Masaryk University • Faculty of Medicine • Brno • Czech Republic
NONINVASIVE METHODS
IN CARDIOLOGY
2017
Edited by: Cornélissen G., Siegelová J., Dobšák P.
DEDICATED TO THE 85TH
ANNIVERSARY OF PROFESSOR THOMAS KENNER
Brno 2017
© 2017 Masarykova univerzita
ISBN 978-80-210-8794-1
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
Reviewed by:	Prof. MUDr. Kamil Javorka, DrSc.
Jessenius Faculty of Medicine in Martin
Comenius University in Bratislava
Slovak Republic
Contents
Prof. Dr. Thomas Kenner, D.h.c. mult. 85 years of age ........................................................................ 5
Jarmila Siegelova
20 Years of History of Department of Sports Medicine and Rehabilitation........................................ 15
Jarmila Siegelová
Dr Othild Schwartzkopff (18. 5. 1922 - 23. 5. 2017) Halberg Chronobiology Center University of
Minnesota, USA.................................................................................................................................. 49
Jarmila Siegelová, Germaine Cornélissen
The Meaning of Acute Changes of Cardio Ankle Vascular Index...................................................... 55
Kazuhiro Shimizu, Akihiro Ogawa, Kohji Shirai
Acute Effect of Resistance Training on Cardio-Ankle Vascular Index (Cavi).................................... 63
Akihiro Ogawa, Kazuhiro Shimizu, Kohji Shirai
Different Chronotherapy Protocols Applied to Blood Pressure........................................................... 69
Germaine Cornelissen, Yoshihiko Watanabe, Jarmila Siegelova, Jiri Dusek, Alena Havelkova,
Leona Dunklerova, A. Chase Turner, Larry Beaty, Kuniaki Otsuka
Chronobiology, Mitochondria, and Cardiovascular Disease............................................................... 83
Linda Sackett-Lundeen, Germaine Cornelissen
Seven Day Blood Pressure Variability: The Effect of Sauna Procedure and Whole Body
Cryotherapy Procedure on 24 Hour Blood Pressure Profile in Healthy Subjects................................ 99
Jarmila Siegelová, Alena Havelková, Klaudia Michalčinová, Jiří Dušek, Michal Pohanka,
Leona Dunklerová, Pavel Vank, Petr Dobšák, Germaine Cornélissen
Seven-Day Ambulatory Blood Pressure Monitoring after 4 Months of Exercise Training................117
Jarmila Siegelová, Alena Havelková, Dita Raková, Jiří Dušek, Michal Pohanka, Leona Dunklerová,
Petr Dobšák, Germaine Cornélissen
When to Exercise for Better Health................................................................................................... 125
Jarmila Siegelová, Alena Havelková, Jiří Dušek, Leona Dunklerová, Petr Dobšák,
Germaine Cornélissen
Ambulatory Rehabilitation Program for Patients with Cardiovascular Diseases ..............................133
Leona Mífková, Alena Havelková, Radka Látalová, Pavel Homolka, Pavel Vank,
Ladislav Svoboda, Michaela Sosíková, Jarmila Siegelová, Petr Dobšák
Effect of Cv-Rhb Program on Main Functional Parameters and Arterial Stiffness in Patients with
Cardiovascular Diseases.................................................................................................................... 139
Alena Havelková, Leona Mífková, Petra Palanová, Veronika Mrkvicová, Michaela Spáčilová,
Jiří Jančík, František Várnay, Jiří Jarkovský, Ladislav Dušek, Michaela Sosíková,
Pavel Vank, Jarmila Siegelová, Petr Dobšák
CATkit: A Toolkit for Chronobiological Study with Diverse Applications........................................145
Cathy Lee Gierke, Germaine Cornelissen
Lessons Learned from Longitudinal Blood Pressure Monitoring......................................................149
Yoshihiko Watanabe, Larry Beaty, Kuniaki Otsuka, Jarmila Siegelova, Germaine Cornelissen
Spaceflight and Geriatrics................................................................................................................. 157
Nandu Goswami
NONINVASIVE METHODS IN CARDIOLOGY 2017
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Prof. Dr. Thomas Kenner, D.h.c. mult. 85 years of age
Jarmila Siegelova
Dept. of Physiotherapy and Rehabilitation, Dept. of Sportsmedicine and Rehabilitation, Faculty of Medicine, Masaryk
University, St. Anna´s Teaching Hospital, Brno
Figure 1: 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 University Brno, 2000
Head, Dept. of Physiology, Karl-Franzens-Universität Austria
Rektor (president) Karl-Franzens-Universität, Austria
Dean of Medical School, Karl-Franzens-Universität, Austria
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
NONINVASIVE METHODS IN CARDIOLOGY 2017
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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-Franzens-Universität, Graz,
Austria.
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
NONINVASIVE METHODS IN CARDIOLOGY 2017
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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 scientific papers 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 great luck to cooperate with Prof. Thomas Kenner from nineties in the last century, he
visited Brno every year two or three times, presented every time one or two lectures and dicussed with
me, late Prof. Bohumil Fiser, CSc, Dr. Jiri Dusek,CSc, Prof. Petr Dobsak, CSc, late Prof. Jan Penaz,
CSc, late Profesor Zdenek Placheta, DrSc., Prof. Pavel Braveny, CSc., Masaryk University and our
other excelent scientist from abroad Prof. Dr. Franz Halberg, D.h.c, father of chronobiology, Prof.
Dr. Germaine Cornelissen, University Minnesota, Halberg Chronobiology Center, USA, late Prof. Dr.
Jean Paul Martineaud, Medical Faculty, University Paris, France, Prof. Jean Eric Wolf, University
Dijon, France, Dr. Jean Christoph Eicher, University Dijon France and other cooperating visitors
from Japan Prof. Masario Kohzuki University Sendai and Prof. Kohji Shirai, Toho University, Chiba.
The presentations were published in Scripta Medica, Masaryk University Brno (included in SCOPUS
database), in Abstracts books and in Noninvasive methods of Cardiology 1996, 1999, 2002, 2003,
2005, 2006, 2007, 2008, 2009, 2010, 2011, 2012, 2013, 2014, 2015, 2016 and it is possible to find then
on Masaryk University, CZ web sides and on web sides of University Minnesota USA. We wish him
a many happy returns of his birthday and happiness with his wife Brigitte Kenner his family.
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 five years.
Ad multos Annos!
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Figure 2: Prof. MUDr. Jarmila Siegelová, DrSc, Dr. Othild Schwarzkoppf, Prof. Dr. Franz Halberg, Dr.h.c.mult.,
Prof. MUDr. Thomas Kenner,Dr.h.c.mult., Prof. MUDr. Bohumilf Fiser, CSc, Brno, Congress of Cardiology,
1997
Figure 3: Prof. Dr. Thomas Kenner, Dr.h.c.mult., Prof. MUDr. Jarmla Siegelova, DrSc., Congress of Noninvasive
methods in Cardiology, Brno 2014
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Figure 4: Prof. Dr. Thomas Kenner, Dr.h.c.mult., Prof. MUDr. Jarmila Siegelova, DrSc., Congress of
Noninvasive methods in Cardiology, Brno videopresntation with Prof. Dr. Germaine, Cornelissen, University of
Minnesota, USA 2014
Figure 5: Prof. Dr. Thomas Kenner, Dr.h.c.mult., Brigitte Kenner, Prof. MUDr. Jarmila Siegelova, DrSc.,
Congress of Noninvasive methods in Cardiology, Brno videopresntation with Prof. Dr. Germaine, Cornelissen,
University of Minnesota, USA 2014
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Figure 6: Prof. Thomas Kenner, Dr.h.c.mult., Brigitte Kenner, Graz University, Austria, Prof. MUDr. Jarmila
Siegelová, DrSc., MUDr. Jiri Dusek, CSc., Congress of Cardiology, Brno, 2013
Figure 7: Prof. Dr. Thomas Kenner, Dr.h.c.mult. Austria and Prof. Dr. Kohji Shirai, Japan, Congress
Noninvasive Methods in Cardiology, Brno 2012
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Figure 8: Prof. Thomas Kenner, Dr.h.c.mult., Brigitte Kenner, Graz University, Austria, Prof. MUDr. Jarmila
Siegelová, DrSc., Assoc. Prof. Dieter Platzer, Graz, Austria, MUDr. Jiri Dusek, CSc., Congress of Cardiology,
Brno, 2015
Figure 9: Assoc. Prof. Dieter Platzer, Prof. Thomas Kenner, Dr.h.c.mult., Brigitte Kenner, Graz University,
Austria, MUDr. Jiri Dusek, CSc., Prof. MUDr. Jarmila Siegelová, DrSc., Congress of Cardiology, Brno, 2015
NONINVASIVE METHODS IN CARDIOLOGY 2017
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Figure 10: Prof. Dr. Thomas Kenner, Dr.h.c.mult. Austria, Congress of Cardiology, Brno, 2015
Figure 11: Prof. Dr. Germaine, Cornelissen, Cathy Gierke, University of Minnesota, USA,
Prof. Thomas Kenner, D.h.c. mult., Assoc. Prof. Dieter Platzer, University Graz, Austria,
Prof. MUDr. Jarmila Siegelova, DrSc., Prof. MUDr. Petr Dobsak, CSc., Masaryk University,
videoconference, Workshop Brno, 2016
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Figure 12: Anita Ertl, Prof.MUDr. Jarmila Siegelová, DrSc, Prof. Dr. Thomas Kenner, D.h.c.mult., Brigitte
Kenner, Dept. of Physiology, University Graz, Austria 2016
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NONINVASIVE METHODS IN CARDIOLOGY 2017
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20 Years of History of Department of Sports Medicine and
Rehabilitation
Prof. MUDr. Jarmila Siegelová, DrSc.
Department of Physiotherapy and Rehabilitation, Faculty of Medicine, Masaryk University, the Czech Republic
History
Two Departments - the Dept. of Functional Diagnostics and Sports Medicine of the Faculty of
Medicine, Masaryk University and the Department of Rehabilitation of the St. Anna Teaching Hospital
in Brno established the Department of Functional Diagnostics and Rehabilitation, Faculty of Medicine,
Masaryk University, now the Dept. of Sports Medicine and Rehabilitation since 2010, headquartered
in St. Anna Teaching Hospital in Brno in October 1, 1997. The history of both workplaces is different.
Department of Functional Diagnostics and Sport Medicine, Faculty of Medicine, St. Anna Teaching
Hospital
In 1952, the Department of Sports Medicine was established, which was based in the Faculty
Hospital and closely followed at the II. internal clinic of LF MU. The Clinic of Sport Medicine of St.
Anna Teaching Hospital was established in 1983. The workplace was managed by Prof. MUDr. Jiří
Polčák, DrSc., at that time already the head of II. Internal Clinics (1947 - 1971), from 1952 to 1963.
Department of Sports Medicine carried out teaching of students of medicine and also therapeutic
and preventive activity under the vice-head of MUDr. Karel Kocnar (1953 - 1963).
Doc. MUDr. Vladimír Dražil, CSc. was the head of the Dept. of Sports Medicine from 1963 to
1983 and his vice-head for medical and preventive activities was MUDr. Karel Kocnar (1963-1983).
Doc. MUDr. Vladimír Dražil, CSc. continued as the head of the Department until 1988. A part of the
important staff of the clinic during this period was doc. MUDr. Jiří Rouš, CSc. (died 1985).
Figure 1: Doc. MUDr. Vladimír Dražil, CSc., Head 1963 - 1988
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Figure 2: Doc. MUDr. Jiří Rouš, CSc.
In 1981, the Institute of Sports Medicine Prague was created from the Dept. Sports Medicine in
Brno and the head was MUDr. Drahuška Blahová, anthropologist Marie Řezníčková, nurse Marie
Sobková, who became a leading sister and later replaced by Olga Nezbedová.
In 1988 Prof. MUDr. Zdeněk Placheta, DrSc. became the head of the Department of Sports Medicine
of and his vice-head for therapeutic and preventive activities was MUDr. Dušan Vítek (1983-1992).
The department of Sports Medicine, Faculty of Medicine, Masaryk University, performed pedagogical
activities - teaching of students of the Faculty of Medicine in the field of sports medicine, medical and
preventive activities in the field of sports medicine and research activities, including the worldwide
research program of the International Biological Program (IBM) in the 1970s.
Figure 3: Prof. MUDr. Z. Placheta DrSc., Head 1988 - 1996
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Figure 4: First row: Hrubá, M. Krainová, MUDr. J. Bušková, prof. MUDr. Z. Placheta, DrSc.,
MUDr. D. Blahová, MUDr. K. Kočnar, L. Třasoňová, A. Kotulánová, A. Pásková,
second row prof. MUDr. J. Novotný, CSc., MUDr. I. Dohnalová, CSc., O. Korvasová, N. Tomanová,
doc. MUDr. V. Dražil, MUDr. D. Vítek, RNDr. K. Čechovský, 1988
Professor Placheta contributed to the renaming of the Dept. of Sports Medicine to the Dept. of
Functional Diagnostics and Sports Medicine in 1991, in connection with organizational and economic
changes in Czech health care. Thanks to the quality of results of his work and the modern concept
of the content, based on the concept of Scandinavian clinical physiology and other experience from
other European countries and the USA, the Dept. earned under the leadership of Prof. Z. Placheta the
reputation of one of the best workplaces of its kind in the Czech Republic. The Department had 10
other doctors, the head nurse Věra Bednářová, later Ludmila Třasoňová and 10 nurses.
In 1996 Prof. MUDr. Jarmila Siegelová, DrSc. took over the management of Dept. of Functional
Diagnostics and Sports Medicine.
Figure 5: Prof. MUDr. Jarmila Siegelová, DrSc., Head of Dept. 1996 – 2007, Head of Dept. of Physiotherapy
and Rehabilitation 2005 - 2012
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Prof. MUDr. Jarmila Siegelová, DrSc. has been cooperating since 1966 with the scientists from
University of Tuebingen, Germany, with Professor Karel Brecht and Professor Hans Riecker and
Prof. Dr. Nguyen-Duong Hoang, from 1970s with Professor Jean-Paul Martineud and Professor E.
Savin at the Faculty of Medicine in Paris, France, from 1980s with Professor Franz Halberg and
Professor Germaine Cornélissen of the University of Minnesota, USA, from 1990s with Professor
Thomas Kenner of the University of Graz, Austria. All these collaborations she has transferred to the
Department of Functional Diagnostics and Sports Medicine. Thus, two to three annual international
scientific symposiums, conferences and workshops were organized by Prof. Siegelová.
In 2000 Rector of Masaryk University awarded the nomination of Doctor Honoris Causa to
Professor Franz Halberg, University of Minnesota, USA, and Professor Thomas Kenner, University
of Graz, Austria.
Figure 6: Ing. H. Paperlein, Prof. MUDr. J. Siegelová, DrSc., Prof. Dr. Nguyen-Duong Hoang, Prof. Dr. H.
Rieckert, I. Paperlein, University Tübingen, Germany
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Figure 7: Professor Jean-Paul Martineaud, *27.3.1931-†29.11.2010, Faculty of Medicine, Paris, France
Figure 8: Professor Franz Halberg, M.D., Ph.D., Dr. h. c. multi, July 5, 1919 – June 9, 2013,
University of Minnesota, USA
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Figure 9: Prof. Dr. G. Cornélissen, University of Minnesota, USA, Director, Halberg´s Chronobiologic Center,
University of Minnesota, USA (2002)
Figure 10: Prof. Dr. Thomas Kenner, M.D., Dr. h.c. mult., Dean of Faculty of Medicine, Rector of University,
University Graz, Austria
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Figure 11: Awards of the title of Doctor Honoris Causa from Prof. RNDr. J. Zlatuška, CSc., Rector of Masaryk
University to Professor F. Halberg, USA and Professor T. Kenner, Austria (Brno 2000)
Figure 12: Professor Franz Halberg, Professor Thomas Kenner, Prof. MUDr. Jarmila Siegelová, DrSc. (2000)
NONINVASIVE METHODS IN CARDIOLOGY 2017
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Since 1997 Prof. MUDr. Petr Dobšák, CSc. has been working at the Department of Functional
Diagnostics and Rehabilitation and he continued his earlier co-operation with Professor Jean-Eric
Wolf and dr. Jean-Christoph Eischer and co-operation with Japanese scientists. In the Department
of Functional Diagnostics and Rehabilitation there were given lectures from Prof. Kou Imachi, Dipl.
Eng., PhD, University of Tokyo, Prof. Masaki Anraku, MD, PhD, University of Tokyo, Prof. Yusuke
Abe, MD, PhD, University of Tokyo, Prof. Atsushi Baba, MD, PhD, University of Tokyo, Associate
Prof. Itsuro Saito, Dipl.Eng., PhD, University of Tokyo, Associate Prof. Takashi Isoyama, Dipl. Eng.,
PhD, University of Tokyo, Prof. Kozaburo Hayashi, Dipl. Eng., PhD, University of Osaka, Prof. ShinIchi
Nitta, MD, PhD, Tohoku University Sendai, Prof. Makoto Tamai, MD, PhD, Tohoku University
Sendai, Prof. Masahiro Kohzuki, MD, PhD, Tohoku University Sendai, Associate Prof. Yusuke Inoue,
Dipl. Eng., PhD, Tohoku University Sendai, Prof. Kouji Shirai, MD, PhD, Toho University Chiba, Dr.
Kazuhiro Shimizu, MD, PhD, Toho University Chiba, Msc. Akihiro Ogawa, PhD, Toho University
Chiba, Japan, and this continued in the Department too.
The Department of Functional Diagnostics and Rehabilitation continued to perform pedagogical
activities - teaching students of the Faculty of Medicine in the field of internal medicine, since 1995 in
bachelor‘s study of Physiotherapy, medical and preventive activities in the field of internal medicine,
diagnostics of cardiovascular, respiratory and metabolic diseases and sports medicine.
Figure 13: Prof. J.E. Wolf, Dijon, France (2008)
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Figure 14: Prof. Dr. Masario Kohzuki, Sendai, Japan
The Department of Sports Education and Rehabilitation organized international symposia,
workshops and congresses every year, 2-3 times a year, attended by foreign colleagues from medical
faculties and universities. These activities have led to a number of joint scientific publications and
monographs.
Figure 15: From the right MUDr. P. Homolka, Ph.D., MUDr. P. Vank, Prof. MUDr. B. Fišer, CSc., L.
Tařsoňová, Prof. Dr. F. Halberg, MUDr. V. Zatloukal, CSc., Dr. O. Schwartzkopff, MUDr. J. Dušek, CSc., Prof.
MUDr. J. Siegelová, DrSc., Prof. Dr. V. Chromý, DrSc., Prof. MUDr. J. Novotný, CSc. (1996)
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Figure 16: MUDr. K. Kočnar, Prof. MUDr. Z. Placheta, DrSc. (1997)
Figure 17: Doc. MUDr. V. Dražil, CSc., Prof. MUDr. Z. Placheta, DrSc. (1997)
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Figure 18: Prof. MUDr. Z. Placheta, DrSc., Doc. MUDr. J. Máčková, CSc., Prof. MUDr. J. Siegelová, DrSc.,
Prof. MUDr. J. Vítovec, CSc. (1997)
Figure 19: Doc. MUDr. T. Kára, Ph.D., Prof. MUDr. P. Dobšák, CSc., Prof. MUDr. M. Kučera, DrSc. (1997)
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Figure 20: Prof. MUDr. J. Siegelová, DrSc., Prof. Dr. F. Halberg, d.h.c. multi, MUDr. J. Dušek, CSc. (2002)
Figure 21: Prof. Dr. G. Cornélissen, Prof. MUDr. J. Siegelová, DrSc. (2002)
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Figure 22: From the right Prof. Dr. G. Cornélissen, Dr. O. Schwartzkopff, Prof. F. Halberg, Prof. H. Illnerová,
DrSc., President of AV ČR, Prof. MUDr. J. Siegelová, DrSc. (2002)
Figure 23: From the right Prof. MUDr. J. Siegelová, DrSc., Prof. Dr. F. Halberg, Prof. MUDr. B. Fišer, CSc.,
MUDr. P. Homolka, Ph.D., Prof. Dr. G. Cornélissen, sitting Dr. O. Schwartzkopff, Prof. Dr. M. Havelková, DrSc.
(2003)
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Figure 24: From the left Prof. MUDr. B. Fišer, CSc., Prof. Dr. T. Kenner, B. Kenner, Doc. MUDr. M. Pohanka,
Ph.D., Dr. O. Schwartzkopff, Prof. Dr. F. Halberg, MUDr. J. Dušek, CSc., Prof. MUDr. J. Siegelová, DrSc.
(2008)
Department of Rehabilitation
Medical rehabilitation at St. Anna Teaching Hospital was performed since the 1950s, first on
orthopedics, later on in neurology, internal medicine and in other disciplines. Separate Rehabilitation
Department was established in 1965 and the head of the Rehabilitation Department was at first MUDr.
Silvio Koenig (born in 1923, died 1993) from 1965 to 1985. The department had 3 more physicians
and 20 physiotherapists.
Prim. MUDr. Jitka Svobodová was the head of the Department from 1985 to 1997. The Department
of Rehabilitation managed all physiotherapists (41) who had previously joined the clinics and provided
rehabilitation care in all clinical disciplines. The first head of the physiotherapist staff was Helena
Juráková, whose function was later taken over by Marie Falberová.
The important change of the Rehabilitation Department occurred in November 1992, when a
bed unit was created. Bed unit No 23 had at the beginning 20 beds, later this number increased to
32 beds, which until now served to complete the early rehabilitation of clinical disciplines, mainly
neurosurgery, orthopedics, neurology, surgery. Jarmila Georgová worked as a station nurse with the
staff of 14 other nurses and 4 physiotherapists.
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Physiotherapy is an integral part of the therapy of all clinical disciplines in St. Anna Teaching
Hospital.
