alteration in the normal range
will be detected
Time structural (chronomic
endpoints): the control in
whatever we do [3]
2. Quantification of normalcy,
e.g., health
Population-based: percent
abnormality, e.g., morbidity
and mortality
Individualized: P-values for
statistical significance and
for scientific (i.e., clinical)
signification
Recognizing risk of abnormality
before the fait accompli of
catastrophe
3. Interpretation of reality Putative (imaginary) set
points, e.g., the fiction of
a true time-invariant blood
pressure
Chronomes: consisting of
a) rhythms;
b) trends;
c) deterministic and other
chaos;
d) any residuals and interactions
among a, b, c and d
Chronorisk syndromes:
1) circadian overswinging of
blood pressure; or
2) chronome alteration with
heart rate jitter deficit; or
3) circadian vascular rhythm
alteration; or
4) altered about-yearly
rhythms in circulating prolactin
and TSH
signaling breast and prostatic
cancer risk elevation
4. Variability Confounder (foe) Of interest in its own right
(friend)
Tool and invaluable source of
much information [4]
5. Biosystems’ behavior if
perturbed
Settling down to an imaginary
steady state (constancy) or
limited random ‘hunting’, e.g.,
as (mistakenly anticipated)
when a single blood pressure
is taken after some (≤ 30)
minutes of rest
Dynamic chronomes that
characterize health within
chronobiologic limits set by
the intermodulation of the
chronomes’ α-, β-, γ- and
δ- (spontaneous, reactive and
modulating) rhythms (2), e.g.,
a large circadian change in
blood pressure during bed rest
Positive individualized quantification
of health
6. Analogy Thermostats with “hunting”
noise (information lost)
Pendulums in resolvable
chronomes
Prediction from parameters
7. Physiologic or normal
ranges of variation
Broad, random, indivisible;
equated to noise, neglecting
current standard for diagnosis
and treatment
Structured, predictable [5];
resolved into reference ranges
(chronodesms) for chronomes
Circadian blood pressure
amplitude (bp-a) or circadian
standard deviation (SD) for
detecting effect of in utero
exposure to betamimetics
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NONINVASIVE METHODS IN CARDIOLOGY 2012
View of: I. Current homeostatic
response physiology
II. Time-structural (chronome)
physiology
Utility of II
8. Action? Confounder elimination
incompatible with detection
of circadian blood pressure
disorder
Monitoring and as-one-goes
analyses, and on this basis,
action
Detects treatable overswinging
of BP-A, which carries
a 720% increase in risk of ischemic
stroke; improves cancer
treatment
9. Endpoints • Original values:
Casual measurements at times
of convenience, not necessarily
of pertinence (e.g., of ‘the’
blood pressure with > 40 %
uncertainty in diagnosis in
cases of border-line hypertension)
(4):
Time-unspecified:
• mean
• SE
Time-specified chrones in
chronomes:
Time-coded:
• original values
• SD
• MESOR(s)
• period(s), τ
• amplitude(s), A
• acrophase(s), φ
• waveform(s) (A,φ)
• pairs of harmonics
• trends
• chaotic dimensions
• residuals
Chronobiologic software:
• provides information, e.g., on
points 3 and 4 above
• guides timed treatment that
has greatly prolonged the
survival of cancer patients
10. Sources of variation Exogenous responses to
stimuli from proximity mostly
from the habitat niche
Endogenous and exogenous;
responses to stimuli from near
and far, including cosmos
Resolution of impact of storms
in space on myocardial infarctions
on earth: space weather
report? [6]
11. Mechanism Feedbacks along axes:
unstructured ‘modulation’
like the deus ex machina
in a physiological tragedy
since outcomes may be
unpredictable
Feedsidewards in networks
with alternating outcomes:
predictable (insofar as rhythmic)
as a chronomodulation
Predictable since rhythmic
neuro-endocrine-vascular
intermodulations can account
for outcomes that may be as
different as stimulation vs.