Figure 25: Prim. MUDr. Jitka Svobodová, Head, Dept. of Rehabilitation 1985 – 1997, 1997 – 2009 Vicehead of
the Department
Department of Functional Diagnostics and Rehabilitation LF MU, St. Anna Teaching Hospital
On 1.10.1997 the Dept. of Functional Diagnostics and Rehabilitation was established from the
Dept. of Functional Diagnostics and Sports Medicine and from the Department of Rehabilitation. The
reasons for the establishment of the Dept. were the teaching of a bachelor‘s study of physiotherapy,
which had a new possibility of pedagogical activity within the Faculty of Medicine of Masaryk
University.
The Dean of Faculty of Medicine MU Prof. MUDr. Jiří Vorlíček, CSc. and the director of St. Anna
Teaching Hospital in Brno, MUDr. Alena Štětková, CSc. supported the establishment of the Dept. of
Functional Diagnostics and Rehabilitation.
Head of the Department of Functional Diagnostics and Rehabilitation was Prof. MUDr. Jarmila
Siegelová, DrSc., her vice-heads for therapeutic preventive activity were MUDr. Jitka Svobodová and
MUDr. Pavel Homolka, Ph.D. (until 2002), the head nurse was Ludmila Třasoňová (until 2002) and
head physiotherapist Marie Falberová (until 2009), station nurse Eva Vránová.
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Figure 26: From the left MUDr. L. Bednařík, Prof. MUDr. J. Siegelová, DrSc., MUDr. A. Štětková, CSc.,
Director of St. Anna Teaching Hospital, Prof. MUDr. J. Vorlíček, CSc., Dean of Faculty of Medicine MU, Prof.
MUDr. Z. Placheta, DrSc. (1.10.1997)
Figure 27: From the left MUDr. J. Svobodová, Prof. MUDr. J. Siegelová, DrSc., MUDr. A. Štětková, CSc.,
Director of St. Anna Teaching Hospital, Prof. MUDr. J. Vorlíček, CSc., Dean of Faculty of Medicine MU, Prof.
MUDr. Z. Placheta, DrSc., Prof. MUDr. J. Novotný, CSc., MUDr. P. Homolka, Ph.D. (1.10.1997)
NONINVASIVE METHODS IN CARDIOLOGY 2017
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Figure 28: From the left MUDr. L. Bednařík, Prof. MUDr. J. Siegelová, DrSc., MUDr. A. Štětková, CSc.,
Director of St. Anna Teaching Hospital, Prof. MUDr. J. Vorlíček, CSc., Dean of Faculty
of Medicine MU(1. 10. 1997)
Figure 29: Staff of the Department 1. 10. 1997
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Figure 30: 1.10.1997 the staff of the Department of Functional Diagnostics and Rehabilitation
Figure 31: 1.10.1997 the staff of the Department of Functional Diagnostics and Rehabilitation
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Figure 32: 1.10.1997 the staff of the Department of Functional Diagnostics and Rehabilitation
Figure 33: From the left L. Třasoňová, Prof. MUDr. Z. Placheta, DrSc., Prof. Dr. J.P. Martineaud, Paris,
France, B. Kenner, Prof. Dr. T. Kenner, Graz, Austria, vice-head MUDr. J. Svobodová (1997)
NONINVASIVE METHODS IN CARDIOLOGY 2017
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Figure 34: From the left Prof. MUDr. J. Siegelová, DrSc., B. Kenner, Prof. Dr. T. Kenner, Graz, Austria (1997)
Figure 35: Prof. E. Savin, M.D., Paris, France, Prof. MUDr. Jarmila Siegelová, DrSc.
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Figure 36: From the left MUDr. Pavel Homolka, Ph.D., MUDr. Jarmila Matějková, CSc., Prof. MUDr. Jarmila
Siegelová, DrSc., head nurse Ludmila Třasoňová, Doc. MUDr. Vladimír Dražil, CSc., nurse Marie Sobková,
MUDr. Drahuška Blahová, MUDr. Ilona Dohnalová, CSc. (2000)
Figure 37: From the left nurses R. Látalová, T. Slámová, D. Bulová, A. Kotulánová, E. Vránová, head
physioterapeutist M. Falberová (2002)
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Figure 38: Head physioterapeutist Marie Falberová, Prof. MUDr. Jarmila Siegelová, DrSc., Head of the
Department, , vice-head MUDr. Jitka Svobodová (2003)
In 1998, master‘s degree studies in physiotherapy were starting. The first graduates of the bachelor‘s
program of Physiotherapy at the Faculty of Medicine continued the studies in the master program.
The study of physiotherapy was coordinated until 1998 by Ing. N. Lžičařová. Since 1998, Mgr.
L. Dunklerová has been coordinating the studies in physiotherapy, lectures, practical exercises and
clinical training in bachelor‘s and master‘s program studies in physiotherapy.
Mgr. L. Dunklerová in cooperation with prof. MUDr. J. Siegelová, DrSc. ensure repeated
accreditation of both forms of study at the level of the Ministry of Health and the Ministry of Education
in the Czech Republic.
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Figure 39: First graduates of bachelor‘s degree in physiotherapy in 1998
Figure 40: Commission for State Final Examination of the Bachelor‘s Degree 1998, composed of the
chairwoman of the commission Prof. MUDr. Jarmila Siegelová, DrSc., Members Doc. MUDr. Ivan Müller, CSc.,
MUDr. Jana Roubalová, MUDr., Bohumila Müllerová, MUDr. Jitka Svobodová, MUDr. Eva Drápelová, MUDr.
František Trkan
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In 1998, a detached workplace for outpatient rehabilitation of the Department of Fuctional
Diagnostics and Rehabilitation was opened, including a balneotherapy facility at the Institution of
NCO NZO at Vinařská, Brno. For the opening, MUDr. Alena Štětková, CSc., Director of St. Anna
Teaching Hospital and the director of NCO NZO MUDr. Petr Svačina, CSc. with the support of the
Rector of Masaryk University and Dean of the Faculty of Medicine, significantly contributed by their
cooperation to the new establishment.
Figure 41: From the left MUDr. P. Svačina, CSc., Director of NCO NZO, Prof. MUDr. J. Vorlíček, CSc., Dean
of LF MU, MUDr. A. Štětková, CSc., Director of St. Anna Teaching Hospital, Prof. MUDr. J. Siegelová, DrSc.,
MUDr. J. Svobodová (1998)
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Figure 42: Staff of the Department 1998
Figure 43: From the left MUDr. H. Svačinová, Ph.D., JUDr. J. Jahodářová, MUDr. A. Štětková, CSc., Director
of St. Anna Teaching Hospital, MUDr. P. Svačina, CSc., Director of NCO NZO, MUDr. J. Svobodová, Prof.
MUDr. J. Siegelová, DrSc., Prof. RNDr. J. Zlatuška, CSC., Rector of MU (1998)
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Figure 44: From the left M. Penčikovová, MUDr, D. Blahová, Doc. MUDr. V. Dražil, CSc., JUDr. Jahodářová,
MUDr. P. Homolka, Ph.D., T. Slámová, E. Vránová, Prof. MUDr. P. Dobšák, CSc., M. Benešová, Doc. MUDr. J.
Jančík, CSc. (1998)
Figure 45: From the left MUDr. P. Homolka, Ph.D., Prof. MUDr. Z. Placheta, DrSc., head nurse of St. Anna
Teaching Hospital, Prof. MUDr. Z. Brázdová, DrSc., Prof. MUDr. J. Zlatuška, DrSc., Rector of MU, MUDr. A.
Štětková, CSc., Director of St. Anna Teaching Hospital, Prof. MUDr. J. Vorlíček, CSc., Dean of LF MU, Prof.
MUDr. J. Siegelová, DrSc., L. Třasoňová (1998)
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In 2000, the Department of Rehabilitation Care, St. Anna Teaching Hospital was established; its
head was MUDr. Jiří Pazdírek (2000 - 2005) and since 2005 until now MUDr. Marcela Nováková; the
rehabilitation staff of this facility belonged to the Dept. of Functional Diagnostics and Rehabilitation
until 2010; teaching for Bachelor‘s and Master‘s of Physiotherapy was performed there since 2000.
The Department of Functional Diagnostics and Rehabilitation also educated a number of scientific
and pedagogical staff of physiotherapy, who achieved Ph.D., habilitation and professor degrees in
the field of internal medicine and physiotherapy, not only at Masaryk University, but also at Charles
University in Prague.
From 1998 the cardiovascular rehabilitation program of outpatients was realized under Prof. MUDr.
Jarmila Siegelová, DrSc. in the Department of Functional Diagnostics and Rehabilitation.
It was one of the results of successful cooperation with Swiss Cardiovascular Center in Bern,
Switzerland, led by Prof. H. Saner.
Figure 46: Prof. Hugo Saner, M.D., Ph.D., Swiss Cardiovascular Center in Bern, Switzerland
In 2000, rebuilding of the building E, where the Department of Functional Diagnostics and
Rehabilitation was situated, under the full activities was realized.
There were built new spaces for cardiovascular rehabilitation and a new lift in the building.
This reconstruction was realized at that time under the head Prof. MUDr. J. Siegelová, DrSc.
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Figure 47: Dr. J.CH. Eicher, Dijon, France, Doc. MUDr. Jiří Jančík, Ph.D., MUDr. J. Svobodová (2003)
In 2005, the Department of Physiotherapy and Rehabilitation was established by the management
of the Faculty of Medicine of Masaryk University, whose task is to organize and provide teaching in
the field of Physiotherapy in Bachelor‘s and follow-up Master‘s Studies.
From 2005 to 2012, Prof. MUDr. Jarmila Siegelová, DrSc. was Head of the Department of
Physiotherapy and Rehabilitation of the Medical Faculty of MU. During the academic year, our
Department taught students with the aid of about 150 teachers who worked in St. Anna Teaching
Hospital and out patients rehabilitation workplaces. Numbers of students fluctuate every year from
180 to 200.
Prof. MUDr. Petr Dobšák, CSc. became Head of the Dept. of Functional Diagnostics and
Rehabilitation in 2007.
Prof. MUDr. Petr Dobšák, CSc. started in 1997 as a lecturer, was appointed Associate Professor
(habilitated) in 2004 and Professor in 2007; he replaced Prof. MUDr. Jarmila Siegelová, DrSc., who
continued in the clinic as a professor.
Vice-head for healing and preventive care of Prof. MUDr. Petr Dobšák, CSc. was first MUDr. Jitka
Svobodová, who was replaced later by the vice-head MUDr. Michaela Sosíková, Ph.D. from 2008.
The head physiotherapist was Marie Falberová until 2009, from 2009 Mgr. Pavlína Svobodová.
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Figure 48: Prof. MUDr. Petr Dobšák, CSc.,
Head of Department of Functional Diagnostics and Rehabilitation from 2007 until now
Head of Department of Physiotherapy and Rehabilitation from 2012 until now
Figure 49: Vice-head MUDr. Michaela Sosíková, Ph.D., from 2008 until now
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Figure 50: Prof. MUDr. Zdeněk Placheta, DrSc., MUDr. Jitka Svobodová, Marie Falberová, MUDr. Anna
Rajdová, MUDr. Michaela Sosíková, Ph.D., MUDr. Pavel Homolka, Ph.D. and staff (2007)
Figure 51: Prof. MUDr. Petr Dobšák, CSc., Prof. MUDr. Jan Žaloudík, CSc., Dean of Faculty of Medicine
(2007)
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Figure 52: Marie Falberová, Prof. MUDr. Petr Dobšák, CSc., Prof. MUDr. Jarmila Siegelová, DrSc. (2007)
In 2010, the Department of Functional Diagnostics and Rehabilitation was renamed to the
Department of Sports Medicine and Rehabilitation of Faculty of Medicine, MU, with place of business
at St. Anna Teaching Hospital.
In 2012 Prof. MUDr. Petr Dobšák, CSc. became Head of the Department of Physiotherapy and
Rehabilitation of LF MU.
Prof. MUDr. Jarmila Siegelová, DrSc. managed the Operational Program „Modifying a system
of education in the field of physiotherapy in the field of Education for Competitiveness, funded from
European sources, from 2012 to 2014. The project has been successfully completed.
Figure 53: The research team of the Operational Program in the field of Education for Competitiveness
„Modification of the system of education in the field of physiotherapy“
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Department of Sports Medicine and Rehabilitation continues to perform pedagogical training in
general medicine (internal medicine), physiotherapy and rehabilitation, teaching together with the
Department of Physiotherapy and Rehabilitation.
In 2014, Bachelor‘s program of Physiotherapy was started in English and the first graduates
successfully completed their studies in 2017.
In the field of treatment and preventive activities, the Department of Sports Medicine and
Rehabilitation performs excellent rehabilitative treatment at the acute beds clinic, at the other clinics
of St. Anna Teaching Hospital in Brno, in the field of outpatient treatment and in the field of sports
medicine and functional diagnostics of cardiovascular and respiratory diseases.
Figure 54: First State Final Examination in English: From the left Prof. MUDr. P. Dobšák, CSc., Bc. Eli
Odnozopov, Bc. Tessa Bell, Prof. MUDr. J. Siegelová, DrSc., MUDr. E. Drápelová, Doc. MUDr. I. Müller, CSc.
(2017)
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Figure 55: Graduates of the Bachelor‘s degree in Physiotherapy 2017
In the field of scientific research, international scientific research projects have been solved
together with scientists from Halberg Chronobiology Center, University of Minnesota, USA, Faculty
of Medicine, Paris, Dijon, France, Tohoku University of Sendai, University of Tokio, Japan, University
of Graz, Austria and other European countries. Detailed information on the scientific publications of
the Department of Sports Medicine and Rehabilitation, Masaryk University can be found in the World
Databases of Web of Science, Scopus, Medline, Faculty of Medicine, Masaryk University and the
Halberg Chronobiology Center, University of Minnesota, USA.
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Dr Othild Schwartzkopff (18. 5. 1922 - 23. 5. 2017) Halberg
Chronobiology Center University of Minnesota, USA
Jarmila Siegelová, Germaine Cornélissen*
Dept. of Physiotherapy and Rehabilitation, Dept. of Sportsmedicine and Rehabilitation,
Faculty of Medicine, Masaryk University, St. Anna´s Teaching Hospital, Brno
*Halberg Chronobiology Center, University of Minnesota, USA
It is with great sadness for us that Othild Schwarzkopff passed away on May 23, 2017 at the age of 95.
Dr. Othild Schwarzkopff will be remembered as an outstanding clinical physician and from the
mid-1990s as a scientist in chronobiology at the Halberg Chronobiology Center in Minnesota, USA.
Dr. Othild Schwartzkopff was born on 18 May 1922 in Germany and received her medical degree in
1946 at the University of Goettingen. After her clinical training in hospital she worked in the Pediatrics
Department of the General Hospital in Rheydt / Rheinland and later in the Children’s Tuberculosis
Institute in Aprath / Rheinland until 1958.
Dr. Othild Schwarzkopff moved to Canada in 1958. She worked in different hospitals and finally
she held the position of a pediatric resident at Vancouver General Hospital. She was licensed in British
Columbia. In 1963, Dr. Schwartzkopff became a Member of the College of Physicians and Surgeons.
In July 1968, she received her license to practice in the USA and moved to Minnesota. Dr. Othild
Schwartzkopff became a Fellow of the American Academy of Pediatrics (FAAP) in April 1971. From
1968 to 1988, she was in general pediatric practice in St. Paul, Minnesota, USA. During her last years
in practice, she held a clinical academic position in the Pediatrics Department at the University of
Minnesota. There as a clinical assistant professor of pediatrics, she introduced second-year medical
students to the problems they might face in practice.
In the mid-1990s, Dr. Schwartzkopff joined the Halberg Chronobiology Center, where she served
as the Clinical Director. She already had an interest in the cardiovascular system and chronobiology
when in 1945, for her dissertation on “The effects of nicotinic acid and nicotinic acid amide on the
cardiovascular system, blood pressure in particular”. In the field of chronobiology she measured the
blood pressure at about the same time each day, covering usually at least a week on each patient.
She provided also ambulatory blood pressure monitoring on herself over some years. She collected
also data that are now of interest in a transverse way for looking at about half-weekly and weekly
components of biological rhythms in healthy subjects and patients. As part of the BIOCOS Project,
Othild Schwarzkopff has indeed participated in many studies, with collaborators around the world,
as attested by her over 270 publications and her numerous invitations to lecture abroad, notably
here in Brno, but also in Austria, China, India, Russia, Saudi Arabia, Slovakia, Taiwan, Turkey and
Vietnam, among others. She visited our Masaryk University very often together with prof. Franz
Halberg and she presented new results in chronobiologic studies. Some scientific presentations were in
every year organized by Jarmila Siegelova as MEFA Congresses in Brno, in Noninvasive Methods of
Cardiology Congresses, in Workshops in Masaryk University. On the personal contact she discussed
the chronobiology question with the other regular partipitans in Congresses in Masaryk University
in Brno, namely with prof. Dr. Thomas Kenner, D.h.c. mult,, Rector emeritus of University in Graz,
Brigitte Kenner, late Prof. Dr. Jean Paul Martineaud, Faculty of Medicine, Paris, late Prof. Dr. Bohumil
Fiser, Masaryk University, Minister of health (2000-2002) in Czech Republic and our scientific team
(Dr. Jiri Dusek and prof. Siegelova) from Masaryk University. From 2011, she took part in every
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year scientific Workshops and Congresses with International participation via video-transmission. In
2008 Dr. Othild Schwartzkopff was presented at the proclamation of Brno consensus of Vascular
Variability Disorders. Prof. Franz Halberg proposed this evaluation based on over 61 years lasting
chronobiologic scientific studies on blood pressure and heart rate, together with professor Germaine
Conelissen, Dr. Othild Schwarzkopff and in cooperation with chronobiologists around the world and
Dr. Othild Schwartzkopff was a hard working woman, with great organizational abilities, who was
able to manage the social life in the laboratory environment, home hospitality, offered for the scientist
who visited the Halberg Chronobiology Center and an excellent scientist and medicine doctor.
Prof. Franz Halberg and Dr. Othild Schwarzkopff, together with prof. Germaine Cornelissen, give
very important message, which reflects that one of the important tasks of the Halberg Chronobiology
Center is the prevention of cardiovascular diseases, namely to screen blood pressure and heart rate for
Vascular Variability Anomalies, and while using the information from longitudinal records to learn
more about influences from our environment near and far, striving for a unified science.
The paper is amplified from: Cornelissen G, Beaty L, Siegelova J, Otsuka K, Watanabe Y, Singh
RK, Singh R, Singh RB, Kenner B, Kenner T. Obituary: Dr. Othild Schwartzkopff: 18 May, 1922 – 23
May 2017. World Heart J 2017; 9 (2): in press.
Figure 1: Dr. Othild Schwarzkopff 18. 5. 1922 - 23. 5. 2017
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Figure 2: Professor Franz Halberg, Dr. Othild Schwartzkopff during MEFA Congress in Brno 2005 organized by
Prof. MUDr. Jarmila Siegelová, DrSc.
Figure 3: Dr. Othild Schwartzkopff during Noninvasive Methods in Cardiology Congress in Brno 2002
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Figure 4: Dr. Othild Schwartzkopff with Brigitte Kenner, Dr. Jiri Dusek and Prof. MUDr. Jarmila Siegelová,
DrSc., Casle Rájec near Brno, Congress Noninvasive Methods in Cardiology, October 2005
Figure 5: Professor Bohumil Fišer, As. Professor Michal Pohanka, Professor Thomas Kenner, Brigitte Kenner,
Dr. Othild Schwartzkopff , Professor Franz Halberg, Dr. Jiří Dušek, Professor Jarmila Siegelová, Brno Congress
Noninvasive Methods in Cardiology, 2008 (Brno Consensus)
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Figure 6: Othild Schwartzkopff, M.D., prof. Franz Halberg, M. D., Dr. h. c. multi., Prof. MUDr. Jarmila
Siegelová, DrSc., Dr. Jiri Dusek, Brigitte Kenner, Prof. Thomas Kenner, M. D., Dr. h. c. multi., Austria –
videoconference in Brno Masaryk University, 2012
Figure 7: Professor Franz Halberg, Dr. Othild Schwartzkopff, Professor Germaine Cornélissen in Halberg
Chronobiology Center University Minnesota on May 3-4, 2013 during Symposium (videoconference) in Masaryk
University Brno with participation of Professor Kenner and Brno team from Department of Physiotherapy and
Rehabilitation
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Figure 8: Dr. Othild Schwartzkopff at the site of Battle at Austerlitz near Brno, 2004
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The Meaning of Acute Changes of Cardio Ankle Vascular
Index
Kazuhiro Shimizu1
, MD. PhD. Akihiro Ogawa2
, PT. MSc. and Kohji Shirai1
, MD. PhD.
1
Department of Internal medicine, Toho University Sakura Medical Center, Japan
2
Department of Rehabilitation, Toho University Sakura Medical Center, Japan
Key word
CAVI, Arterial stiffness
Summary
The cardio-ankle vascular stiffness index (CAVI) reflected vascular aging, and the progression of
atheroscrlosis. Furthermore, CAVI was observed to change relatively short term. When nitroglycerin
was administered, CAVI decreased in five minutes, indicating CAVI reflected the state of arterial
smooth muscle cell contraction. We observed that CAVI of the people living 300 km far away from
the center of big disaster of earthquake and tsunami, increased rapidly. And after that, the incidence
of brain hemorrhage and death rate increased in the town. We also observed the several cases whose
suffered from coronary artery disease, or aortic dissection and brain hemorrhage, increased CAVI
just before those accidents. In considering those, we proposed the hypothesis “the smooth muscle
contraction theory for the vascular accident”. Here, we want to discuss the meanings of rapid changes
of CAVI.
Introduction
In 2006, a new arterial wall stiffness parameter, the cardio-ankle vascular stiffness index (CAVI),
was developed. CAVI is a parameter that reflects the stiffness of the aorta, femoral artery, and tibial
artery as a whole. (1) The conspicuous feature is independency from blood pressure at measuring
time. The stiffness shown by CAVI was thought to comprise organic stiffness and functional stiffness.
Organic stiffness is mainly concerned with collagen, elastinhyaluronic acid, calcification and intimal
thickening with smooth muscle cell proliferation, whereas functional stiffness is mainly due to smooth
muscle cell contraction (Fig 1). In this paper, to understand the meaning of rapid changes of CAVI,
the effect of nitroglycerin administration, and the changes of CAVI of the people suffering from huge
earthquake, and those of several case sufferings from cardio-vascular events were studied. Finally, we
discussed those results and presented the new hypothesis for the occurrence of cardiovascular events.
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Figure 1: CAVI detect the organic stiffness and the functional stiffness
I. Effect of nitroglycerin administration on cardio-ankle vascular index. As shown in Fig. 2, we
reported that arterial stiffness shows acute changes by nitroglycerin (NTG) for both healthy people and
atherosclerotic people. After resting for 10 minutes in supine position on a bed, CAVI was measured at
baseline. Next, a tablet of NTG (0.3mg) was administered sublingually and CAVI was measured every
5 minutes for 20 minutes using a Vasela 1500 (Fukuda Denshi, Tokyo, Japan). Simultaneously, BP and
heart rate (HR) were measured by Vasela 1500.
The purpose of this study was to clarify the difference between effects of NTG on the functional
stiffness in patients with and without coronary artery disease (CAD) using CAVI.
To date, several reports have discussed the effect of NTG on arterial stiffness using PWV. However,
as shown in the current study, BP decreased after NTG administration. Thus, even when PWV
decreased, it cannot be concluded that NTG actually decreased the arterial stiffness, because PWV
decreases when the BP decreases. 1 On the other hand, CAVI is independent from BP at the time of
measurement. Taken together, the effect of the drugs which affect BP on the proper arterial stiffness
can be evaluated using CAVI. In this study, CAVI decreased in both healthy young adults and in CAD
patients after NTG administration. This is the first report to demonstrate the effect of NTG on proper
arterial stiffness of the artery, in vivo.
CAVI at the baseline might indicate the state of organic stiffness as atherosclerosis. After taking
NTG, decreased CAVI (ΔCAVI) might indicate relaxation of smooth muscle cell contraction. In another
words, functional stiffness might be due to the state of contracture of arterial smooth muscle cells.
After NTG administration, the stiffness of the arteries from the origin of the aorta to the ankle as
measured by CAVI decreased in both healthy volunteers and CAD patients by nearly the same extent,
suggesting that the response of the arterial smooth muscle cell to nitric oxide is preserved even in CAD
patients under medications.
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Figure 2: The effect of nitroglycerin administration to CAD patients and healthy people
II. A huge earthquake hardened arterial stiffness monitored with CAVI. It is known that the
frequency of cardiovascular events increases just after a huge earthquake.
On March 11th
, 2011, an earthquake of magnitude 9.0 occurred on the Pacific coast of Tohoku,
Honshu Island, Japan, at 14:46 local time (the Great East Japan Earthquake). It was followed by a series
of powerful aftershocks, with 31 earthquakes of magnitude larger than 6 in 3 days. As shown in Figure
1, our institute (Toho University Sakura Medical Center Hospital) was situated about 300 km away
from the epicenter. The building was strongly shaken, and part of a wall collapsed. An unusual crisis
occurred in our town. Shimizu et al. reported that arterial stiffness was increased by psychological
stress (Fig 3). Psychological stress caused the increase of death (Fig 4).
The Great East Japan Earthquake provided an unusual opportunity to investigate the relationship
between emotional stress and arterial stiffness. The Great East Japan Earthquake increased CAVImonitored
arterial stiffness in both healthy people and patients with cardiovascular risk factors,
whereas blood pressures did not change significantly. We investigated the incidence of death rates in
our town. As shown in Fig. 4, the number of deaths in our town in the following month (April 2011)
increased compared with that in April during several previous years. And the number of patients,
who were hospitalized into our hospital with acute coronary syndrome, takotsubo cardiomyopathy,
and cerebral bleeding just after the earthquake. The acute increase in arterial stiffness might be an
important risk factor for cardiovascular morbidity and mortality after a big disaster. This finding could
play a key role in solving the cause of cardiovascular events after a disaster.
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Figure 3: A huge earthquake hardened arterial stiffness monitored with CAVI
Figure 4: Psychological stress caused the increase of death
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III. The changes of CAVI in patients suffering from cardio-vascular events.
We met several cases whose CAVI was enhanced relatively short term, and suffered from cerebral
infarction, dissecting aneurysm, acute myocardial infarction and cerebral bleeding (Fig 5). Those
might just happen by chance. But, there might remain some possibility that this is not by chance, but
by some causal relationship. The latter possibility will discussed in the next chapter.
Figure 5: ΔCAVI raise might be a sign of cardiovascular events in the near future
IV. Arterial smooth muscle cell contraction theory for the occurrence of cardio-vascular events
To explain the process that enhanced ΔCAVI just before the cardiovascular events, might be the
trigger of following cardio-vascular events, we considered arterial smooth muscle cell contraction
theory for the occurrence of cardio-vascular events as illustrated in Fig 6.
Atherosclerotic changes occurred mainly in intimal layer. In this process, organic stiffness was
increased. That was reflected to enhanced CAVI. At this stage, vasa vasorum were developed in
atheromatous lesion from the adventitia and penetrated medial smooth muscle layer. Thus, nutrition
in atheromatous lesion was supplied by vasa vasorum. When CAVI was enhanced further in relatively
short term, this means that medial smooth muscle cells begin to contract and to choke the vasa vasorum.
Then, atherosclerotic lesion become ischemic state, and easily undergo necrosis. Then, plaque rupture,
dissecting aneurysm and hemorrhage occurred from this necrotic core.
Based on this theory, continuous monitoring CAVI might be very important and useful predictor of
cardiovascular events. To prove this hypothesis, we are now under investigation from various aspects.
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Figure 6: Arterial smooth muscle cell contraction theory
Conclusion
CAVI is not only a good surrogate marker of atherosclerosis, but also a good moritoring index
of life style-related diseases such as hypertension, diabetes mellitus, dyslipidemia, visceral obesity.
Furthermore, enhanced CAVI during continuous monitoring might be an advance warning for the
cardiovascular events.
Acknowledgement
We deeply appreciated prof. PETR DOBSAK and prof. JAMILA SIEGELOVA.
References
	 1.	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.
	 2.	Shimizu K, Yamamoto T, Sato S, Takahashi M, Noike H, Shirai K. Effect of nitroglycerin
administration on cardio-ankle vascular index. Vascular Health and Risk Management. 2016;
2:313—319.
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	 3.	Shirai K, Song M, Suzuki J, et al. Contradictory effects of β1-and α1-aderenergic receptor blockers
on cardio-ankle vascular stiffness index (CAVI)–CAVI is independent of blood pressure. J
Atheroscler Thromb. 2011;18: 49-55.
	 4.	Shimizu K, Takahashi M, Shirai K. A huge earthquake hardened arterial stiffness monitored with
cardio-ankle vascular index. J Atheroscler Thromb. 2013; 20:503-11.
	 5.	Trichopoulos D, Zavitsanos X, Katsouyanni K, Tzonou A, Dalla-Vorgia P. Psychological stress and
fatal heart attack: the Athens (1981) earthquake natural experiment.Lancet. 1983; 321:441–444.
	 6.	Dobson AJ, Alexander HM, Malcolm JA, Steele PL, Miles TA. Heart attacks and the Newcastle
earthquake. Med J Aust. 1991; 155:757-761.
	 7.	Leor J, Poole WK, Kloner RA. Sudden cardiac death triggered by an earthquake. N Engl J Med.
1996; 334:413-419.
	 8.	Shimizu K, Takahashi M and Shirai K. A huge earthquake hardened arterial stiffness monitored
with cardio-ankle vascular index. J Atheroscler Thromb,2013;20:503-511
	 9.	Shimizu K, Yamamoto T, Shirai K. Arterial stiffness, as monitored by cardio-ankle vascular index,
is affected by obstructive sleep apnea, blood glucose control and body weight -a case of 8 years
follow up-. International Medical Case Reports Journal. 2016; 9:231-235.
NONINVASIVE METHODS IN CARDIOLOGY 2017
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NONINVASIVE METHODS IN CARDIOLOGY 2017
63
Acute Effect of Resistance Training on Cardio-Ankle Vascular
Index (Cavi)
1
Ogawa A, 2
Shimizu K, 2
Shirai K.
1
Department of Rehabilitation, Toho University Sakura Medical Center, Japan
2
Department of Internal medicine, Toho University Sakura Medical Center, Japan
Key words
Cardio-ankle vascular index, arterial stiffness, resistance training, atherosclerosis,
Introduction
Pulse wave from the heart is very important role of our homeostasis. Therefore elasticity of the
aorta plays an important role to keep vascular functions. Vascular dysfunction has been shown to play
a central role in arteriosclerosis. Cardio-Ankle Vascular Index (CAVI) makes it possible to determine
non-invasively arteriosclerosis 1). Dobsak et al. reported that CAVI was significantly improved by
12 weeks exercise and muscle contraction stimulation for heart failure patients. However, there is no
report about the immediate change of the CAVI after resistance training2). The aim of this study was
to investigate correlation about functional stiffness and skeletal muscle mass after resistance training
(RT).
Subjects
The subjects were 21 healthy adult males (Table 1).
Table 1: Characteristic of experimental subjects
Methods (experimental methods and design)
The study was conducted in a quiet environment and temperature-controlled room (25°C–26°C).
The subjects were examined at approximately the same daytime after a standardized light meal and
NONINVASIVE METHODS IN CARDIOLOGY 2017
64
were asked to avoid caffeine or tobacco on the day of the study. At baseline, CAVI was measured in
supine position after 10min rest. Next, all the subjects performed 10-times of RT exercises on right leg.
Then, CAVI was measured immediately after RT and 5min later (Figure 1).
Figure 1: Procedure of resistance training and experimental protocol
CAVI was measured using device VaSera®
1500 (Fukuda Denshi Co., Ltd, Tokyo, Japan).
The changes of stroke volume (SV) and cardiac output (CO) were continuously monitored using
hemodynamic monitoring system Aesculon®
(Osypka Medical, California, USA). The evaluation of
skeletal muscle mass and body composition was done by bioelectrical impedance analyzer Inbody®
770 (Inbody Co., Ltd., Seoul, South Korea). Skeletal muscle mass index (SMI) was calculated using
limb skeletal muscle mass and body height as follows:
SMI = limb skeletal muscle mass / height (m)2
Statistics
Each parameter was evaluated from three measurements using Friedman test. In the case of
significant difference; Steel-Dwass test was used for post hoc multiple comparisons. Mann-Whitney
test was used to compare change of CAVI (ΔCAVI) for difference between right (Rt) and left (Lt) value
of CAVI. Relationship between CAVI and SMI was examined by partial correlation adjusted for age.
Significance level was set at P<0.05. SPSS Statistics (version 21) was used for data analysis.
Results
Continuous measurement by impedance cardiography showed that HR was increased until the end
of RT. HR peaked within 30sec after the end of RT, and then decreased. On the other hand, there was
no obvious change in the SV. Thus, the change in CO was dependent on HR (Figure 2).
NONINVASIVE METHODS IN CARDIOLOGY 2017
65
Figure 2: Changes in cardiac output
There was no significant change in either diastolic and systolic blood pressure (Table 2).
Table 2: Changes in blood pressure at each measurement time
CAVI in both Rt (exercise side) and Lt (non-exercise side) decreased significantly after RT (6.00 vs.
5.80, P<0.01; 6.00 vs. 5.80 P<0.01, respectively), and returned to the CAVI value registered at baseline
after 5min (5.80 vs. 6.00 P<0.01; 5.70 vs. 6.00 P<0.01, respectively). This result is shown in Fig.3. There
was no significant difference in the ΔCAVI between Rt and Lt (Table 3). Both Rt and Lt CAVI and SMI
showed significant negative correlation (r=-0.59; P<0.05). This result is shown in Fig.4.
NONINVASIVE METHODS IN CARDIOLOGY 2017
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Figure 3: Changes in CAVI at each measurement time
Table 3: Comparison of ΔCAVI
NONINVASIVE METHODS IN CARDIOLOGY 2017
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Figure 4: Relevance of CAVI and SMI
Discussion
This study analyzed the acute change of CAVI before and after a bout of resistance training.
Similar changes were observed on both exercising and non-exercise side. One previous trial reported
that CAVI was reduced immediately after aerobic exercise (3), and in the present study we found
similar results. However, our study brought a new insight because the CAVI changes were promoted
by resistance training (and in one leg only). This observation might demonstrate the systemic effect
of nitric oxide (NO) activation by exercise (4). Shimizu et al. (2016) showed similar changes of CAVI
after administration of nitroglycerin (5). There was also the relevance between CAVI and SMI.
Sampaio et al. (2014) found a decreased SMI and increased CAVI in a group of community-dwelling
elderly, where CAVI was shown to be an independent factor of skeletal muscle mass (6). It is likely
that vascular elastic function plays an important role in blood flow of skeletal muscles. The present
study has several limitations. First, all involved subjects were healthy males, and not patients with
cardiovascular diseases. Secondly, due to technical limitations, it was not possible to measure the
changes of nitric oxide production.
Conclusion
Increased peripheral blood flow promoted by isometric contractions, can improve the systemic
vascular functional stiffness. The present study showed that partial (one-leg) resistance training may
contribute to the decrease of vascular stiffness. From this point of view, this study has fundamentally
contributed to clarify the effect of exercise on vascular functional stiffness.
NONINVASIVE METHODS IN CARDIOLOGY 2017
68
Acknowledgement
We deeply appreciated the assistance from Professor Petr Dobsak and Professor Jarmila Siegelova.
References
	 1.	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; 13:101–7.
	 2.	Dobsak P, Tomandl J, Spinarova L et al. Effects of neuromuscular electrical stimulation and aerobic
exercise training on arterial stiffness and autonomic functions in patients with chronic heart failure.
Artif Organs 2012; 36(10):920-930.
	 3.	Zhixiong Z, Zan H, Minshao Y et al. Longer rest intervals do not attenuate the superior effects of
accumulated exercise on arterial stiffness. Eur J Appl Physiol 2015; 115:2149–2157
	 4.	Maiorana A, O‘Driscoll G, Taylor R, Green D. Exercise and the nitric oxide vasodilator system.
Sports Med 2003; 33(14):1013-35.
	 5.	Shimizu K, Yamamoto T, Sato S et al. Effect of nitroglycerin administration on cardio-ankle
vascular index. Vasc Health Risk Manag 2016;12: 313-19.
	 6.	Sampaio RA, Sewo-Sampaio PY, Yamada M et al. Arterial stiffness is associated with low skeletal
muscle mass in Japanese community-dwelling older adults. Geriatr Gerontol Int 2014 ; 14(1):109-
14.
NONINVASIVE METHODS IN CARDIOLOGY 2017
69
Different Chronotherapy Protocols Applied to Blood Pressure
Germaine Cornelissen1
, Yoshihiko Watanabe2
, Jarmila Siegelova3
, Jiri Dusek3
, Alena Havelkova3
,
Leona Dunklerova3
, A. Chase Turner1
, Larry Beaty1
, Kuniaki Otsuka3
1
Halberg Chronobiology Center, University of Minnesota, Minneapolis, MN, USA
2
Tokyo Women‘s Medical University, Daini Hospital, Tokyo, Japan
3
Masaryk University, Brno, Czech Republic
Dedicated to the memory of Franz Halberg
Abstract
Blood pressure serves both as a marker variable and as a gauge of the response to timed treatment
(chronotherapy). The relative merits of several transverse and longitudinal chronotherapy designs are
reviewed herein, from small studies on groups and N-of-6 pilot studies to larger clinical trials. Some
chronotherapy designs are aimed at optimal results for the average patient in a given target population,
while others aim at personalized chronotherapy, where each patient in the study is considered as an
N-of-1 pilot. All chronotherapy trials considered herein relied on around-the-clock blood pressure
measurements obtained automatically to determine optimal treatment times. Because anti-hypertensive
medications can affect the circadian amplitude in addition to the rhythm-adjusted average (MESOR),
treatment effects should be assessed on all characteristics of the circadian blood pressure rhythm.
Because abnormal blood pressure and heart rate variability also relates to cardiovascular disease
risk, anti-hypertensive treatment should target not only the lowering of blood pressure, but also the
restoration of an acceptable circadian variation in blood pressure. Methods to analyze individual blood
pressure records makes it now feasible to determine personalized optimal treatment times. Outcome
studies remain to be performed to assess the gain to be obtained from personalized chronotherapy in
terms of an actual decrease in adverse cardiovascular events.
Keywords
Blood Pressure, Blood Pressure Variability, Chronotherapy, Circadian, Cosinor, Longitudinal
versus Transverse Design, Response Rhythm, Vascular Variability Disorders
Introduction
Circadian rhythms are in the spotlight now that a molecular basis has provided a mechanism for their
existence, the importance of which has just been recognized by the Nobel Assembly at the Karolinska
Institutet that awarded the 2017 Nobel Prize in Physiology or Medicine jointly to Jeffrey C. Hall,
Michael Rosbash and Michael W. Young “for their discoveries of molecular mechanisms controlling
the circadian rhythm”.
The term “circadian”, derived from the Latin “circa” (about) and “dies” (day), was coined in 1959
by Franz Halberg to indicate that circadian rhythms had a period of about 24 hours [1]. The meaning
of the term refers to free-running and the partly endogenous nature of circadian rhythms, their period
differing slightly but statistically significantly from 24 hours in the absence of environmental time cues
NONINVASIVE METHODS IN CARDIOLOGY 2017
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[2, 3]. It also indicates the statistical uncertainty in estimating the period: even under synchronized
conditions, circadian characteristics, including the period, cannot be estimated exactly, because of
measurement error and changes occurring from one day to another, as amply documented for blood
pressure [4, 5].
As shown by Halberg, circadian rhythms are ubiquitous; they characterize most, if not all, variables
across species, from archaea [6] to humans. In particular, his demonstration of circadian variation
in mitoses of different organs and tissues, and for different liver functions related to different stages
of the cell cycle, laid the foundation for cancer chronotherapy [7]. Broader applications followed his
demonstration of the hours of changing resistance to a host of external stimuli [8-13]. The physiological
response to stimuli (such as noise, bacterial endotoxins, radiation, and drugs) changes predictably as
a function of circadian stage. It is thus possible to optimize treatment by timing its administration in
order to maximize its effectiveness while minimizing its side effects. This is the principle underlying
timed treatment (chronotherapy).
Chronotherapy can make the difference between life and death
Timing, the critical ingredient of chronobiological designs, is not just another factor that can be
ignored. Under the standardized conditions of the laboratory, timing was repeatedly shown to tip the
scale between health and disease, and even between death and survival. This is the case for instance
in relation to the exposure of mice to the same dose of an adrenal cortical inhibitor (SU-4885) as a
function of circadian timing. In three experiments involving 70, 210, and 350 mice, tested at 6 different
circadian stages 4 hours apart in relation to the lighting regimen of 12 hours of light alternating with
12 hours of darkness, depending on the dosage, most if not all mice died when exposed late during the
light (rest) span, but most if not all survived when exposed to the same dosage of the same agent earlier
during the rest span, Figure 1.
Figure 1: In the experimental laboratory, inbred animals of the same strain, sex and age, receiving the same dose
of the same drug administered at one of 6 different circadian stages can either all survive or all die, depending
only on when the drug was administered. Timing is as important, if not more important than dosing. © Halberg
Chronobiology Center
The response to a single daily “meal” can also make the difference between life and death in a
mammalian model of potentially fatal interactions between hunger, cold and rhythms, namely the
singly-housed mouse abruptly restricted to a single daily “meal”. Most singly-housed mice (but not
multiply-housed mice) die when they have access to food for 4 hours during the first part of the light
(rest) span each day, but if food is only available during 4 hours in the early part of the dark (active)
span, most of the mice survive [14].
NONINVASIVE METHODS IN CARDIOLOGY 2017
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Blood pressure and blood pressure variability
Blood pressure varies greatly. It is characterized by a large-amplitude circadian rhythm in both
normotensive and hypertensive individuals [15, 16]. Circadian rhythm characteristics also usually
undergo large day-to-day variability [4, 5]. Abnormal variability patterns of blood pressure and heart
rate have been associated with an increased cardiovascular disease risk in several outcome studies,
beyond an elevated blood pressure itself [17, 18].
The circadian pattern of blood pressure, described by its rhythm-adjusted mean value, the MESOR
(Midline Estimating Statistic Of Rhythm), its double amplitude and acrophase, measures of the
predictableextentandtimingofchangewithin24hours,anditswaveform,determinedbycharacteristics
of harmonic terms, also differs between men and women, and undergoes predictable changes as
a function of age [19]. It thus made sense to derive time-specified reference limits (chronodesms)
computed as circadian-stage-dependent 90% prediction limits computed on the basis of data collected
from clinically healthy peers, separately for men and women in different age groups. Similarly, 90%
prediction limits were derived for each circadian parameter. A patient’s record can thus be compared
to these chronobiologic standards to determine whether the blood pressure profile is within acceptable
limits or not, based on both the 2-component cosinor model fitted to the data and on a computercomparison
of the patient’s record versus the chronodesmic limits of clinically healthy peers matched
by gender and age. Instead of the usual question whether blood pressure is too high or acceptable,
more informative questions can be answered, such as “for how long is blood pressure above the upper
limit of acceptability”, “what is the total amount of blood pressure excess” (estimated as the area
delineated by the record when it exceeds the time-specified upper 95% prediction limit and that limit),
and “when does most of the blood pressure excess occur” [20]. This approach by “sphygmochron”
[20] goes beyond the concept of the blood pressure load [21], as illustrated in Figure 2. Whereas both
patients have a similar percent time elevation (or blood pressure load versus time-specified limits),
blood pressure excess (or hyperbaric index, HBI) is more than three times larger for patient #2 than for
patient #1 (764 vs. 231 mmHg x hour over 24 hours).