inhibition of immunity
12. Hierarchy Up/down Collateral:
alternating primacy among intermodulating
multifrequency
rhythms in chronomes
Focusing on selected tasks at
different times
13. Teleonomy Righting and regulation Anticipatory, preparatory
coordination
Greater flexibility
14. Simplified analogy Thermostat Pendulum Prediction of risk by alteration
of parameters
15. Biological evolution Darwinian, externally adaptive More and more internal and
integrative while externally
adaptive to both nature and
nurture
Instrumented self-help
16. Health and environmental
care
Medical treatment often
limited and late, given mostly
after the diagnosis of overt
disease [7]
Optimization according
to marker chronomes (of
interventions by drugs and/
or devices, e.g., pacemakers,
with diagnosis and treatment
refined by narrowed reference
range and assessment within
that range of chronorisk leading
to preventive treatment
timed by marker rhythms (that
also serve to validate effect)
E.g., catastrophic and iatrogenic
disease prevention
Table 3. continue
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NONINVASIVE METHODS IN CARDIOLOGY 2012
View of: I. Current homeostatic
response physiology
II. Time-structural (chronome)
physiology
Utility of II
17. Animal husbandry,
apiculture, aquaculture and
economic entomology
Timed by convenience Chronome-based Optimization: greater efficacy;
fewer undesirable effects
18. Value Often wasteful Cost-effective Waste reduced
19. Seeking inanimate and
animate origins
Stratigraphy for identifying, in
geologically space, sequences
in time; radiocarbon dating
Additional tracing of chronomo-ontogeny
and chronomophylogeny
[8] in the context of
glimpses of cycles in corresponding
spans of a figurative
cosmo-ontogeny (8)
Adds to knowledge of the past
to better optimize the future
20. Life in the scheme of physical
and cultural things
Survival of the fittest with humans
dominating food chains
viewed in the perspective of
bioenergetics in a mostly terrestrial
ecology
Physically and socially
chronomodulating and thus
informatively and integratively
evolving biota molded by human
culture
Homo not only faber but
cosmoinformans and chronomodulans
in a budding broad
chrono-cosmoecology (9)
Humans safeguard the
integrity of the biosphere as it
extends into the cosmos and
as we speculatively, by joining
the approaches by ablations.
superposed epochs and
resonance tests concomitantly
explore the temporal aspectsof
our origins, possibly represented
by our chronomes that
in turn may reflect a long-past
environment (11)
21. Cosmos Ignored The broad spectrum of
non-photic environmental
cycles, reflected in physiology,
predates pathology and sociology
(including politics and
militarism), as in the ~30-year
BEL cycle (12, 13), Figure 2
Survival from hard vascular
events of individuals and from
war and diseases of societies of
populations (11)
22. Investigator satisfaction Frustrating work when
(without specification of chronobiologic
timing, even at the
same clock-hours), one gets
confusing and/or obscuring,
even opposite results from the
same intervention. Up or down
regulation may miss or misinterpert
a change in amplitude
or phase
Sheer fun: long-standing
controversy is resolved by accounting
for both the genetic
and broadly environmental
bases of the feed-sidewards
among inanimate and animate
cycles that constitute life; disease
risk recognition promises
to lead to the prevention or
timed treatment of catastrophic
diseases such as stroke,
cancer or sudden death
Increased productivity
[1] 	 Just as contemporary physics, by fission and fusion, gathers more and more energy by splitting the atom, biomedicine gathers
more and more information by splitting the normal value range into time structures, thereby resolving, e.g., trends and chaos as
well as rhythms (fission) and looking at their feedsideward interrelations (fusion) for a better understanding of an interdigitated,
indivisible Janus-faced inseparable soma and psyche.
[2] 	 Health care, required to deal with disease risk gauged within the normal range, such as conditions in Figure 1, will be missed by
current health promotion, a step in the right direction, by its recommendations of attention to diet, exercise or relaxation, but
should be preceded and followed by a chronobiological assessment of the timing as well as effect of recommended procedures,
rather than merely by the current reliance of ruling out the occurrence of values outside the normal range.