	
Figure 2: The percentage time elevation of blood pressure above time-specified reference limits can be very
similar between two patients but fail to convey the larger risk of patient #2 whose blood pressure reached much
higher values than those of patient #1. The difference is better represented by the hyperbaric index, the area of
excess delineated by the blood pressure record when it is above the upper limit of acceptability and the limit itself.
© Halberg Chronobiology Center
Since the availability of monitors for the automatic measurement of blood pressure, several protocols
have been designed and used by us to assess the merits of timed-treatment (chronotherapy) of an
NONINVASIVE METHODS IN CARDIOLOGY 2017
72
elevated blood pressure and other blood pressure abnormalities, the vascular variability disorders [17,
18]. Some of these study designs are described below to highlight their respective relative merits.
Blood pressure chronotherapy
Optimization of Prazosin in patients with idiopathic hypertension
The first optimization of an anti-hypertensive medication by timing designed by Franz Halberg
in cooperation with Frederick C Bartter and Hans-Georg Güllner was published in 1979 [22, 23].
The study involved only 10 patients, but its design is impeccable. The anti-hypertensive treatment
tested was the once-daily administration of prazosin, an α1-blocker which acts as an inverse agonist
at alpha-1 adrenergic receptors. These receptors are found on vascular smooth muscle, where they are
responsible for the vasoconstrictive action of norepinephrine. Prazosin had a plasma half-life of about
1.5 hours [23].
One important feature of the study design relates to the standardization of experimental conditions.
The patients were admitted to a metabolic ward and fed constant diets; they were kept recumbent
during the entire study to eliminate the effects of posture and physical activity on blood pressure. Since
blood pressure can decrease by hospital admission itself, patients were monitored for 3 days before the
start of intervention.
Another critical aspect of the study was the use of one of the first available automatic blood
pressure monitors, the Roche “Arteriosonde”, an analog device that needed calibration of both blood
pressure and time, the measurements being recorded as dots on moving paper that had to be manually
transcribed into numerical values and entered on punched cards for computer analysis. The drawback
of small measurement errors introduced in the process was greatly overshadowed by the merit of
obtaining data around the clock without the need to wake-up and disturb the study participants. Data
were collected automatically every 30 minutes for the entire duration of the study.
Most importantly, the study followed a double-blind, placebo-controlled design. Every patient received
one capsule, either active drug (1 mg prazosin) or placebo, every 4 hours for 7 days. Only one prazosin
capsule was given every day. The time of prazosin administration was delayed by 4 hours every day.
Results showed a decrease in blood pressure by 5 to 12 mmHg (systolic) and 6 to 7 mmHg (diastolic),
the greatest lowering observed when prazosin was administered at midnight. When given at 08:00 or
at 12:00, prazosin was effective in lowering blood pressure for 24 hours, but when given at 04:00, it
only lowered blood pressure for 13 hours. The results thus indicated that the effect and duration of
prazosin’s action depended not only on dosage, but also on the time of its administration [22, 23].
The only caveats are the fact that treatment at a given circadian stage lasted only one day (to keep
the length of the study manageable), and that the study endpoints were limited to an effect on blood
pressure itself without consideration for any modification of the circadian variation in blood pressure.
These limitations are fully understandable since these data were among the first to be collected
automatically around the clock. Very little, if any, information was available regarding the day-today
variability in the circadian rhythm characteristics of blood pressure, or about vascular variability
disorders and their relation to cardiovascular disease risk.
Comparison of presumed optimal chronobiologic timed treatment versus conventional dosing
Another chronotherapy protocol aimed at treating at the anticipated optimal circadian stage, based
on the circadian blood pressure profile and the pharmacokinetics of the anti-hypertensive drug used
[24, 25]. In this approach, results from the sphygmochron [20] are used as a guide to time treatment,
which targets the time of peak drug action to the time of highest blood pressure excess.
NONINVASIVE METHODS IN CARDIOLOGY 2017
73
This design from Dr. Rina Zaslavskaya was tested by her versus conventional treatment at the time,
which consisted of dosing three times a day. The anti-hypertensive drugs tested were propranolol,
clonidine, and α-methyldopa. Propranolol is a β-blocker. It appears in the blood after 30 minutes and
has a maximum effect between 60 and 90 minutes when taken by mouth. Clonidine is classified as a
centrally acting α2
-adrenergic agonist and imidazoline-receptor agonist that has been in clinical use
for over 40 years. Effects of α-methyldopa start around 5 hours after administration and last about a
day.
One feature of this design is that it is cost-effective since it consists of only two arms: the
chronotherapy arm and the conventional (control) arm. One limitation of this design is that there is
no verification that the selected treatment time is indeed the optimal time to treat. Since these trials
also anti-date knowledge about vascular variability disorders, target endpoints included a lowering of
the average blood pressure but not any effect of blood pressure variability or the circadian variation
in blood pressure. Despite these shortcomings, results were very positive. As compared to oncetraditional
treatment three times a day, chronotherapy (applied 1.5 to 2 hours before the daily blood
pressure peak, determined by around-the-clock measurements for the preceding 3 days) needed less
drug to lower blood pressure more and faster, and was accompanied by fewer complications and less
over-dosage [24, 25], Figure 3.
	 Figure 3: A predicted best time, based on the pharmacokinetics of the drug and on the chronodiagnosis,
was compared with treatment as usual (taken 3 times a day in equal doses). The chronobiologic timing was
determined in such a way as to target the time of highest efficacy of the drug to match the time of highest blood
pressure values predicted by model fitting. With all 3 drugs tested (propanolol, clonidine, and α-methyl-dopa), a
larger reduction in the blood pressure MESOR was achieved with a smaller dose, resulting in fewer side effects
(the latter not shown). Data of R Zaslavskaya. © Halberg Chronobiology Center
Pilot N-of-6 studies
Before undertaking large clinical trials, it is often cost-effective to first proceed with smaller pilot
studies aimed at determining the optimal circadian stage at which to administer a given treatment.
Such pilot studies can be as small as N-of-6 studies, wherein 6 different circadian stages are tested,
equally distributed along the 24 hours, or at least during the waking span from the time of awakening
to bedtime. To yield reliable results, it is important that study participants be a random sample of the
target population and that they be randomly assigned to the different treatment times.
One such N-of-6 pilot study tested effects of low-dose aspirin on blood coagulation and also on blood
pressure [26]. As shown in Figure 4, the effect of low-dose (100 mg/day) aspirin on lipoperoxides in
NONINVASIVE METHODS IN CARDIOLOGY 2017
74
platelet-rich plasma was highest when administered shortly after the time of awakening and lowest 9 and
12 hours after awakening. Similar results were found for an effect of low-dose aspirin on lymphocyte-βadrenoceptors
[26]. The circadian stage-dependent response of these two variables to low-dose aspirin,
assessed by the fit of a 24-hour cosine curve to the treatment-versus-reference difference assigned to
the time of treatment administration, was statistically significant in each case (P<0.05). Low-dose
aspirin was also found to have a circadian stage-dependent effect on blood pressure. In this case, the
blood pressure lowering was greatest in the afternoon and evening, Figure 5 [27].
	
Figure 4: The response of lipoperoxides is seen by plotting the 2-day around-the-clock profile obtained after
1-week treatment with low-dose aspirin for comparison with a similar profile obtained before treatment.
© Halberg Chronobiology Center
Provided there is a marked effect of the tested intervention and that its effect has a marked circadian
stage-dependent response, N-of-6 pilots can be very useful. In the case of low-dose aspirin, its effect
on blood pressure assessed in this N-of-6 pilot was later confirmed based on a much larger population,
yielding similar results [28]. One caveat, however, relates to the limited statistical power associated
with the small number of study participants.
	
Figure 5: The effect on blood pressure can differ from that on blood coagulation. Low-dose aspirin reduces
the blood pressure MESOR most when it is administered in the afternoon, rather than shortly after awakening.
© Halberg Chronobiology Center
NONINVASIVE METHODS IN CARDIOLOGY 2017
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Pilot N-of-1 studies
Ultimately, preference should be given to N-of-1 investigations since they underlie personalized
optimization of treatment, recognizing that every patient is different. Individualized chronotherapy is
made feasible by the availability of ambulatory blood pressure monitors for the automatic collection
of around-the-clock measurements, preferably for longer than 24 hours, and of statistical methods for
the analysis of data thus obtained.
Parameter tests [29] detect differences in the MESOR, amplitude, and acrophase tested either jointly
or separately. It is thus possible to determine whether treatment at one circadian stage is preferable to
treatment at a different circadian stage. This is illustrated in Figure 6 [30]: Diltiazem hydrochloride
(240 mg) taken daily around 04:30 during an interruption of sleep, as compared to after awakening
around 08:30, by a 75-year old hypertensive man was associated with both a lowering of the MESOR
of systolic blood pressure from 147.7 ± 2.1 to 141.7 ± 1.0 mmHg (P=0.017) and a reduction of the
double circadian amplitude from 34.2 ± 6.0 to 19.6 ± 3.0 mmHg (P=0.039). The reduction in circadian
amplitude is thought to have been beneficial since before switching the treatment time 4 hours earlier,
the circadian amplitude was above the upper limit of acceptability.
Figure 6: The same dose of the same anti-hypertensive medication (Diltiazem HCl) can lower the blood pressure
MESOR to a larger extent, and it can also reduce an excessive circadian amplitude of blood pressure when given
at one rather than at another circadian stage. The difference in effect can be assessed for the individual patient
by means of parameter tests. © Halberg Chronobiology Center
The self-starting cumulative sum (CUSUM) control chart [31] can be used to assess the effectiveness
of a given intervention for the individual patient. In this approach, a break-out of one of the two (upward/
downward) CUSUM curves outside the decision interval (shaded band) indicates that a statistically
significant change (increase/decrease) in the endpoint examined took place. Following the CUSUM
curve backwards to the time when it first deviates from zero provides an estimate of when the change
started to take effect. As opposed to applications in industry, in medicine the start of treatment is known
(recorded) and if this time coincides with the time when the CUSUM line first departs from zero, then a
causal relation may be assumed [32]. An example is provided in Figure 7 (top). The MESOR of systolic
blood pressure of a man newly diagnosed with hypertension decreases, starting almost immediately
once anti-hypertensive treatment is started, but the efficacy of the treatment is only detected after a
couple of weeks [33]. Figure 7 (bottom) indicates that when anti-hypertensive medication is taken
NONINVASIVE METHODS IN CARDIOLOGY 2017
76
daily in the evening, the circadian amplitude of systolic blood pressure is increased. Since this patient
already had an excessive circadian amplitude of blood pressure, evening dosing should be avoided.
Methodologic considerations for the design of clinical trials: transverse versus longitudinal design
Studies on groups of patients are best designed to include more than two test times. In other words,
more than two circadian stages at which to administer the anti-hypertensive medication need to be
considered. Depending on the response rhythm to the given treatment, selecting two treatment times
about 12 hours apart, such as morning and evening, may correspond to the midline crossing of the
response rhythm. If so, no difference will be detected, even if benefit could be derived from treating at
a different circadian stage [34, 35].
It is also recommended to measure blood pressure around the clock so that the circadian variation
can be assessed. Indeed, treatment can also affect the amplitude and/or acrophase of the circadian
rhythm in blood pressure, in addition to lowering the MESOR. If this is the case, measuring blood
pressure always at the same clock hour may yield inaccurate results and even opposite results when
measurements are taken at another time [36]. Some, but not all anti-hypertensive medications affect
the circadian amplitude of blood pressure [37, 38].
Figure 7: The same dose of Diovan HTC (80/12.5) was taken at the same circadian stage for 17 days before
the treatment time was advanced by 3-4 hours. After all 6 circadian stages had been tested, the protocol was
repeated with shorter spans on each treatment time. As seen from the self-staring CUSUM, the initiation of
treatment was effective in bringing about a statistically significant decrease in the MESOR of systolic blood
pressure, the effect being detected after about one month. When treatment was taken in the evening, it was
associated with a statistically significant increase in the circadian amplitude of blood pressure. © Halberg
Chronobiology Center
One example of a small clinical trial using six different test times between 08:00 and 18:00 enrolled
24 presumably normotensive individuals, who were randomly assigned to one of six times to undergo
periodontal surgery [13]. Blood pressure was measured around the clock by ambulatory monitoring on
three occasions, bracketing dental visits. Periodontal surgery was performed on the last visit. Whereas
the blood pressure of patients undergoing periodontal surgery in the morning increased in response
to the intervention, the blood pressure of patients similarly treated in the afternoon decreased. The
NONINVASIVE METHODS IN CARDIOLOGY 2017
77
blood pressure response to periodontal surgery was shown to be circadian stage-dependent by one-way
ANOVA and by cosinor, a 24-hour cosine curve being fitted to the difference in blood pressure
associated with the dental procedure (P<0.05) [13].
In the above study, the design was transversal, since different patients were assigned to different
circadian stages at which periodontal surgery was to be performed. The same recommendations of
considering more than two treatment times and to automatically measure blood pressure around the
clock to assess the response to treatment also apply to longitudinal designs. In longitudinal studies,
patients serve as their own control, and each patient in such clinical trials can also be considered as
different N-of-1 cases. Doing so allows the personalized optimization of treatment while still deriving
average results for the target population.
Clinical trials are usually based on a transversal design. While only average results for the population
can be derived from this approach, one advantage is that patients can be kept in their respective arms
of the study for as long as desired. When followed-up over a sufficiently long time for adverse events
to have occurred, the data are amenable to logistic regression estimating any benefit to be derived not
just in terms of the marker variable (usually blood pressure lowering) but also in terms of actual target
organ damage.
Examples of chronotherapy trials based on a longitudinal design
Clinical trials based on a longitudinal design have thus far been limited to assessing benefit derived
in terms of changes in the marker variable(s) (blood pressure and heart rate). Outcome studies focused
on benefits to be derived in terms of the incidence of actual adverse cardiovascular events will need to
first determine for each patient the optimal treatment regimen, then compare the occurrence of adverse
events between patients thus treated chronobiologically versus similar patients treated conventionally,
without consideration of timing, since the optimal treatment time will differ among patients.
In longitudinal designs, the optimal duration of treatment on any administration time has not yet
been determined. It should be long enough for its full effect to have taken place, but not too long to
avoid interference from other sources, such as the modulation of the circadian blood pressure rhythm
by the circannual variation.
In one trial, the time of administration of Micardis (Telmisartan, an angiotensin II receptor
antagonist), with or without low-dose aspirin, was changed every day [39]. In this cross-over, doubleblind,
randomized study, 20 MESOR-hypertensive patients were recruited. The study consisted of three
stages (placebo, Micardis, and Micardis with low-dose aspirin), each lasting 7 days. The treatment was
administered each day at a different circadian stage, 3 hours apart, from the time of awakening to
bedtime. In addition to the lowering of blood pressure, Micardis was associated with a reduction of the
circadian amplitude of blood pressure, the effect being more pronounced when low-dose aspirin was
added to Micardis. While Micardis was most effective in decreasing blood pressure when taken 6 to
9 hours after awakening, it was concluded that monitoring over spans longer than one day on a given
regimen was required to reliably estimate the optimal treatment time [39].
In another trial, Hyzaar (Losartan/hydrochloride, an angiotensin II receptor antagonist combined
with a diuretic) was administered for at least one month at a given circadian stage to each of 30
hypertensive patients [40]. The time of treatment administration was changed during consecutive
spans to cover six treatment times from awakening to bedtime at approximately 3-hour intervals.
At the end of each span during which Hyzaar was taken at a given circadian stage, each patient
contributed a 7-day record of around-the-clock ambulatory blood pressure monitoring [40]. Overall, a
larger reduction of the MESOR of diastolic blood pressure was achieved when Hyzaar was taken in the
NONINVASIVE METHODS IN CARDIOLOGY 2017
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early morning for more patients, while treatment upon awakening was the best choice for most patients
to reduce the circadian amplitude of blood pressure the most. Importantly, the optimal treatment time
differed considerably among patients [40].
Discussion and Conclusion
Since abnormal blood pressure variability also relates to an increased cardiovascular disease risk,
chronotherapy of blood pressure should assess effects on all circadian characteristics, and not just on
the 24-hour average (MESOR). As noted above, not all anti-hypertensive drugs have an effect on the
circadian amplitude [37, 38]. Restoring an acceptable circadian blood pressure rhythm can be more
important than lowering the blood pressure MESOR to a larger extent. Evidence stems from a crossover,
double-blind, randomized study comparing the effect of two calcium channel blockers: benidipine
given once a day in the morning, and nifedipine given twice a day, in the morning and evening [41].
Whereas nifedipine lowered blood pressure to a larger extent than benidipine, only benidipine also
reduced the circadian amplitude of blood pressure. This effect on the circadian amplitude of blood
pressure is thought to account for the considerably lower incidence of stroke and overall cardiovascular
events in a large trial of benidipine [42] compared to outcomes from two other large clinical trials of
nifedipine (the STONE and Syst-China trials) [43, 44]. These trials were all performed in Asia where
an excessive circadian amplitude of blood pressure may be more prevalent and was associated with a
large increase in adverse outcomes [18].
In the experimental laboratory, treating at the optimal circadian stage was documented to prolong
survival [45], Figure 8. Chronotherapy of Temocapril, an angiotensin-converting enzyme (ACE)
blocker, led to more than the doubling of the survival time of salt-loaded, spontaneously hypertensive
stroke-prone (SHR-SP) rats. Animals treated daily early during the light (rest) span lived longer than
animals treated early during the dark (active) span.
Figure 8: The efficacy of anti-hypertensive drugs can also be optimized by timing, as shown here in terms
of the effect of Temocapril on the lifespan of stroke-prone Okamoto rats. Data of A Fujimura. © Halberg
Chronobiology Center
In the clinic, results from the Hyzaar trial show that individualized chronotherapy is estimated to
help more than half the patients in need of anti-hypertensive medication, when treatment is targeted
NONINVASIVE METHODS IN CARDIOLOGY 2017
79
to restore an acceptable circadian variation of blood pressure and heart rate. Intuitively, it makes
sense that the best time to treat will differ for a patient with an excessive circadian amplitude of blood
pressure (CHAT, short for Circadian Hyper-Amplitude-Tension) who has the largest blood pressure
excess in the afternoon than for a patient who has a reversed circadian variation of blood pressure
(ecphasia) who has the largest blood pressure excess at night. Ecphasia can occur in patients with noninsulin-dependent
diabetes mellitus complicated by autonomic nervous dysfunction [46].
Since patients can present with widely different circadian patterns of blood pressure and heart rate
as illustrated in a series of case reports [16], and thus with different combinations of vascular variability
disorders, it makes sense to adjust the timing of treatment (chronotherapy) to the chronodiagnosis. This
concept has been referred to as chronotheranostics [36].
In summary, in order to obtain a reliable chronodiagnosis, blood pressure needs to be measured
around the clock for longer than 24 hours, preferably for 7 days or longer. Chronotherapy should aim at
restoringacceptablecircadianrhythmsofbloodpressureinadditiontoloweringbloodpressure.Tailoring
chronotherapy to the chronodiagnosis implies personalization of treatment timing. Chronotherapeutic
designs should include treatment at 5 or 6 different circadian stages equally distributed over the active
span (from awakening to bedtime), if not over the full 24 hours.
The availability of monitors to automatically collect blood pressure data around the clock and of
methodsfortheiranalysisnowrendersitfeasibletotestmorethantwotreatmenttimes--theconventional
morning versus evening dosing -- in order to truly implement a personalized optimization of treatment
by timing. Further work is needed (1) to determine the duration of treatment at a given circadian
stage during the optimization stage, (2) to proceed with outcome studies comparing the incidence
of adverse cardiovascular events on personalized chronotherapy versus conventional treatment, and
(3) to determine modalities for the continued monitoring at intervals to ascertain that the prescribed
treatment regimen remains effective in maintaining acceptable circadian variation in blood pressure
and heart rate.
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Trial Of Nifedipine in the Elderly (STONE). J Hypertens 1996; 14: 1237-1245.
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(Suppl 2): S14.
Correspondence:
Germaine Cornélissen
Halberg Chronobiology Center
University of Minnesota, Mayo Mail Code 8609
420 Delaware St. S.E. Minneapolis, MN 55455, USA
TEL +1 612 624 6976 FAX +1 612 624 9989
E-MAIL corne001@umn.edu
Website: http://halbergchronobiologycenter.umn.edu/
Support:
Halberg Chronobiology Fund
University of Minnesota Supercomputing Institute
A&D (Tokyo, Japan)
NONINVASIVE METHODS IN CARDIOLOGY 2017
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Chronobiology, Mitochondria, and Cardiovascular Disease
Linda Sackett-Lundeen, Germaine Cornelissen
Halberg Chronobiology Center, University of Minnesota, Minneapolis, MN, USA
Abstract
Halberg defined chronobiology as the science objectively quantifying and investigating mechanisms
of biologic time structure, including rhythmic manifestations of life. The term is derived from: Chronos
meaning time, bios (life), and logos (science). Biological rhythms are essential to all living organisms.
Covering a wide range of frequencies, the circadian (about 24-hour) rhythm is manifested in both
health and disease. Circadian rhythms in all living organisms can be influenced or synchronized by
environmental factors, such as the lighting regimen and feeding schedule, but their partly endogenous
nature is now well documented at the molecular level. The suprachiasmatic nuclei (SCN) located in the
hypothalamus are considered by many to be the master clock that orchestrates the organism’s biological
rhythms, which are then carried out in almost every cell in the body by different parts of the cell. The
mitochondria consist of a double-membraned organelle where cellular metabolism takes place in a
rhythmic pattern. Most cells in the body need mitochondria for energy production. Some cells that
need lots of energy include those in muscle, kidney, and primarily heart. Circadian rhythm parameters
are useful gauges of health and disease risk. Alterations in circadian rhythm parameters (MESOR,
amplitude, and acrophase) related to cardiovascular diseases indicate mitochondrial dysfunction. In
order to evaluate the role of mitochondria in the heart and cardiovascular diseases, this review looks
into their mechanism and function, and reviews how chronobiology may help investigations of the role
played by mitochondria in cardiovascular diseases.
Keywords
ATP, Cardiovascular Disease, Cellular Energy, Chronobiology, Circadian Rhythm, Mitochondria
Chronobiology
Introduction
The knowledge of rhythms dates back to the very beginning of life on this planet. All living matter
and the evolving organisms were exposed to the earth‘s revolution around the sun with its periodicity
of day and night, light and darkness, with the periodic changes in the length of the daily light and
dark span in relation to the climatic changes of the seasons. In addition, some aquatic life forms
were exposed to the periodic input provided by the cycles of the moon with its influence on ocean
tides (Touitou & Haus, 1992). It was a necessity for all life forms (early in the beginning and even
later) to adapt to the periodically changing environment on our planet. The related periodic functions,
originally in response to environmental stimuli, may have impressed themselves on the genetic makeup
of living matter. Periodic variations, many but not all of which follow the frequencies of the periodic
environmental input, are found in the most primitive and ancient forms of life presently available for
study. Many other periodic functions, however, have no known environmental counterpart (Touitou &
Haus, 1992).
NONINVASIVE METHODS IN CARDIOLOGY 2017
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Biological rhythms are inherent to most if not all living organisms in one form or another and are
noted at all levels of biological organization, from intracellular processes, tissues, organs and organ
systems to the individual, populations, and the biosphere (Halberg, 1969; Halberg et al., 2001b). They
also span a broad frequency range, periods varying from milliseconds (activity of single neurons),
seconds(heartbeatandrespiration),hours(about90-minutebasicrest-activitycycle),todays(circadian),
weeks (circaseptan), and months (circatrigintan) to years (circannual) and even decades (Halberg et al.,
2001b). Probably the most widely known and understood is the circadian rhythm which plays a special
role ever since its partly endogenous nature was placed on a solid molecular basis and core clock genes
were shown to be implicated in major disease conditions (Cornélissen & Otsuka, 2017).
Many chronobiologists have investigated circadian and other rhythms in both health and disease
(Halberg, 1969; Halberg, et al., 2012; Haus et al., 1988, 2001; Lewy et al., 2007; Nicolau et al., 1989,
Singh et al., 2002; Sothern et al., 2009). Circadian rhythm parameters can be estimated by the least
squares fit of a 24-hour cosine curve with or without the addition of harmonic terms. They include
the MESOR (Midline Estimating Statistic Of Rhythm, the value midway between the highest and the
lowest values of the cosine function best fitting the data), the amplitude (half the predictable extent of
change within a cycle), and the acrophase (a measure of the timing of overall high values recurring in
each cycle), Figure 1. The period (τ), the duration of one complete cycle, reported in time units, is often
assumed to be 24 hours under 24-hour synchronized conditions. The MESOR equals the arithmetic
mean when data are equidistant and cover an integer number of cycles. The MESOR and amplitude
are expressed in the same units as the original data (i.e., blood pressure in mmHg), and the acrophase
is expressed in relation to the reference time as negative degrees (with -360° = period; 0° = reference
time).
Figure 1: Example of a cosine function for a complete 24-hour cycle, showing the MESOR, amplitude, and
acrophase of the best-fitting cosine curve. © Halberg Chronobiology Center
History of Chronobiology
Prehistoric man, the hunter and gatherer of food for the family, was familiar with the concept of time
and the environmental periodicities related to its passage. They may not have understood biological
NONINVASIVE METHODS IN CARDIOLOGY 2017
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rhythms, but they knew that there were times when they could hunt and gather food depending on the
time of the day and/or the changing of the seasons.
There are many references in the literature referring to periodicities as a function of time. In the
Bible the importance of temporal factors was recognized as stated in Ecclesiastes: “To everything
there is a season and a time to every purpose under the Heaven: a time to be born and a time to die; a
time to plant and a time to harvest.“ In Genesis, the first task of God was to create light and then the
alternation of light and darkness. Also the 7-day cycle of activity and rest is part of the story of creation
as presented in the Old Testament; the 6 days of work were followed by a day of rest. It is believed that
the Egyptian calendar was invented around 4200 BC (Touitou & Haus, 1992).
Ancient physicians already realized the presence of rhythms in certain aspects of disease, notably
rhythms of about 7 days, when they noticed that certain symptoms would either ease or worsen. Greek
physicians and naturalists (Aristotle, Hippocrates, Diocles) observed that some symptoms recurred
predictably according to patterns of about 7 days such as intermittent fevers. The life cycle of the
malarial parasite (Sanchez de la Peña et al., 1984) could now account for some of these observations.
Aristotle believed that the moon influenced reproductive functions and disorders that affected women.
He also believed the heart to be the organ that controlled sleep and awake times, contrary to Galen,
who felt that it was the brain. Hippocrates described that crises in diseases occurred at regular intervals
and that these intervals may be related to celestial body movements. Diocles figured the number 7
played an important role in the periodicities of health and disease (Touitou & Haus, 1992).
Aschoff (1974) suggested that the history of rhythm research began in 650 BC, when the Greek poet
Archilochus of Paros wrote “Recognize which rhythms govern man”. As noted by Halberg et al. (2001a),
a later fragment by Archilochus refers to the solar eclipse of 6 April 647 BC, which authenticates the
fragment on rhythm as dating from the seventh century BC, and identifies Archilochus as a lyric link
to both the study of rhythms and to that of the Sun.
In ancient days it was generally accepted that any cyclic changes in an organism represented
exclusively the effects of cyclic changes in environmental factors. Some of the first observations that
led to the recognition of the endogenous nature of certain periodicities were made in 1729 when the
French astronomer Jean-Jacques d’Ortous de Mairan reported that the daily changes in the position
of the appendages of the heliotrope plant, Mimosa pudica, whose inflorescences turn their rows of
flowers to the sun, persisted in continuous darkness (Robertson McClung, 2006). This observation was
followed in 1745 by the designation of a „flower clock“ by Carl Linnaeus (Carl von Linné), who showed
that at certain sun-related clock hours the flowers of some plant species are open while those of others
are closed (Touitou & Haus, 1992). When in 1832 Augustin Pyramus de Candolle, a Swiss botanist,
finally measured what de Mairan observed, he found that the leaf movement of Mimosa pudica not
only persisted in complete darkness, its period of 22-23 hours also free-ran from the environmental
24-hour cycle. De Candolle also showed that the leaf movements could be reversed by inverting the
light/dark schedule (Robertson McClung, 2006). These findings, probably not completely understood
by botanists at the time, were likely the first description of the partly endogenous nature of the about
24-hour rhythm that can be synchronized by the lighting regimen.
Many more discoveries were made since the 1800s. Julien-Joseph Virey in 1814 wrote his doctorate
thesis in Medicine on diurnal rhythms in health and disease in humans, were he emphasized the
importance of timed therapy (Touitou & Haus, 1992). Balfour (1815) tried to predict fevers according
to the lunar cycle and according to the timing of previous attacks and suggested that treatment should
be timed according to the expected occurrence of the next attack of the disorder (Touitou & Haus,
1992). In humans, Thomas Laycock proposed in 1842 that periodicity originated from within the
system („isoteric origin“) or was caused by periodic factors acting from without („exoteric origin“) or
NONINVASIVE METHODS IN CARDIOLOGY 2017
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by a combination of both („endoexoteric“) (Lavie, 1992). Edward Smith (1861) wrote a book “Health
and Disease: as Influenced by the Daily, Seasonal, and other Cyclical Changes in the Human System”,
where he reports on rhythms in health and disease, even stating in his Preface: “…that no work of
modern date exists in which the cyclical changes proceeding in the human system are described, or in
which even the influence of season is cited at any length in reference to the causation and treatment of
disease” (Smith, 1861). He reported a higher toxicity of ethanol in the morning and stressed that drug
effects are cycle-stage dependent. Smith (1861) also reported a circadian periodicity of time of death:
„death occurs much more frequently from 1 to 5 a.m. (Lavie, 1992).
In the 1900s, the field exploded with many new investigators with many new findings and studies
taking place. The 1960 symposium at Cold Spring Harbor Laboratory laid the groundwork for the field
of Chronobiology (Cold Spring Harbor Symposium, 1960). One physician who had started to study
changes as a function of time was the young Dr. Franz Halberg, who while counting mouse eosinophils
found that the counts depended on when the eosinophils were harvested in relation to the light/dark
regimen (Halberg & Visscher, 1950). Franz Halberg also deserves credit for recognizing the critical
importance of circadian rhythms in view of their partly endogenous nature and the difference they
make between life and death. It was not until around 1959 that the word circadian started to replace
24-hour periodicity. Franz Halberg wrote in 1959: “in discussions with Professor William McDonald
(and others) of the Department of Classics at the University of Minnesota, the term ‘circadian’ was
derived from ‘circa’ (about) and ‘dies’ (day); it may serve to imply that certain physiologic periods are
close to 24 hours, if not of exactly that length” (Halberg, 1959). By collecting a critical mass of data
documenting the ubiquity of circadian rhythms, by developing statistical methods for their analysis
and quantitative assessment, and by meticulously presenting a host of practical clinical applications,
Halberg laid the foundation for the new discipline of chronobiology (Cornélissen et al., 1989). The field
then started to explode, with many more researchers who contributed greatly to the field (for review,
see Touitou & Haus, 1992; Lemmer, 2009; Otsuka et al, 2016).
Much interest in circadian rhythms in recent years stems in part from the discovery of clock genes
that provided a molecular mechanism for their manifestation (Konopka & Benzer, 1971). While clock
genes reside in almost every cell, those in the suprachiasmatic nuclei (SCN) are thought by many
to be the most important since they may orchestrate the entire circadian system. The SCN is a tiny
region of the brain in the hypothalamus, situated directly above the optic chiasm. Apart from the core
Clock genes (Clock, Bmal1, Cry and Per), other genes continue to be discovered that participate in the
coordination of circadian rhythms. This is now an entire field of research since clock genes have also
been found to underlie a host of disease conditions (Mazzoccoli et al., 2012).
Chronobiology in Health & Disease
Even before attention was given to clock genes in relation to health and disease, circadian rhythm
characteristics served as markers of health in screening for disease and pre-disease. Time-specified
reference values in health from womb to tomb have been made available for blood pressure (Cornélissen
et al, 1992, 1993; Halberg et al., 1992, 1993), endpoints of heart rate variability (Otsuka et al., 1999),
hormones (Halberg et al., 1981; Haus et al., 1988), and biochemical variables (Haus et al., 1988).
Deviations from these chronobiologic norms have been shown to associate with disease conditions
(neurological, metabolic, endocrine and cardiovascular diseases) as well as with aging. Of interest
herein is the relationship between biological rhythms of different frequencies in cardiovascular disease
and mitochondrial function and/or dysfunction.
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Mitochondria
Introduction
Mitochondria are double-membraned organelles found in the cells of all eukaryotic organisms,
considered to be the power generators of the cell, converting oxygen and nutrients into adenosine
triphosphate (ATP). Siekevitz, in 1957, called the mitochondria the “powerhouses of the eukaryotic
cells”.
Besides supplying energy to the cell, mitochondria are involved in other tasks (McBride et al.,
2006): 1) signaling - part of any communication process that governs basic activities of cells and
coordinates all cell actions; 2) cellular differentiation - process where a cell changes from one cell
type to another; and 3) cell death or apoptosis - process of programmed cell death that occurs in
multicellular organisms. Mitochondria also help in maintaining control of: 1) the cell cycle - series
of events that take place in a cell leading to its division and duplication of its DNA to produce two
daughter cells; and 2) cell growth - biological cell development and cell division (reproduction).
Much was known about the mitochondrion as an organelle before it was determined that it also has
its part/assignment in the biologic rhythms of the organism. The mitochondrion is the organelle where
the final stages of cellular respiration occurs: i.e., the Kreb’s cycle and the electron transport chain.
The cells in the body that use a lot of energy have the highest numbers of mitochondria in them. In
particular, muscle cells in the heart need lots of energy all of the time. Whereas leg muscles can rest,
heart muscles are always working.
Mitochondria are the chief producers of ATP, which is the transporter of chemical energy for the
cell, to be used in metabolism. ATP is a small molecule nucleotide used in cells as a coenzyme and
a nucleotide used in the formation of DNA and RNA. It is often referred to as the „molecular unit of
currency“ of intracellular energy transfer that powers the cell‘s metabolic activities (Knowles, 1980).
The inner membrane of the mitochondrion is highly folded into cristae, which house the megadalton
complexes of the electron transport chain and ATP synthase involved in the basic rates of cellular
metabolism, Figure 2.
Figure 2: Structure of mitochondrion showing the outer porous membrane and the inner impermeable membrane
with cristae where ATP is produced (reproduced from Wikipedia)
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Chronobiology of Mitochondria
Circadian variations have been found in mitochondrial oxidative phosphorylation and coenzyme
Q10 (CoQ10) (Gvozdjáková et al., 2014). Cardiac function relies on a time-varying supply of oxidative
energy during the mitochondrial oxidative phosphorylation produced by mitochondrial respiration
(Kohsaka et al., 2014). CoQ10 is a fat-soluble substance, also in the mitochondria, that participates
in the cellular respiration process, generating energy in the form of ATP (Dutton et al., 2000). Both
circadian and circaseptan (about-weekly) variations in ATP have been documented by Ulmer et al.
(2001), Figure 3. CoQ10 is an antioxidant that is needed for basic cell function. CoQ10 concentrations
decrease with age and may be low in people with hypertension and other heart conditions, along
with other diseases. While continuously monitoring her blood pressure around the clock, one healthy
woman took CoQ10 daily, changing the timing of supplementation every 7 days, starting shortly after
awakening, then delaying administration time by about 3.5 hours every week until it was taken around
bedtime. Treatment time was then advanced weekly by about 3.5 hours. Figure 4 shows the circadian
stage-dependent effect of CoQ10 on the 24-hour amplitude of systolic blood pressure (SBP). When
CoQ10 was taken in the morning, the circadian amplitude of SBP was much larger than when the same
dose of CoQ10 was taken in the late evening. In this subject, evening dosing was desirable since her
circadian amplitude of SBP was excessive.
Figure 3: Time dependence of beta-ATP in L1210 leukemia cells (detrended data). Both the circadian and the
circaseptan components characterizing beta-ATP are statistically significant. Note that the 7-day amplitude is
much larger than the 24-hour amplitude. © Halberg Chronobiology Center
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Figure 4: Circadian stage-dependent effect of CoQ10 supplementation on the 24-hour amplitude of SBP
of a clinically healthy woman. © Halberg Chronobiology Center
Mitochondrial Function
McBride et al. (2006) suggested that the broader question remains regarding the underlying
purpose of mitochondrial dynamics and the translation of these morphological transitions into altered
functional output. One hypothesis is that mitochondrial respiration and metabolism may be spatially
and temporally coordinated by the architecture and positioning of the organelle. Recent evidence
supports and expands this idea by demonstrating that mitochondria are an integral part of multiple cell
signaling cascades. Interestingly, proteins such as GTPases, kinases and phosphatases are involved
in bi-directional communication between the mitochondrial reticulum and the rest of the cell. These
proteins link mitochondrial function and dynamics to the coordination of metabolism, cell-cycle
control development, antiviral responses and cell death (McBride et al., 2006).
History of Mitochondria
The earliest records of intracellular structures that most probably represent mitochondria date
back to the 1840s by Henle (Ernster & Schatz, 1981). In 1890, Altman described these structures
as occurring everywhere and called them “bioblasts”. He describes the “bioblasts” as “elementary
organisms living inside cells and carrying out vital functions” (Ernster & Schatz, 1981). In 1898, the
term “mitochondrion” was introduced by Carl Benda, from the Greek “mitos” meaning thread and
“chondros” meaning granule (Benda, 1898). In 1912, Benjamin F. Kingsbury was the first to relate the
mitochondrion with cell respiration, but his results were almost exclusively based on morphological
observations. In 1913, Otto Henrich Warburg took particles, which he called “grana” from extracts of
guinea-pig liver and linked them to respiration. Finally in 1925, David Keilin discovered cytochromes
and the respiratory chain was described. Some mitochondrial structure, i.e., the outer membrane, could
be seen under the light microscope, which was confirmed in 1945 by Claude and Fullam by electron
micrographs (Ernster & Schatz, 1981). It was not until the early 1950s that Palade (1952, 1953) and
Sjöstrand (1953a,b) published the first high-resolution electron micrographs of mitochondria. Palade’s
micrographs showed that the mitochondrial membrane is folded to form ridges which he called “cristae
mitochondriales” (Palade, 1952). Sjöstrand’s micrographs showed the double membranes inside the
mitochondrion that had divisions or septae in the inner chamber of the cell (Sjöstrand, 1953a,b). For a
detailed history of mitochondria, see Ernst and Schatz (1981).
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As reviewed elsewhere (Cornélissen et al., in press), chronobiological aspects of mitochondria were
studied at least since the 1960s. In the 1970s, circadian variations in mitochondria were investigated
by Heinz von Mayersbach (1983), Karl Philippens (1968, 1970, 1971, 1973) and their team, as they
used succinate dehydrogenase (SDH) as a marker enzyme to visualize mitochondria histochemically.
Biochemical studies figuring the mitochondria as the “powerhouse of the cell”, combined with the
unique evolutionary origin of the mitochondria, led the way to decades of research focusing on the
organelle as an essential, yet independent, functional component of the cell. Recently, however,
our conceptual view of this isolated organelle has been profoundly altered with the discovery that
mitochondria function within an integrated reticulum that is continually remodeled by both fusion and
fission events. The identification of a number of proteins that coordinate these activities is beginning
to provide mechanistic details of mitochondrial membrane remodeling.
Mitochondria in the Heart
Mitochondrial respiration takes place in the inner mitochondrial membrane in heart cells through
a series of metabolic reactions using oxygen and nutrients in the cell to produce ATP, the source of
energy in the cells (Gvozdjáková et al., 2014). About 90% of the ATP in the heart is produced from these
oxidation-reduction reactions in the mitochondria, with the mitochondria consisting of 20% to 40%
of the cardiomyocyte volume (Gvozdjáková et al., 2014). Gvozdjáková et al. (2014) showed in isolated
mitochondria of the heart muscle of rats that ATP production in the mitochondrial respiratory chain
in heart muscle and CoQ10 concentrations vary along the 24-hour scale (Gvozdjáková et al., 2014).
Changes in OXPHOS and CoQ10 myocardial mitochondria may be involved in the pathophysiology
of the heart muscle. A low CoQ10 concentration and an impaired OXPHOS in heart mitochondria are
considered to be a molecular basis for heart failure and can trigger an acute myocardial infarction,
cardiac arrest or stroke, all of which can end in sudden death (Gvozdjáková, 2008).
Chest pain associated with acute myocardial infarction is more prevalent in the second quarter
of the day (Singh et al., 2003). In addition, it has been known for some time that the onset of heart
failure, myocardial infarction, and sudden death is greatest in the early hours of the morning. There
are clinical implications of the circadian rhythms of hemostatic and related mechanisms that happen
during the morning hours. There is a morning rise in blood viscosity, vasoconstriction, vascular
response to norepinephrine, blood pressure, platelet activity, and blood coagulability/fibrin formation.
Parallel to these increases is a decrease in fibrinolytic activity. The combination of these events leads
to fibrin accumulation and a risk of thrombosis with cardiovascular and cerebrovascular accidents
and embolisms. In a group of patients, we were able to look at the circadian and circaseptan timing
of cardiac mortality and the incidence of primary intracerebral hemorrhage, Figure 5 (Nicolau et al.,
1991).
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Figure 5: Circadian (left) and circaseptan (right) variation of cardiac mortality and the incidence of
primary intracerebral hemorrhage (redrawn from Nicolau et al., 1991). © American Association for Medical
Chronobiology and Chronotherapeutics (AAMCC)
Cardiac function relies on a time-varying supply of oxidative energy produced by mitochondrial
respiration. Mitochondrial dysfunctions in the heart muscle are associated with both structural and
functional abnormalities (Kohsaka et al., 2014). Heart function relies on oxidative energy that is supplied
continuously by mitochondria. Because energy demand in the heart varies across the sleep/wake cycle,
timely supply of energy may benefit the heart and optimize its function. This time-dependent energy
metabolism is subject to the circadian clock system, in which a set of core clock genes plays a major
role. Without clock gene function, the daily rhythms in heart energy metabolism are impaired. Kohsaka
et al. (2014) showed that ablation of the circadian clock gene Bmal1 specific to the heart results in
cardiac mitochondrial defects, such as reduced enzymatic activities within the respiratory complex.
Mice lacking cardiac Bmal1 function show decreased expression of genes associated with the fatty
acid oxidative pathway, the tricarboxylic acid cycle, and the mitochondrial respiratory chain in the
heart; and they develop severe progressive heart failure with age. It has also been shown that similar
changes in gene expression related to mitochondrial oxidative metabolism occur in C57BL/6J mice
subjected to chronic reversal of the light-dark cycle, thus showing disrupted circadian rhythmicity.
These findings by Kohsaka et al. (2014) indicate that the circadian clock system plays an important
role in coordinating mitochondrial metabolism and thus also in maintaining intact cardiac function.