[3] 	 Location and dispersion indices include the determination from histogram of values, of means (arithmetic, geometric, ­harmonic),
median, mode, minimum, maximum, 100% and 90% ranges, interquartile range, standard deviation (SD), weighted SD, ­standard
error (SE); these endpoints are computed from time-unspecified values in the context of the homeostatic approach, whereas in
Table 3. continue
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NONINVASIVE METHODS IN CARDIOLOGY 2012
the chronobiologic framework the location and dispersion indices are used as such on systematic time-specified samples, as time
series-derived parameters, i.e., on each of the endpoints of time structures, M, A, , (An
,n
), etc.
[4] 	 An international project on The Biosphere and the Cosmos, BIOCOS, focuses first upon chronocardiology in general and blood
pressure and heart rate dynamics in particular, for stroke and other catastrophic vascular disease prevention (consult chronobiology
home page, http://www.msi.umn.edu/~halberg/).
[5] 	 Information from the physiologic range for prevention, diagnosis or treatment is much refined when this range is individualized
and interpreted in the light of a personalized background as well as in the context of gender-, age-, ethnicity- and chronome stage-
specification.
[6] 	 The need for forecasting storms in space should be explored further on the basis of systematic studies aligning physiological
lifetime monitoring and clinical and archival statistical studies with ongoing physical data collection near and far, both for ascertaining
effects and in studying countermeasures. Blood pressure, heart rate and other physiological and psychological monitoring
would also provide basic information on any cross-spectral and other associations (feedsidewards) (2) within and among
biological and environmental chronomes while further providing reference values of medical interest.
[7] 	 Even if some preventive measures have also been long implemented, e.g., by vaccination, and even if recently more and more hygienic
measures (such as exercise and caloric, fat and sodium restriction) are also popular, all can be greatly improved by timing
designed with chronobiological individualization. Current action based on group results fails to recognize, for instance, that the
blood pressure response to salt (5, 6) may differ as a function of circadian stage, and there are indeed individuals in whom the
addition of salt lowers rather than raises blood pressure (6, 7).
[8] 	 Development from the egg of rhythms (some may be much older than shards) and of other constituents of chronomes to trace
their homeo- or heterochronically roughly ‘recapitulatory’ development across species, with both ontogeny and phylogeny, perhaps
tracing in their turn the concomitant development of the geocosmic environment. This distant basic goal can be pursued
with the immediate reward of obtaining indispensable reference values for the diagnosis of two chronobiologic risk syndromes,
circadian hyper-amplitude-tension, briefly CHAT, and chronome alterations of heart rate variability, briefly CAHRVs, just as an
extreme deficit in heart rate jitter associated with an increase in the risk of ischemic stroke or of a myocardial infarction of 720
and 550%, respectively.
Support: GM-13981 (FH), University of Minnesota Supercomputing Institute (GC, FH).
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55 (Suppl 1): 153s–190s.
2.	 Halberg F, Cornelissen G, Katinas GS, Watanabe Y, Otsuka K, Maggioni C, Perfetto F, Tarquini R, Schwartzkopff O, Bakken EE.
Feedsidewards: intermodulation (strictly) among time structures, chronomes, in and around us, and cosmo-vasculo-neuroimmunity.
About ten-yearly changes: what Galileo missed and Schwabe found. In: Conti A, Maestroni GJM, McCann SM, Sternberg
EM, Lipton JM, Smith CC. Eds., Neuroimmunomodulation (Proc. 4th
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Extended consensus on means and need to detect vascular variability disorders (VVDs) and vascular variability syndromes
(VVSs). Leibniz-Online Nr. 5, 2009 (http://www.leibniz-sozietaet.de/journal). 35 pp.
4.	 Halberg F, Cornelissen G, International Womb-to-Tomb Chronome Initiative Group: Resolution from a meeting of the International
Society for Research on Civilization Diseases and the Environment (New SIRMCE Confederation), Brussels, Belgium,
March 17–18, 1995: Fairy tale or reality? Medtronic Chronobiology Seminar #8, April 1995, 12 pp. text, 18 figures. http://www.
msi.umn.edu/~halberg/
5.	 Itoh K, Kawasaki T, Cugini P. Effects of timing of salt intake to 24-hour blood pressure and its circadian rhythm. J Nutr Sci Vitaminol
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29: 667–677.
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7.	 Bittle CC Jr, Molina DJ, Bartter FC. Salt sensitivity in essential hypertension as determined by the cosinor method. Hypertension
1985; 7: 989–994.
8.	 Halberg F, Otsuka K, Katinas G, Sonkowsky R, Regal P, Schwartzkopff O, Jozsa R, Olah A, Zeman M, Bakken EE, Cornelissen G.
A chronomic tree of life: ontogenetic and phylogenetic ‘memories’ of primordial cycles keys to ethics. Biomed & Pharmacother
2004; 58 (Suppl 1): S1–S11.
9.	 Halberg F, Cornelissen G, Regal P, Otsuka K, Wang ZR, Katinas GS, Siegelova J, Homolka P, Prikryl P, Chibisov SM, Holley
DC, Wendt HW, Bingham C, Palm SL, Sonkowsky RP, Sothern RB, Pales E, Mikulecky M, Tarquini R, Perfetto F, Salti R, Maggioni
C, Jozsa R, Konradov AA, Kharlitskaya EV, Revilla M, Wan CM, Herold M, Syutkina EV, Masalov AV, Faraone P, Singh
RB, Singh RK, Kumar A, Singh R, Sundaram S, Sarabandi T, Pantaleoni GC, Watanabe Y, Kumagai Y, Gubin D, Uezono K,
Olah A, Borer K, Kanabrocki EA, Bathina S, Haus E, Hillman D, Schwartzkopff O, Bakken EE, Zeman M. Chronoastrobiology:
proposal, nine conferences, heliogeomagnetics, transyears, near-weeks, near-decades, phylogenetic and ontogenetic memories.
Biomed & Pharmacother 2004; 58 (Suppl 1): S150–S187.
10.	 Halberg F, Cornelissen G, Katinas G, Tvildiani L, Gigolashvili M, Janashia K, Toba T, Revilla M, Regal P, Sothern RB, Wendt HW,
Wang ZR, Zeman M, Jozsa R, Singh RB, Mitsutake G, Chibisov SM, Lee J, Holley D, Holte JE, Sonkowsky RP, Schwartzkopff O,
Delmore P, Otsuka K, Bakken EE, Czaplicki J, International BIOCOS Group. Chronobiology’s progress: season’s appreciations
2004–2005. Time , frequency , phase , variable , individual , age- and site-specific chronomics. J Appl Biomed 2006; 4: 1–38.
http://www.zsf.jcu.cz/vyzkum/jab/4_1/halberg.pdf
11.	 Halberg F, Cornelissen G, Sothern RB, Katinas GS, Schwartzkopff O, Otsuka K. Cycles tipping the scale between death and
survival (= “life”). Progress of Theoretical Physics 2008; Suppl. 173: 153–181.
12.	 Halberg F, Cornelissen G, Czaplicki J, Prabhakaran Nayar SR, Siegelova J. Brückner-Egeson-Lockyer (BEL) climate cycle in
original Brückner’s, Lockyer’s and follow-up data. In: Halberg F, Kenner T, Fiser B, Siegelova J. Eds. Proceedings, Noninvasive
Methods in Cardiology, Brno, Czech Republic, October 4–7, 2008. p. 74–89. http://web.fnusa.cz/files/kfdr2008/sbornik_2008.
pdf
13.	 Halberg F, Cornelissen G, Best WR. A transtridecadal BEL cycle in human blood pressure and body weight. In: Halberg F, Kenner
T, Fiser B, Siegelova J. Eds. Proceedings, Noninvasive Methods in Cardiology, Brno, Czech Republic, July 7–10, 2009. p. ­257–270.
http://web.fnusa.cz/files/kfdr2009/sbornik_2009.pdf
NONINVASIVE METHODS IN CARDIOLOGY 2012
Edited by: HALBERG F., KENNER T., SIEGELOVÁ J., DOBŠÁK P.
Published by Masaryk University in 2012
1st
edition, 2012
Printed by: Tiskárna KNOPP, Černčice 24, 549 01 Nové Město nad Metují
Typesetting: Institute Biostatistics and Analyses, Masaryk University
ISBN 978-80-210-6026-5
ISBN 978-80-210-6026-5