Mitochondria in Developing and Diseased Heart
The high-capacity mitochondrial system generates and consumes enormous amounts of ATP in
order to support the constant pumping function of the heart in response to changing energy demands
(Dorn et al., 2015). The development and maturation of this specialized high-capacity mitochondrial
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system in the heart occur largely during the perinatal and postnatal developmental stages. The process
begins with a major surge in mitochondrial biogenesis at birth. Following this biogenic surge, there is
a period of maturation that involves a dramatic increase in dynamics (mitophagy, fusion, and fission),
leading to redistribution and dense packing of the specialized mature mitochondria along myofibrils.
This cellular architecture facilitates the transfer of high-energy phosphates between the mitochondria
and the contractile apparatus. The resultant mature mitochondrial system is capable of high-capacity
oxidation of fuels such as fatty acids, the predominant fuel substrate for the adult heart (Dorn et
al., 2015). Pathological cardiac hypertrophy and heart failure are characterized by an increase in the
expression of many contractile and structural genes that are normally expressed in fetal hearts along
with decreased expression of normal adult genes. Results imply progressive, pathologic remodeling
and dysregulation of mitochondrial energy production during the development of heart failure (Dorn
et al., 2015).
Role of mitochondrial DNA damage in the development of atherosclerosis
The mitochondrial organelles have pivotal roles in producing reactive oxygen species (ROS)
and in coordinating cell death, inflammation and metabolism. Mitochondrial dysfunction leads to
oxidative stress, disease, cell death, metabolic dysfunction and inflammation, which can all promote
atherosclerosis (Yu & Bennet, 2016). Recent evidence indicates that mitochondrial DNA (mtDNA)
damage is present and promotes atherosclerosis through mitochondrial dysfunction. mtDNA damage
may also be increased in atherosclerosis, since conditions that promote disease, such as hyperglycemia
and smoking, also increase ROS. Atherosclerosis, a leading cause of mortality in developed countries,
is characterized by fatty plaque formation in the arteries, the large conduit vessels carrying vital
oxygen and nutrients to the tissues. The atherosclerotic plaque forms at sites of endothelial dysfunction,
often where there is disturbed flow and altered shear stress. However, plaque rupture may occur that
occludes the artery, resulting in significant sequelae such as heart attacks and strokes (Yu & Bennett,
2016). Further work needs to be done to see whether eliminating mtDNA damage and mitochondrial
dysfunction can reduce atherosclerotic plaque burden and/or vulnerability.
Vital Role for Mitochondrial Calcium Exchange in Heart Function
Luongo et al. (2017) documented that the exit of calcium from mitochondria serves a critical role
in heart function. It has long been thought that calcium transport into mitochondria is a key signal
linking cardiac workload with energy production (Luongo et al., 2017). Other studies have shown the
importance of this pathway during stress, but the question was also raised whether the mitochondrial
calcium exchange was necessary for normal cardiac function. Luongo et al. (2017) used a newly
developed mutant mouse model to show that a mitochondrial sodium-calcium exchanger (NCLX)
is necessary for the heart to function properly. They found that without NCLX, the animals suffered
sudden cardiac death. They showed that the movement of calcium in and out of the myocardial
mitochondria is important to both cell death and pro-energetic signaling pathways (Luongo et al.,
2017). These findings suggest that mitochondrial calcium efflux may be a promising therapeutic target
with the potential to lessen the severity of cardiac disease states (Luongo et al., 2017).
Monitoring of Mitochondria may Predict Cardiac Arrest
Perry et al. (2017) developed a new technique to continuously monitor the mitochondria on the
epicardial surface using an enhanced resonance Raman spectroscopy which may predict the onset
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of cardiac arrest. They have conducted experiments on animals to evaluate whether the live heart
tissue is receiving enough oxygen to meet the demands in the heart. They identified the time when the
myocardium is so energy deficient that it cannot function properly with changes in mitochondrial redox
state preceding changes in cellular function. Whereas most blood tests used presently only measure
tissue injury or ischemia, this new approach evaluates the entire mitochondrial electron transport chain
to determine how much oxygen a cell needs to function properly (Perry et al., 2017). These authors
were able to quantify the reduced fraction of specific electron transport chain cytochromes, a metric
they named the resonance Raman reduced mitochondrial ratio (3RMR). As oxygen deficiency worsens,
heme moieties within the electron transport chain become progressively more reduced, leading to an
increasein3RMR.Myocardial3RMRincreasedfromreferencevaluesafterinferiorvenacavaocclusion
(Perry et al., 2017). A 3RMR value exceeding 40% at 10 min predicted subsequent cardiac arrest with
95% sensitivity and 100% specificity, outperforming all current measures, including contractility and
ejection fraction. 3RMR correlated with indices of intracellular redox state and energy production
(Perry et al., 2017). This new method may allow the assessment of the adequacy of oxygen delivery to
tissues in patients during intensive care medicine and surgery.
Concluding Remarks
Rhythms are ubiquitous and important to all living organisms. Rhythms are affected externally by
the environment, activity schedule and diet, among other factors. Rhythms are also partly endogenous.
Mitochondria also play an important role in the body and can influence biological rhythms via
circadian clock genes. Biological rhythms are important for health. Circadian disruption and impaired
clock genes are associated with increased cardiovascular disease risk and actual disease. Circadian
rhythm characteristics serve as markers of health and disease. They lead to primary prevention and,
when needed, they can guide the timing of treatment (chronotherapy). New treatment modalities of
mitochondrial dysfunctions (e.g., CoQ10 supplementation) should be combined with chronobiology for
optimal results in cardiovascular and other diseases.
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S, Mori H, Ichimaru Y, Mitsutake G, Pella D, Fanghong L, Zhao Z, Rao RS, Gvozdjakova A,
Halberg F. Circadian heart rate and blood pressure variability considered for research and patient
care. Int J Cardiol 2003; 87: 9-28.
	51.	Singh RB, Pella D, Otsuka K, Halberg F, Cornélissen G. New insights into circadian aspects of
health and disease. J Assoc Physicians India 2002; 50: 1416-1425.
	52.	Sjöstrand FS. Electron microscopy of mitochondria and cytoplasmic double membranes. Nature
1953a; 171: 30-32.
	53.	Sjöstrand FS. The ultrastructure of the outer segments of rods and cones of the eye as revealed by
the electron microscope. J Cell Comp Physiol 1953b; 42: 15-44.
	54.	Smith E. Health and Disease as Influenced by the Daily, Seasonal, and Other Cyclical Changes in
the Human System. London: Alton and Maberly; 1861; 409 pp.
	55.	Sothern RB, Yamamoto T, Cornélissen G, Takumi T, Halberg F. Central and peripheral circadian
clock genes, their statistical analysis for rhythms, and relationship to health and disease. Scripta
medica (Brno) 2009; 82: 133-163.
	56.	Touitou Y, Haus E. Biological rhythms from Biblical to Modern Times. A Preface. In Touitou Y,
Haus E (Eds.) Biological Rhythms in Clinical and Laboratory Medicine. Heidelberg: SpringerVerlag;
1992; pp. 1-5.
	57.	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 2001; 74: 87-92.
	58.	von Mayersbach H. An overview of the chronobiology of cellular morphology. In: Reinberg A,
Smolensky M (Eds.) Biological Rhythms and Medicine, New York: Springer-Verlag; 1983; pp.
47-78.
	59.	Yu EPK, Bennet MR. The role of mitochondrial DNA damage in the development of atherosclerosis.
Free Rad Bio Med 2016; 100: 223-230.
Correspondence:
Germaine Cornélissen
Halberg Chronobiology Center
University of Minnesota, Mayo Mail Code 8609
420 Delaware St. S.E. Minneapolis, MN 55455, USA
TEL +1 612 624 6976 FAX +1 612 624 9989
E-MAIL corne001@umn.edu
Website: http://halbergchronobiologycenter.umn.edu/
Support:
Halberg Chronobiology Fund
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Seven Day Blood Pressure Variability: The Effect of Sauna
Procedure and Whole Body Cryotherapy Procedure on 24
Hour Blood Pressure Profile in Healthy Subjects
Siegelová J., Havelková A., Michalčinová K., Dušek J., Pohanka M., Dunklerová L., Vank P., Dobšák
P., Cornélissen G.*
Department of Physiotherapy, Department of Sport Medicine and Rehabilitation, Faculty of Medicine, Masaryk
University, St. Anna Teaching Hospital, Brno, CZ, *Halberg Chronobiology Center, University of Minnesota, USA
Introduction
Regular exercise increases life expectancy, quality of life and work capability and productivity. In
patients with ischemic heart disease the non-pharmacologic exercise treatment decrease morbidity
and mortality of patients. 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 (1-4).
Because there are not many data about the effect of one hour aerobic and resistant training on 24h
profiles of systolic and diastolic blood pressure, measured using ambulatory blood pressure monitoring,
in the days with exercise and in the days without exercise during seven day ambulatory blood pressure
monitoring we studied it.
We have found that in healthy subjects one hour lasting aerobic training, combined training does
not change mean blood pressure from seven day/ 24h ambulatory blood pressure monitoring and there
were no differences between the days with exercise and without exercise in healthy subjects (5) and
in patients with coronary heart disease one hour lasting combined training (aerobic and resistant) does
not change mean blood pressure from seven day/ 24h ambulatory blood pressure monitoring.
Our previous studies on 7 day /24 h ambulatory blood pressure monitoring showed that the
values of 24h blood pressure varies from day to day in the same healthy men and patients (6-10). In
physiotherapy there are used positive and negative thermotherapy in the application on the whole body
in the regeneration of the tissues in organism and also in the therapy of diseases.
A lot of studies analyzed the immediate effect of the sauna procedure - positive thermotherapy on the
whole body and cryotherapy procedure on the whole body- negative thermotherapy on cardiovascular
parameters - on blood pressure and heart rate.
A sauna bath exposes the bather to a short period of intense dry or wet heat and thus activates
the sympathetic nervous system (11). To prevent an increase in the core body temperature, blood is
diverted to the skin to allow cooling to take place. Heart rate is elevated, and in particular diastolic
blood pressure decreases as a result of a lower peripheral resistance (12).
There are no data about the effects of these procedures on 24-hour blood pressure profile in the
days with procedures of sauna and the days without procedure and in the days with procedure of
cryotherapy and in the days without cryotherapy.
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The aim of the study was to compare 24-hour profile from the 7-day blood pressure monitoring
after application of sauna procedure and cryotherapy procedure in healthy subjects. From seven day
ambulatory blood pressure monitoring we compared the blood pressure 24 h profile in the day with
sauna procedure (0-24 h) and in the day without sauna procedure (25-48 h after sauna procedure). We
analyzed also the effect of whole body cryotherapy on the same day blood pressure profile (0-24 h) and
on the next day blood pressure profile (25-48) without cryotherapy during seven days /24h ambulatory
blood pressure monitoring in healthy subjects.
Methods and subjects
We examined 10 men and 10 women, healthy subjects, mean age 25±0.5 years, body weight was
70±6.50 kg, height was 1.74±0.044 m, body mass index (BMI) 23±0.705 kg/m2.
Sauna procedure
The sauna culture has always flourished in Finland and nowadays is used everywhere. Taking a
sauna begins by washing oneself up and then going to sit for some time in the hot room, typically
warmed to 80–110 °C (176–230 °F). The subject after rewarming takes cooling in water. After cooling
one goes back to the hot room and begins the cycle again. The healthy young subjects took two cycles
of warming and cooling.
Figure 1: Sauna
Whole body cryotherapy
Whole body cryotherapy (WBC) is currently used in physiotherapy. This treatment involves
exposing individuals to extremely cold dry air (below -100 °C) for two to four minutes. During these
exposures, individuals wear minimal clothing, which usually consists of shorts for males and shorts
and a crop top for females. After two to four minutes cooling there is a period of aerobic exercise for
a period of 10 minutes.
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Figure 2: Whole body cryotherapy
Methods of ambulatory blood pressure monitoring
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. We calculated mean systolic and diastolic blood
pressure for seven days. The regime of measurement of blood pressure was done for 7 days repeatedly
every 30 minutes from 5 to 22 h during the day time and once in an hour from 22 to 5 h at night (7).
For the sauna procedure and cryotherapy procedure they took the instruments for ambulatory blood
pressure monitoring off. The average SBP and DBP and their standard deviations (SD) or standard
error (ER) in the given days were determined by the calculation of arithmetic mean of these values
during every day and during 7 days. We evaluated the days with sauna (0-24h) and the days without
sauna (25-48h) and the days with cryotherapy (0-24 h) and the days without cryotherapy (25 -48 h).
The study was approved by local ethics committee and the patients signed the informed consent.
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Figure 3: Seven day ambulatory blood pressure monitoring
Figure 4: Blood pressure monitoring device A and D
Results
In the group of healthy subjects seven day ambulatory monitoring in all seven days including one
day with sauna and one day with cryotherapy showed the mean systolic blood pressure SD 122 ± 7.2
mmHg, the mean diastolic blood pressure 71 ± 2.8 mmHg and heart rate 73 ± 6.2 beat per minute. The
data are presented in Fig. 5 – 7.
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Figure 5: Mean systolic blood pressure from 7 day ambulatory blood pressure monitoring in all seven days
including one day with sauna and one day with cryotherapy is shown as red lines, 24-hour blood pressure profile
in 7-days is shown as black point
Figure 6: Mean diastolic blood pressure from 7 day ambulatory blood pressure monitoring in all seven days
including one day with sauna and one day with cryotherapy is shown as red lines, 24-hour blood pressure profile
in 7-days is shown as black point
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Figure 7: Mean heart rate from 7 day ambulatory blood pressure monitoring in all seven days including one day
with sauna and one day with cryotherapy is shown as red lines, 24-hour heart rate profile in 7-days is shown as
black point
Sauna
We compared mean systolic blood pressure (±SD) from 7 day ambulatory blood pressure monitoring
in all seven days (122±7.2 mmHg) with mean systolic blood pressure profile (±SD) 0 – 24 h after sauna
(121± 9 mmHg) and with mean systolic blood pressure profile (±SD) 25 – 48 h after sauna (122±9.3
mmHg) and we have not found differences in systolic blood pressure. These results are shown in Fig 8.
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Figure 8: Mean systolic blood pressure (±SD) from 7 day ambulatory blood pressure monitoring in all seven days,
mean systolic blood pressure (±SD) 0 – 24 h after sauna, mean systolic blood pressure (±SD) 25 – 48 h after sauna
We compared mean diastolic blood pressure (±SD) from 7 day ambulatory blood pressure monitoring
in all seven days (71±2.8 mmHg) with mean diastolic blood pressure profile (±SD) 0 – 24 h after sauna
(70±4.69 mmHg) and with mean diastolic blood pressure profile (±SD) 25 – 48 h after sauna (70±5.4
mmHg) and we have not found differences in diastolic blood pressure. These results are shown in Fig 9.
Figure 9: Mean diastolic blood pressure from 7 day ambulatory blood pressure monitoring in all seven days, mean
diastolic blood pressure (±SD) 0 – 24 h after sauna, mean diastolic blood pressure (±SD) 25 – 48 h after sauna
NONINVASIVE METHODS IN CARDIOLOGY 2017
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We compared mean heart rate (±SD) from 7 day ambulatory blood pressure monitoring in all seven
days (73±6.2 bpm ) with mean heart rate (±SD) 0 – 24 h after sauna (75±9.0 bpm ) and with mean
heart rate (±SD) 25 – 48 h after sauna (72±6.1 mmHg) and we have not found differences in heart rate.
These results are shown in Fig 10.
Figure 10: Mean heart rate from 7 day ambulatory blood pressure monitoring in all seven days, mean heart rate
(±SD) 0 – 24 h after sauna, mean heart rate (±SD) 25 – 48 h after sauna
Cryotherapy
After cryotherapy we compared mean systolic blood pressure (±SD) from 7 day ambulatory blood
pressure monitoring in all seven days (122±7.2 mmHg) with mean systolic blood pressure profile
(±SD) 0 – 24 h after cryotherapy (122±8.8mmHg) with mean systolic blood pressure profile (±SD) 25
– 48 h after cryotherapy (121±8.1mmHg) and we have not found differences in systolic blood pressure
after cryotherapy. These results are shown in Fig 11.
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Figure 11: Mean systolic blood pressure (±SD) from 7 day ambulatory blood pressure monitoring in all seven
days, mean systolic blood pressure (±SD) 0 – 24 h after cryotherapy, mean systolic blood pressure (±SD) 25 – 48
h after cryotherapy
After cryotherapy we compared mean diastolic blood pressure (±SD) from 7 day ambulatory blood
pressure monitoring in all seven days (71±2.8 mmHg) with mean diastolic blood pressure profile
(±SD) 0 – 24 h after cryotherapy (71±5.4mmHg) with mean diastolic blood pressure profile (±SD) 25
– 48 h after cryotherapy (71±3.6mmHg) and we have not found differences in diastolic blood pressure
after cryotherapy. These results are shown in Fig 12.
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Figure 12: Mean diastolic blood pressure from 7 day ambulatory blood pressure monitoring in all seven days,
mean diastolic blood pressure (±SD) 0 – 24 h after cryotherapy, mean diastolic blood pressure (±SD) 25 – 48 h
after cryotherapy
After cryotherapy we compared mean heart rate (±SD) from 7 day ambulatory blood pressure
monitoring in all seven days (73±6.2 bpm) with mean heart rate (±SD) 0 – 24 h after cryotherapy
(74±9.2 bpm) and with mean heart rate (±SD) 25 – 48 h after cryotherapy (71±7.3 bpm) and we have
not found differences in heart rate after cryotherapy. These results are shown in Fig 13.
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Figure 13: Mean heart rate from 7 day ambulatory blood pressure monitoring in all seven days, mean heart rate
(±SD) 0 – 24 h after cryotherapy, mean heart rate (±SD) 25 – 48 h after cryotherapy
Sauna
The variability of 24 h systolic blood pressure in the day after sauna (0-24h) and of 24 h systolic
blood pressure after sauna (25-48h) was not different in comparison to the seven day mean systolic
blood pressure, as is shown on Fig.14.
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Figure 14: Mean systolic blood pressure from 7 day ambulatory blood pressure monitoring in all seven days (red
lines), mean systolic blood pressure in day after sauna 0 – 24 h (open circles), mean systolic blood pressure in
day after sauna 25 – 48 h (black points)
The variability of 24 h diastolic blood pressure in the day after sauna (0-24h) and of 24 h diastolic
blood pressure after sauna (25-48h) was not different in comparison to the seven day mean diastolic
blood pressure, as is shown on Fig.15.
Figure 15: Mean diastolic blood pressure from 7 day ambulatory blood pressure monitoring in all seven days
(red lines), mean diastolic blood pressure in day after sauna 0 – 24 h (open circles), mean diastolic blood
pressure in day after sauna 25 – 48 h (black points)
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The variability of 24 h heart rate in the day after sauna (0-24h) and of 24 h heart rate after sauna
(25-48h) was not different in comparison to the seven day mean heart rate, as is shown on Fig. 16.
Figure 16: Mean heart rate from 7 day ambulatory blood pressure monitoring in all seven days (red lines), mean
heart rate in day after sauna 0 – 24 h (open circles), mean heart rate in day after sauna 25 – 48 h (black points)
Cryotherapy
The variability of 24 h systolic blood pressure in the day after cryotherapy (0-24h) and of 24 h
systolic blood pressure after cryotherapy (25-48h) was not different in comparison to the seven day
mean systolic blood pressure, as is shown on Fig.17.
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Figure 17: Mean systolic blood pressure from 7 day ambulatory blood pressure monitoring in all seven days (red
lines), mean systolic blood pressure in day after cryotherapy 0 – 24 h (open circles), mean systolic blood pressure
in day after cryotherapy 25 – 48 h (black points)
The variability of 24 h diastolic blood pressure in the day after cryotherapy (0-24h) and of 24 h
diastolic blood pressure after cryotherapy (25-48h) was not different in comparison to the seven day
mean diastolic blood pressure, as is shown on Fig. 18.
Figure 18: Mean diastolic blood pressure from 7 day ambulatory blood pressure monitoring in all seven days
(red lines), mean diastolic blood pressure in day after cryotherapy 0 – 24 h (open circles), mean diastolic blood
pressure in day after cryotherapy 25 – 48 h (black points)
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The variability of 24 h heart rate in the day after cryotherapy (0-24h) and of 24 h heart rate after
cryotherapy (25-48h) was not different in comparison to the seven day mean heart rate, as is shown
on Fig. 19.
Figure 19: Mean heart rate from 7 day ambulatory blood pressure monitoring in all seven days (red lines), mean
heart rate in day after cryotherapy 0 – 24 h (open circles),mean heart rate in day after cryotherapy 25 – 48 h
(black points)
Discussion
Systemic thermal therapy, so-called Sauna or warm water insertion therapy, which is considered
to be one of the thermal vasodilatation therapies and has been applied to many healthy people for
centuries, has been gathering attention from various medical fields. There have been reviews of the
physiologic effects, benefits and risks of sauna bathing (13, 14).
Sauna effects the cardiovascular parameters. To prevent an increase in the core body temperature,
blood is diverted to the skin to allow cooling to take place. Heart rate is elevated, and in particular
diastolic blood pressure decreases as a result of a lower peripheral resistance. Among healthy people,
a sauna bath does not usually cause excess cardiovascular strain, as has been indicated by moderate
changes in heart rate, blood pressure and the excretion of catecholamines (15, 16).
Our results showed that MESOR of 7day/24-hour systolic blood pressure from 7 day ambulatory
blood pressure monitoring was not different from MESOR of systolic blood pressure profile in the day
with sauna (0 – 24 h) and from MESOR of systolic blood pressure profile without sauna (25 – 48 h
after sauna). Similar results we have find in diastolic blood pressure.
MESOR of diastolic blood pressure from 7 day/24-h ambulatory blood pressure monitoring was
not different from MESOR of diastolic blood pressure profile (0 – 24 h) and from MESOR of diastolic
blood pressure profile (25 – 48 h after sauna).
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Our results showed that heart rate from 7 day/24-h of ambulatory blood pressure monitoring was
not different from MESOR of heart rate (0 – 24 h) and from MESOR of heart rate (25 – 48 h after
sauna). In healthy subjects our findings are in agreement with the others references (15, 16).
Numerous studies have accumulated scientific evidence supporting the beneficial effect of whole
body cryotherapy as an alternative treatment and rehabilitation technique.
The physiological mechanisms responsible for the effect of extreme cold exposure and the scientific
basis for and optimal cryotherapy remain unclear. It was showed that stimulation of the autonomic
nervoussystemafterasinglewhole-bodycryostimulationwasmorepronouncedbyusingacryochamber
system (-110° C), (17, 18).
The results in our study showed that in healthy subjects the effect of sauna and cryotherapy does
not change 24-hour MESOR of blood pressure profile, evaluated from seven day/ 24-hour ambulatory
blood pressure monitoring. On the basis of our results, we can prescribe a cryotherapy in healthy
subjects and sport recovery and to enhance sleep quality and biological rhythmic control of human
body.
Conclusion
The present study confirms that in healthy subjects the effect of sauna and cryotherapy does not
change 24-hour MESOR of blood pressure profile, evaluated from seven day/ 24-hour ambulatory
blood pressure monitoring.
The variability of 24-hour blood pressure profile and heart rate in the day after sauna and cryotherapy
(0-24h) was not different from resting day in 24-hour values after sauna and cryotherapy (25-48h).
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.	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.
	 3.	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.
	 4.	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.
	 5.	Siegelová J, Havelková A, Dušek J, Pohanka M, Dunklerová L, Dobšák P, Cornélissen G. Seven
Day Blood Pressure Variability at Rest And During Exercise in Healthy Men And Patients. In
Noninvasive methods in Cardiology, Brno, Masaryk University, 2015, 79-97.
	 6.	Siegelová J, Dušek J, Havelková A, Pohanka M, Dobšák P, Cornélissen G, Halberg F. Sevenday
ambulatory blood pressure monitoring: night-to-day blood pressure ratio after exercise. J
Hypertension 2013, 31, Suppl A, 370.
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	 7.	Siegelová J, Havelková A, Dušek J, Pohanka M, Dunklerová L, Dobšák P, Cornélissen G, Halberg
F. Circadian variability of 24-hour mean values of systolic and diastolic blood pressure in subjects
monitored for 7 consecutive days. J Hypertension 2013, 31, Suppl A, 38.
	 8.	Siegelová, J, Dušek J, Otsuka K, Cornelissen G. Mathematical Model of Cardiovascular Disease
Risk Based on Vascular Variability Disorders. World Heart J 2014, 6, 1, 57-62.
	 9.	Siegelová J, Havelková A, Dušek J, Pohanka M, Dunklerová L, Dobšák P, Cornélissen G, Halberg
F. Ambulatory blood pressure monitoring lasting 7 days: day and night blood pressure variability.
FUNDAMENTAL & CLINICAL PHARMACOLOGY 2013, 27,1, 83.
	10.	Siegelova J., Fiser B. Day-to-day variability of 24-h mean values of SBP and DBP in patients
monitored for 7 consecutive days. J Hypertension, 2011; 294: 818-819.
	11.	Kukkonen-Harjula K, Kauppinen K. How the sauna affects the endocrine system. Ann Clin Res,
1988;20:262–266.
	12.	Kukkonen-Harjula K, Oja P, Vuori I et al. Cardiovascular effects of Atenolol, Scopolamine and
their combination on healthy men in Finnish sauna baths. Eur J Appl Physiol 1994,69:10-15.
	13.	Frishman WH, Grattan JG, Mamtani R. Alternative and complementary medical approaches in the
prevention and treatment of cardiovascular disease. Curr Probl Cardiol, 2005, 30: 383-459.
	14.	Eren B, Fedakar R, Turkmen N, Akan O. Deaths in the Turkish hamam (hot bath). Bratisl Lek
Listy, 2009, 110: 697-700.
	15.	Vuori I. Sauna bather‘s circulation. Ann Clin Res, 1988, 20:249–256.
	16.	Kukkonen-Harjula K, Oja P, Laustiola K, Vuori I, Jolkkonen J, Siitonen S, Vapaatalo H (1989)
Haemodynamic and hormonal responses to heat exposure in a Finnish sauna bath. Eur J Appl
Physiol 58:543–550
	17.	Lobkowska A, Szygula Z. Changes in blood pressure with compensatory heart rate decrease and in
the level of aerobic capacity in response to repeated whole-body cryostimulation in normotensive
young and physicially active men. Int J Occupational Medicine and Environmetal Health, 2010, 23,
367-375.
	18.	Louis J, Schaal K, Bieuzen F, Le Meur Y et al. Head Exposure to Cold during Whole-Body
Cryostimulation: Influence on Thermal Response and Autonomic Modulation. Plos One, 2015, 10,
1371-1389.
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Seven-Day Ambulatory Blood Pressure Monitoring after
4 Months of Exercise Training
Siegelová J., Havelková A., Raková D., Dušek J., Pohanka M., Dunklerová L., Dobšák P., Cornélissen G.*
Department of Physiotherapy, Department of Sportmedicine and Rehabilitation, Faculty of Medicine, Masaryk
University, St. Anna Teaching Hospital, Brno, CZ,
*University of Minnesota, USA
Introduction
Franz Halberg and Germaine Cornelissen using ambulatory blood pressure monitoring showed the
need to account for day-to-day changes of blood pressure and heart rate and the necessity for circadian
assessmentofthehour-to-hourvariabilityincardiovascularparameters.TogetherwiththeChronobiology
center of Minnesota we participate in the international project BIOCOS. The presentation in May 2017
adds new results to this project BIOCOS (1, 2). In the guidelines for diagnoses of hypertension, fixed
limits of 140/90 mmHg (systolic/diastolic BP) were used to diagnose hypertension in all adults 18
years and older. The circadian rhythm in BP was thought to primarily reflect the rest-activity schedule
rather than being in part endogenous (2). While this is no longer the case, ambulatory BP monitoring
is still restricted to “special cases”, often limited to 24 hours. Evidence is presented herein for the need
to routinely screen for BP and heart rate (HR) variability, and for continued monitoring in patients in
need of treatment. According to a consensus meeting held at St. Anna Hospital, Masaryk Univesity,
Brno, Czech Republic in 2008 Franz Halberg with Germaine Cornélissen, Thomas Kenner, Bohumil
Fiser, Jarmila Siegelova and others proclaimed Vascular Variability Disorders. Determination of
Vascular Variability Disorders – MESOR hypertension, circadian hyper-amplitude-tension, excessive
pulse pressure, deficient heart variability and deviation of circadian rhythm is best to diagnose from
seven day/24-h ambulatory blood pressure monitoring (3, 4, 5, 6).
Our previous studies analyzed from seven day/24-h ambulatory blood pressure monitoring
immediate effect of exercise on circadian blood pressure profile. The question of long exercise during
3-4 months will show the effect on seven day/24-h ambulatory blood pressure monitoring.
The purpose of the study
The aim of the study was to compare the 7-day/24-h blood pressure monitoring before and after
exercise training lasting 4 months in healthy subjects.
Methods
We examined 20 healthy subjects, mean age 23.1±2.2 years (from 19 to 29 years, 7 men and 13
women), mean body weight was 72.8±13.4 kg, mean height 174±8 cm.
For exercise training we used walking activity at the level of 70 % maximum heart rate. The
exercise training lasted 4 months. The subjects were recruited for seven-day ambulatory blood pressure
monitoring before and after 4 months. Medical Instruments TM2431 (A&D, Japan) were used for
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ambulatory blood pressure monitoring (oscillation method). One-hour means of systolic and diastolic
blood pressure were evaluated. We calculated mean systolic and diastolic blood pressure for seven days
and every 24-hour profile.
The regime of measurement of blood pressure was done for 7 days repeatedly every 30 minutes
from 5 to 22 h during the day time and once in an hour from 22 to 5 h at night.
The study was approved by local ethics committee.
Figure 1: Seven-day/24-h ambulatory blood pressure monitoring
One-hour means of systolic and diastolic blood pressure were evaluated for every hour from sevenday/24-h
ambulatory blood pressure monitoring.
We evaluated every day mean of 24-hour profile and 7-day mean systolic and diastolic pressure.
We analyzed day-to-day variability before and after 4 months with exercise training.
Results
In healthy subjects, the seven-day blood pressure profile (mean ± SD) in systolic blood pressure was
122±9 mmHg before the exercise training and after 4 months of exercise training it was 123±9 mmHg,
as is shown in Fig. 2.
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Figure 2: Seven-day/24-h systolic blood pressure profile before and after 4 months exercise training
In healthy subjects, the seven-day blood pressure profile (mean ± SD) in diastolic blood pressure
was 70±3 mmHg before the exercise training and after exercise it was 71±3 mmHg in the whole group.
These results are presented in Fig. 3.
Figure 3: Seven-day day/24-h diastolic blood pressure profile before and after 4 months exercise training
In healthy subjects, the seven-day heart rate profile (mean ± SD) was 72.3±4.9 cycle per minute
before the exercise and after exercise it was 72.9±4.8 cycle per minute in the whole group. These
results are shown in Fig. 4.
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Figure 4: Seven-day day/24-h heart rate profile before and after 4 months exercise training
Circadian variability in the following results is presented as everyday 24-h value in the black points
and seven-day/24-h mean as a red line in blood pressure and heart rate.
Seven-day systolic blood pressure variability in 20 healthy subjects before exercise training is shown
in Fig. 5. The lowest systolic blood pressure was 113 ± 2 mmHg, the highest systolic blood pressure
143 ± 2 mmHg.
Figure 5: Seven-day systolic blood pressure variability in 20 healthy subjects before exercise training
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Seven-day systolic blood pressure variability in 20 healthy subjects after exercise is shown in
Fig. 6. The lowest systolic blood pressure was 107 ± 2 mmHg, the highest systolic blood pressure
144 ± 4 mmHg.
Figure 6: Seven-day systolic blood pressure variability in 20 healthy subjects after 4 months exercise training
Seven-day diastolic blood pressure variability in 20 healthy subjects before exercise is shown in
Fig. 7. The lowest diastolic blood pressure was 64 ± 1 mmHg, the highest diastolic blood pressure
76 ± 4 mmHg.
Figure 7: Seven-day diastolic blood pressure variability in 20 healthy subjects before exercise training
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Seven-day diastolic blood pressure variability in 20 healthy subjects after 4 months exercise training
is shown in Fig. 8. The lowest diastolic blood pressure was 64 ± 2 mmHg, the highest diastolic blood
pressure 77 ± 3 mmHg.
Figure 8: Seven-day diastolic blood pressure variability in 20 healthy subjects after 4 months exercise training
Seven-day heart rate variability in 20 healthy subjects before 4 months exercise training is shown in
Fig. 9. The lowest heart rate was 58 ± 4 mmHg, the highest heart rate 80 ± 6 mmHg.
Figure 9: Seven-day heart rate variability in 20 healthy subjects before 4 months exercise training
Seven-day heart rate variability in 20 healthy subjects after 4 months exercise training is shown in
Fig. 10. The lowest heart rate was 54 ± 4 mmHg, the highest heart rate 87 ± 5 mmHg.
NONINVASIVE METHODS IN CARDIOLOGY 2017
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Figure 10: Seven-day heart rate variability in 20 healthy subjects after 4 months exercise training
24-h profile variability before and after 4 months of exercise training was present in our healthy
subjects in cardiovascular parameters, measured from seven-day/24-h ambulatory blood pressure
monitoring. The variability of 24-h systolic blood pressure profile was large and was present also after
4 months of exercise training. In 24-h diastolic blood pressure profile we have seen also large blood
pressure variability before and after 4 months of exercise training. 24-h of heart rate also showed
variability before and after exercise training. The highest and lowest values in the seven-day means are
also in all subjects similar before and after training.
Discussion
Systolic and diastolic 24-h blood pressure profile varied largely and the variability of 24-h profile
was not changed after 4 months of exercise training in our healthy subjects. Our previous results we
have shown that in patients with increased sympathetic activity with chronic coronary artery diseases
(7). The eight weeks of exercise training in patients decreased sympathetic activity and increased
parasympathetic activity (8). Our results on healthy subjects in this study do not show changes in
mean values of heart rate during seven-day/24-h ambulatory blood pressure monitoring. There are
also differences in the age of both groups and perhaps also different living style of young students of
physiotherapy and patients with chronic heart failure could play a role in our results.
Conclusion
The study showed the seven-day/24-h blood pressure monitoring before and after exercise training
lasting 4 months in healthy subjects was not different. 4 months lasting exercise training, based on
walking at the 70 % maximum heart rate, does not affect mean 7-day/24-h of heart rate before and
after training.
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Day-to-day changes of 24-h blood pressure profile systolic and diastolic blood pressure analyzed
from 7-day ambulatory blood pressure monitoring, were not different before and after 4 months lasting
exercise training.
References
	 1.	James PA Oparil S, Carter BL, Cushman WC, Dennison-Himmelfarb C, Handler J, Lackland
DT, LeFevre ML, MacKenzie TD, Ogedegbe O Smith SC Jr, Svetkey LP Taler SJ, Townsend
RR, Wright JT Jr, Narva AS, Ortiz E. 2014 evidence-based guideline for the management of high
blood pressure in adults: report from the panel members appointed to the Eighth Joint National
Committee (JNC 8). JAMA. 2014; 311(5): 507-520.
	 2.	Halberg F, Cornélissen G, Halberg E, Halberg J, Delmore P, Shinoda M, Bakken E. Chronobiology
of human blood pressure. Medtronic Continuing Medical Education Seminars, 4th ed. Minneapolis:
Medtronic Inc.; 1988. 242 pp.
	 3.	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 need and means to detect vascular variability
disorders (VVDs) and vascular variability syndromes (VVSs). Int. J. of Geronto-Geriatrics 11 (14)
119-146, 2008.
	 4.	Halberg F., Cornelissen G., Otsuka K., Siegelova J., Fiser B., Dusek J., Homolka P., Sanches de la
Pena S., Sing R.B. and The BIOCOS project. Extended consensus on means and need to detect
vascular variability disorders and vascular variability syndrome. World Heart J 2010; 2,4:279-305.
	 5.	Halberg F., Cornelissen G., Dusek J., Kenner B., Kenner T., Schwarzkoppf O., Siegelova J. Bohumil
Fiser (22.10.1943 – 21.3.2011): Chronobiologist, Emeritus Head of 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.	Otsuka K., Cornelissen G., Halberg F. Chronomics and continuous ambulatory blood pressure
monitoring. Springer Japan, 2016, 870p. ISBN 978-4-43154630-6.
	 7.	La Rovere MT, Bigger JT, Marcus FI, Mortara A, Schwartz PJ. Baroreflex sensitivity and heart rate
variability in prediction of total cardiac mortality after myocardial infarction. Lancet. 1998.;351:478-
484.
	 8.	Jančík J, Svačinová H, Siegelová J, Dobšák, P, Placheta Z, Fišer B, et al. Baroreflex sensitivity in
patients with chronic coronary artery disease: influence of eight week´s exerciste training. Scripta
Medica, 2001;74:39-44.
NONINVASIVE METHODS IN CARDIOLOGY 2017
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When to Exercise for Better Health
Jarmila Siegelova, Alena Havelková, Jiří Dušek, Leona Dunklerová, Petr Dobšák, Germaine
Cornélissen*
Department of Physiotherapy, Department of Sportsmedicine and Rehabilitation, Faculty of Medicine, Masaryk
University, St. Anna Teaching Hospital, Brno, CZ
University of Minnesota, USA
Introduction
Franz Halberg is a founder of modern chronobiology. Unlike other famous scientists devoting
their activities mostly to presentation of honorary lectures at international scientific conferences Prof
Halberg continued in scientific work until 2013.
The last Halberg proposal for diagnosis of vascular variability disorders on the basis of sevenday/24
hour ambulatory blood pressure and heart rate monitoring was presented in Brno Congress
Noninvasive Methods in Cardiology 2008 (1, 2, 3, 4, 5).
Figure 1: 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,
Halberg Chronobiology Center, University of Minnesota (*1919 - +2013)
NONINVASIVE METHODS IN CARDIOLOGY 2017
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Figure 2: Vascular Variability Anomalies (VVAs) picked up by chronobiologically interpreted 7-day around-theclock
records of blood pressure and heart rate monitoring become Vascular Variability Disorders (VVDs) when
they are replicated in successive 24-hour/7-day records. If several VVDs coexist, the risk of an ischemic stroke
within 6 years increases from about 5% to near 100%. To the five VVDs in the consensus, we can add a sixth, a
circadian desynchronization of the endocrines and the circulation more recently documented as ecfrequentia in
association with adynamia and depression recurring mostly twice-yearly in an extensively studied 62-year-old
woman [10]. © Halberg
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.
In cooperation with Halberg Chronobiology Center since the 1980s we have in Brno measured
658 seven-day/24 hour blood pressure profiles, which we also together analyzed with Minnesota. In
cooperation we described some new findings about chronobiology of blood pressure (6, 7, 8, 9, 10, 11,
12, 13 14).
The aim of the study is to evaluate the effect of daily 1-hour exercise on the seven-day/24-hour
blood pressure profile analyzed as a whole or considering each day separately.
NONINVASIVE METHODS IN CARDIOLOGY 2017
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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.
We calculated 24-hour mean systolic and diastolic blood pressure for seven days, then every day
with exercise and every day without exercise.
We have compared the 24-hour blood pressure profile of 7 days outpatient monitoring in days with
exercise (0-24 h) and in days without exercise (25-48 h) in healthy subjects and patients. We used aerobic
training in 41 healthy subjects, combined training for 20 healthy people, Nordic Walking in 19 subjects
and combined training in 53 patients after myocardial infarction in cardiovascular rehabilitation.
Figure 3: Seven-day/24-h ambulatory blood pressure monitoring
Healthy Subjects - Aerobic Training
We examined 21 men and 20 women, healthy subjects, mean age 29±4.9 years (from 23 to 39).
For exercise training we used bicycle ergometer Kettler, type X7, Germany, 2x during week,
constant load 120 W in men and 80 W in women, lasting 60 min. Every exercise unit was composed
from warm-up period 3 min., load 54 min. and cool-down period 3 min.
Heathy Subjects - Combined Training
We examined 5 men and 15 women, healthy subjects, mean age 29±4.9 years (from 23 to 39).
For exercise training we used aerobic and resistant training, 2x during week, constant load at the
heart rate 70 % of heart rate maximum, lasting 25 min. and resistant training lasting 15 min. Every
exercise unit was composed from warm-up period 10 min. and cool-down period 10 min.
NONINVASIVE METHODS IN CARDIOLOGY 2017
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Heathy Subjects - Nordic Walking
We examined 7 men and 12 women, healthy subjects, mean age 29±4.9 years (from 23 to 39).
For exercise training we used nordic walking, 2x during week, constant distance 4.3 km at the heart
rate 70 % of heart rate maximum.
Patients with infarctus of myocardium
We examined 41 men and 12 women, patients with infarctus of myocardium.
The set being monitored consisted of 53 patients after myocardial infarction in the past history more
than 3 months before, of mean age 63 ± 6.5 years and mean ejection fraction of the left ventricle 43 ±
12.3 %.
ThepatientsunderwentphaseIIofcardiovascularrehabilitation(controlledambulatoryrehabilitation
program) lasting three months with the frequency of three times in a week at the Department of
Sports Medicine and Rehabilitation of St. Anna Teaching Hospital.
The subjects 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 and diastolic blood pressure were evaluated.
We calculated 24-hour mean systolic and diastolic blood pressure for seven days, every day with
exercise and every day without exercise.
Results
Healthy Subjects - Aerobic Training
We compared the blood pressure profile in 24-h with exercise and in 24-h without exercise. In healthy
subjects with aerobic training, seven-day/24-hour of systolic blood pressure was 115 ± 1.1 mmHg,
diastolic 69 ± 1.4 mmHg, in days with exercise (0-24h) systolic blood pressure was 115 ± 2.8 mmHg,
diastolic 69 ± 1.7 mmHg, in days without exercise (25-48 h) systolic blood pressure was 116 ± 3.4 mmHg,
diastolic 69 ± 2.2 mmHg.
Heathy Subjects - Combined Training
In healthy subjects with combined training seven days of systolic blood pressure blood pressure was
113 ± 1.8 mmHg, diastolic 68 ± 1.4 mmHg, days with exercise (0-24h) systolic blood pressure were
112 ± 1.9 mmHg, diastolic 69 ± 1.5 mmHg, in days without exercise (25-48 h) systolic blood pressure
was 113 ± 1.8 mmHg, diastolic 68 ± 1.4 mmHg.
Heathy Subjects - Nordic Walking
In healthy subjects the seven-day blood pressure mean ± SE in systolic blood pressure was
113±1.3 mmHg, in diastolic blood pressure 69±1.3 mmHg in the whole group, in the days with exercise
(0-24h) systolic blood pressure was 111±1.5 mmHg, diastolic blood pressure 67±1.4 mmHg, in the days
without exercise (25-48 h) systolic blood pressure was 113±1.8 mmHg, diastolic blood pressure 69±1.4
mmHg.
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Patients with infarctus of myocardium
In patients with myocardial infarction, seven-day mean systolic blood pressure was 122 ± 4 mmHg,
diastolic 74 ± 3 mmHg, in days with exercise (0-24h) systolic blood pressure was 121 ± 3 mmHg,
diastolic 74 ± 2 mmHg, in days without exercise systolic blood pressure 121 ± 3 mmHg, diastolic 73
± 3 mmHg.
In all healthy subjects and patients our results showed that 1-hour of aerobic training and combined
training did not change the 24-hour MESOR of systolic and diastolic blood pressure profile, assessed
from a seven-day ambulatory blood pressure monitoring (7 days / 24 hours) in healthy subjects and in
patients.
Timing of exercise
Exercise training should be timed according to the circadian blood pressure profile before starting
the program. If the circadian blood pressure amplitude is excessive, we have found that it is preferable
to time exercise earlier in the day (from 7:30 to 19:00) since evening exercise may increase the circadian
amplitude of blood pressure and thus potentially cause harm (16). Ambulatory monitoring interpreted
chronobiologically can serve for the optimization of the timing of exercise on an individual basis.
Discussion
In our earlier study we asked what is the best time of exercise (16). 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. 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) (3). Results were assigned to the clock hour of exercise
during the given span to yield new time series amenable to cosinor analysis (3), complementing the
one-way analysis of variance, the main effect being timing of exercise.
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 (15). 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 us (2).
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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Conclusion I
In this study we also analyzed the timing of exercise. One of our studies showed that the exercise at
9 o´clock in the evening increases the Circadian Hyper-Amplitude Tension (CHAT).
Our studies showed that the exercise in the daily time between 7:30 until 19:00 h does not evoke the
Circadian Hyper-Amplitude Tension (CHAT) in healthy subjects and in patients.
Conclusion II
From the results we can conclude that 24-hour blood pressure MESOR at rest and during exercise
from day-to-day vary in healthy subjects as well as in patients with coronary heart disease IM were
not different in the days with the exercise and without exercise.
The healthy subjects during different kinds of exercise activity get the similar results in 24 h blood
pressure profiles in comparison with the days without exercise.
On the basis of our results we recommend the 7-day blood pressure monitoring or home blood
pressuremonitoring.Theeducationforlong-lastingself-monitoringisthebestapproachformanagement
of hypertension.
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.	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.
	 3.	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.
	 4.	Halberg F, Cornélissen G, Kenner T, Dusek J, Kenner B, Schwartzkopff O, Siegelová J. Bohumil
Fiser (22.10.1943-21.03.2011): Chronobiologist, Emeritus Head of the Physiology Department
at Masaryk university (Brno, Czech Republic), Czech Minister of Health, and Executive Board
Member of the WHO: His Legacies for Public and Personalized Health Care. World Heart J, 2011;
3(1): 3163-3177.
	 5.	Otsuka K, Cornélissen G, Halberg F. Chronomics and Continous Ambulatory Blood Pressure
Monitoring. Springer: London, 2016, 870 p.
	 6.	Siegelová J, Havelková A, Dušek J, Pohanka M, Dunklerová L, Dobšák P, Cornélissen G. Seven
Day Blood Pressure Variability at Rest And During Exercise in Healthy Men And Patients. In
Noninvasive methods in Cardiology, Brno, Masaryk University, 2015, 79-97.
	 7.	Siegelová J, Dušek J, Havelková A, Pohanka M, Dobšák P, Cornélissen G, Halberg F. Sevenday
ambulatory blood pressure monitoring: night-to-day blood pressure ratio after exercise. J
Hypertension 2013, 31, Suppl A, 370.
NONINVASIVE METHODS IN CARDIOLOGY 2017
131
	 8.	Siegelová J, Havelková A, Dušek J, Pohanka M, Dunklerová L, Dobšák P, Cornélissen G, Halberg
F. Circadian variability of 24-hour mean values of systolic and diastolic blood pressure in subjects
monitored for 7 consecutive days. J Hypertension 2013, 31, Suppl A, 38.
	 9.	Siegelová, J, Dušek J, Otsuka K, Cornelissen G. Mathematical Model of Cardiovascular Disease
Risk Based on Vascular Variability Disorders. World Heart J 2014, 6, 1, 57-62.
	10.	Siegelová J, Havelková A, Dušek J, Pohanka M, Dunklerová L, Dobšák P, Cornélissen G, Halberg
F. Ambulatory blood pressure monitoring lasting 7 days: day and night blood pressure variability.
FUNDAMENTAL & CLINICAL PHARMACOLOGY 2013, 27,1, 83.
	11.	Siegelova J., Fiser B. Day-to-day variability of 24-h mean values of SBP and DBP in patients
monitored for 7 consecutive days. J Hypertension, 2011; 294: 818-819.
	12.	Singh, R., F. Halberg, G. Cornelissen, J. Siegelová, K. Hristová, E. Toda, T. Toru, J. Fedacko,
K. Otsuka. Personalized Circadian Timing of Exercise. World Heart Journal, Hauppauge: Nova
Science Publishers, 2013, roč. 5, č. 2, s. 79-90. ISSN 1556-4002.
	13.	Siegelová, J., J. Dušek, K. Otsuka, G. Cornelissen. Mathematical Model of Cardiovascular Disease
Risk Based on Vascular Variability Disorders. World Heart Journal, Nova Science Publishers Inc,
2014, roč. 6, č. 1, s. 57-62. ISSN 1556-4002.
	14.	Cornelissen, G., J. Siegelová, Y. Watanabe, K. Otsuka, F. Halberg. Chronobiologically-Interpreted
ABPM Reveals Another Vascular Variability Anomaly (VVA): Excessive Pulse Pressure Product
(PPP) Updated Conference Report. World Heart Journal, Hauppauge, Spojené státy americké: Nova
Science Publishers, 2012, roč. 4, č. 4, s. 237-245. ISSN 1556-4002.
	15.	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.
	16.	Singh RB, Halberg F, Siegelová J, Cornélissen G. What is the best time for exercise? Noninvasive
Methods in Cardiology 2012. Masaryk University: Brno, 2012, p.163 – 164.
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NONINVASIVE METHODS IN CARDIOLOGY 2017
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Ambulatory Rehabilitation Program for Patients with
Cardiovascular Diseases
Leona Mífková, Alena Havelková, Radka Látalová, Pavel Homolka, Pavel Vank, Ladislav Svoboda,
Michaela Sosíková, Jarmila Siegelová, Petr Dobšák
Department of Sports Medicine and Rehabilitation, St. Anne´s Faculty Hospital, Masaryk University Brno, Czech
Republic
Department of Physiotherapy and Rehabilitation, St. Anne´s Faculty Hospital, Masaryk University Brno, Czech
Republic
Introduction
Cardiovascular diseases (CVD) are still the leading cause of death in Europe (4.4 million deaths/
year, that is, 48% of all deaths yearly). The formidable development and investment in high-technology
diagnostic and therapeutic procedures for cardiovascular diseases (CVD) in past decades increased
survival. Age-adjusted mortality rates have decreased considerably in many European countries, that
is, people are living longer with heart disease. The actual challenge is an optimization of the disabilityfree
survival including active participation in social and economic life for patients after cardiovascular
events. However, resulting benefit is not automatically achieved through HI-TECH interventions and
pharmacotherapy alone but also through cardiovascular rehabilitation (CV-RHB) programs. AHA
and AACVPR define CV-RHB programs as: „Coordinated, multifaceted interventions designed
to optimize a cardiac patient’s physical, psychological, and social functioning, in addition to
stabilizing, slowing, or even reversing the progression of the underlying atherosclerotic processes,
thereby reducing morbidity and mortality„ (1).
A CV-RHB program is tailored to the individual needs and health condition of the patient and
the rehabilitation professional staff should set the exercise program according to the specific health
situation and goals (2, 3 and 4). Most cardiac rehabilitation programs in the Czech Republic last about
8 to 12 weeks. During that time, the patient may work with cardiologists, nurse educators, dietitians,
physiotherapists specialized in cardiovascular rehabilitation and psychologists.
CV-RHB classification
Current classification of CV-RHB has 4 main phases: Phase I (in-hospital); Phase II (outpatient)
which can be provided as a) ambulatory supervised program; b) spa treatment; and c) individual home
training. The remaining two phases are Phase III (stabilization period) and Phase IV (maintenance
period).
Phase I (early; in-hospital)
Ideally, the cardiac rehabilitation program starts while the patient is still in hospital. The duration of
this phase may vary depending on the initial diagnosis, the severity of the event and individual medical
institutions. CV-RHB program begins with non-strenuous activities, such as sitting up in bed, range-ofmotion
exercises and self-care, such as shaving. Then, the patients can progress to walking and limited
stair climbing. They can engage in the kinds of activities they will encounter once back at home.
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Phase II (outpatient; early recovery)
This phase of cardiac rehabilitation begins when the patient leaves the hospital and is often done
in a rehabilitation center. Most cardiac rehabilitation programs of Phase II in the Czech Republic
generally last about 8 to 12 weeks. During this phase, the patient gradually increases his activity level
under the close supervision of cardiac rehabilitation team. The CV-RHB team might suggest exercises
which can be safely do at home, such as walking, gentle calisthenics. The patient can also learn about
eating a healthy diet, quitting smoking, coping with health condition, resuming sexual activity and
finding social support. If the patient doesn’t have a nearby medical facility with a cardiac rehabilitation
center, the CV-RHB team can advise him about safe training at home. In the Czech Republic, the
Public health insurance covers fully the costs of cardiac rehabilitation Phase I and II.
Phase III and IV (ongoing recovery and maintenance)
This is a long-term maintenance program — something to follow for the rest of patient´s life. By
this point, the patient probably will have developed his own exercise routine at home or at a local gym.
The patient may also continue to exercise at a cardiac rehabilitation center. The patient may remain
under medical supervision during this time, particularly if he has special health concerns. Education
about nutrition, lifestyle and weight loss may continue, as well as counseling. For best success, it is
necessary to make sure the exercise and lifestyle practices become patient´s lifelong habits.
Indications and contraindications
Generally, the CV-RHB is indicated for all patients with the following diagnoses: coronary
interventions(PCI),coronaryrevascularization(coronaryarterybypassgraft),cardiacsurgery(valvular,
transplantation, congenital heart diseases), chronic stable AP, acute myocardial infarction (AMI), heart
failure, peripheral artery disease (PAD), and high-risk patients for cardiovascular disease (diabetes,
metabolic syndrome). The main contraindications for inclusion into the CV-RHB program are: sinusal
tachycardia (>120 bpm), systolic blood pressure (SBP >200 mmHg), diastolic blood pressure (DBP
>115 mmHg), symptomatic hypotension, acute infection, heavy aortic stenosis, dissecting aneurysm of
the aorta, unstable AP, acute heart failure, suspected pulmonary embolism, and ventricular tachycardia
or life-threatening arrhythmias (2).
CV-RHB program of Phase II
Time to start the CV-RHB program Phase II is within 3 weeks after acute coronary event („as soon
as possible“), and within 6 weeks after cardiosurgery or intervention (until then, walking and scar care
is recommended). Resistance training can be included only three months after intervention. Inclusion
in the outpatient CV-RHB program (Phase II) is submitted by cardiologist, internist, or general
practitioner. Before starting the CV-RHB, all patients are examined by a cardiologist who controls
them also in the whole course of the program. Before inclusion into the CV-RHB program, all patients
undergo a spiroergometric test to assess functional capacity and training intensity (4). Spiroergometric
test (Power Cube, Ganshorn®
Medizin Electronic, Niederlauer, Germany) is done using an incremental
ramp exercise protocol on bicycle ergometer (Ergoselect 200, Ergoline®
, Bitz, Germany). Twelve-lead
ECG is monitored continuously (AT-104 PC, Schiller®
, Baar, Switzerland). Patients are instructed to
maintain a stable RPM (60 rev.min-1
) and the workload is automatically increased gradually from 0 to
the tolerated maximum (W.min-1
). HR is continuously and automatically recorded during the test, and
BP is measured manually every 2 min. Standard ventilation and respiratory gas exchange parameters
NONINVASIVE METHODS IN CARDIOLOGY 2017
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(VO2
, VCO2
, ventilation – VE) are measured using the “breath by breath” method, peak oxygen
uptake (VO2peak
) is expressed as the highest value of O2
reached in the last 30 s of exercise. Peak HR
(HRpeak
) and peak workload (Wpeak
) are determined in the same way. Ventilatory anaerobic threshold
(VAT-1) is determined by a standard method according to Wasserman (5). An identical protocol for the
spiroergometric test is also realized after completion of the CV-RHB program.
Training session of the ambulatory CV-RHB program
Structure of the training session during the first 2 weeks of CV-RHB program includes the „warmup“
period (10 min), aerobic endurance training on bicycle ergometers (40 min), and relaxation or
„cool-down“ period (10min). Total time of one session is 60min. The training is done 3x/week as
a group exercise (standard duration of the whole CV-RHB program is 12 weeks). After the first 2
weeks of CV-RHB program, a resistance training is added and the structure of the training session
is as follows: „warm-up“ period (10 min), aerobic training on bicycle ergometers (25 min), resistance
training (15min) and „cool-down“ period (10min) for total time 60min. This type of training is called
„combined“, and is applied during the 3rd – 12th week of CV-RHB program. HR and BP at rest are
measured regularly before the beginning of the training session (BP manually using manometer, and
HR continuously by wearable system Polar-Tester).
„Warm-up“ period of the CV-RHB training session consists of simple exercises (including
gymnastic tools) and dynamic stretching exercises, aiming to warm-up the body and muscle mass. The
„warm-up“ period takes place with a musical accompaniment under the guidance of a physiotherapist.
Aerobic (endurance) training on bicycle ergometers is automatically driven using software Ergosoft
2 (Ergoline® Co., Germany) which enables accurate setting of the training type, its intensity and the
continual recording of ECG curves (Fig. 1).
Figure 1: Aerobic endurance training on bicycle ergometers with software Ergosoft 2 (Dept. of Sports Medicine
and Rehabilitation, St.Anne´s Faculty Hospital Brno)
HR, BP and RPE are monitored during the whole training session. During the period of aerobic
(and resistance) training it is necessary to watch carefully any signs of poor exercise tolerance
(excessive dyspnea, stenocardia), significant overshoot of training HR, episodes of bradycardia or
arrhythmias, vertigo, collapse state, etc. Two basic variants of aerobic endurance training are provided
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to the patients included in the CV-RHB program: a) aerobic continuous endurance training (CT) with
constant workload interval training (IT); and, b) aerobic endurance training with variable intensity
(ʺon-offʺ mode). CT is applied with workload intensity at the level of the ventilatory anaerobic threshold
(VAT-1) determined by the spiroergometric test. IT is applied at the beginning of CV-RHB program or
permanently in low-tolerance patients (IT is less demanding than continuous). IT consists from 30-sec
workload (intensity at the level of VAT-1) which is alternated with a 60-sec relaxation phase (50% of
workload at VAT-1). Resistance training is realized using special multifunctional fitness system Tendo
HC COMPACT® (Czech Republic). One-repetition maximum test (1-RM) in weight (resistance)
training is the maximum amount of force that can be generated in one maximal contraction. The result
of this test (for each exercise) is used to determine the training workload at the level of 30%, 40%, 50%,
and 60% of 1-RM. The resistance training consists of a variety of specific exercises, such as benchpress
in sitting position, leg extension, pull-down the pulley in sitting position, pull-down the pulley in
standing position, etc. „Cool-down“ or relaxation phase typically includes low-intensity exercises, slow
walking, static stretching, special relaxation techniques and also Schultz autogenic training (10 min).
The purpose of the outpatient CV-RHB program is not only to improve the fitness, but also to motivate
the patient to adopt a healthy lifestyle based on regular physical activity, proper nutrition, mental wellbeing
and permanent smoking cessation. Counseling for smoking cessation is provided by the staff of
Central Pharmacy (St. Anne´s Faculty Hospital, Brno). Counseling for a healthy diet is provided by a
nutritionist (Department of Sports Medicine and Rehabilitation, St. Anne´s Faculty Hospital, Brno).
CV-RHB program of the Phase II and III, provided by the Dept. of Sports Medicine and Rehabilitation
(St. Anne´s Faculty Hospital, Brno), was founded in 1998 by Professor Jarmila Siegelova, in close
cooperation with the Swiss Cardiovascular Center in Bern (Switzerland), led by Professor Hugo Saner.
Conclusion
Adjusting to a serious health problem often takes time. Cardiac patients may feel depressed or
anxious, lose touch with their social support system, or have to stop working for several weeks. If
they get depressed, they should not ignore it, because depression can make the CV-RHB program
more difficult, as well as negatively influence the relationships and other areas of patients´ life and
health. Counseling provided by health professionals could help to learn healthy ways to cope with
depression and other feelings, and may also suggest medications such as antidepressants. Vocational
or occupational therapy can promote new skills to help the return to work. One of the most valuable
benefits of cardiac rehabilitation is often an improvement in the quality of life, both physical and
emotional. As the patient gets stronger and learns how to manage the health condition he can likely
return to a normal routine and enjoy life more. It is important to know that the chances of having a
successful cardiac rehabilitation program rests largely on the patient – the more dedicated he/she is
to following the program’s recommendations, the better he/she will do. Up until the 1970s, strict bed
rest was thought to be the best medicine after an acute cardiac event. Following discharge moderately
stressful activity such as climbing stairs was discouraged for a year or more. Dr. Thomas LEWIS
(1881 – 1945), an outstanding British cardiologist, wrote: „The patient is to be guarded by day and
night nursing and helped in every way to avoid voluntary movement or effort“. Dr. Lewis was the
author of the monograph “Diseases of the Heart” (1932) which was a medical bestseller at the time.
Today, CV-RHB program is regarded as a lifelong multidisciplinary approach which combines exercise
training, risk factor modification, medical surveillance, emergency support, and psychological and
vocational counseling. And what will be the patient´s main outcome of cardiovascular rehabilitation
in the long run? Although it may be sometimes quite difficult to start a cardiac rehabilitation program
when the patient does not feel well, he/she will benefit in the long run. Cardiac rehabilitation can
NONINVASIVE METHODS IN CARDIOLOGY 2017
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guide him through fear and anxiety as he/she returns to an active lifestyle, with more motivation and
energy to do the things he/she enjoys. Over the long term, he will gain strength, learn heart-healthy
behaviors, improve his/her diet, cut bad habits such as smoking, and learn how to cope with heart
disease. Although studies show the CV-RHB program can improve the quality of life and help to live
longer, many people are not even aware about. And despite the above-mentioned numerous benefits,
the role of physical activity is still underestimated and physical hypo- or inactivity remains highly
prevalent worldwide (6).
Bibliography
	 1.	Leon AS, Franklin BA, Costa F et al. Cardiac rehabilitation and secondary prevention of coronary
heart disease: an American Heart Association scientific statement from the Council on Clinical
Cardiology (Subcommittee on Exercise, Cardiac Rehabilitation, and Prevention) and the Council on
Nutrition, Physical Activity, and Metabolism (Subcommittee on Physical Activity), in collaboration
with the American association of Cardiovascular and Pulmonary Rehabilitation. Circulation 2005;
111(3): 369-76.
	 2.	Chaloupka V., Siegelova J., Spinarova L. et al. Rehabilitation in patients with cardiovascular disease.
Guidelines of the Czech Society of Cardiology. Cor Vasa 2006; 48(7-8): 127-45.
	 3.	Standards of Physiotherapy. Union of Physiotherapists (UNIFY) of the Czech Republic. PHYSIO/10.
Cardiovascular Rehabilitation. Vymazalova L. Acute Care, I phase. Mifkova L. Post-hospital Care,
II - IV phase. 1st revised version. Verlag Dashöfer, 2016.
	 4.	Mezzani A., Hamm L.F., Jones A.M. et al.: Aerobic exercise intensity assessment and prescription
in cardiac rehabilitation: A joint position statement of the European Association for Cardiovascular
Prevention and Rehabilitation, the American Association of Cardiovascular and Pulmonary
Rehabilitation and the Canadian Association of Cardiac Rehabilitation. Policy statement. Eur J
Prev Cardiol 2013; 20(3): 442-67.
	 5.	Principles of Exercise Testing and Interpretation (4th ed.). K. Wasserman, J. Hansen, D. Sue, W.
Stringer, B. Whipp, eds (2004). Lippincott Williams & Wilkins, Philadelphia, USA. 612 pages.
ISBN 7-7817-4876-3
	 6.	Hallal PC, Andersen LB, Bull FC and Lancet Physical Activity Series Working G. Global physical
activity levels: surveillance progress, pitfalls, and prospects. Lancet 380: 247-57, 2012.
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NONINVASIVE METHODS IN CARDIOLOGY 2017
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Effect of Cv-Rhb Program on Main Functional Parameters
and Arterial Stiffness in Patients with Cardiovascular Diseases
Alena Havelková, Leona Mífková, Petra Palanová, Veronika Mrkvicová, Michaela Spáčilová, Jiří
Jančík, František Várnay, 1
Jiří Jarkovský, 1Ladislav Dušek, Michaela Sosíková, Pavel Vank, Jarmila
Siegelová, Petr Dobšák
Department of Sports Medicine and Rehabilitation, St.Anne´s Faculty Hospital, Masaryk University Brno, Czech
Republic
1
Institute of Biostatistics and Analyses, Faculty of Medicine, Masaryk University, Brno, Czech Republic
Introduction
Regular exercise and diet habits are well-known determinants of the extent of arterial stiffening
in healthy aging (1 and 2). Both these lifestyle measures represent clinically valuable interventions
to improve arterial biomechanical properties beyond their impact on blood pressure (BP) and
other conventional risk factors (3). The association of aortic and proximal arterial stiffness with
cardiovascular and all-cause mortality is independent of conventional risk factors and strongest in
the setting of higher cardiovascular risk (4). Aerobic exercise has been attractive for reducing arterial
stiffness since the demonstration of improved systemic arterial compliance and aortic β-stiffness
index in healthy, sedentary young adults (5). Moreover, arterial properties after training were similar
to those in endurance athletes in spite of a relatively modest exercise dose (cycling 3 × 30 min per week
at 75% of maximum workload; 6). These short-term changes may argue for exercise-mediated arterial
adaptations being predominantly functional rather than structural in origin (7).
Patients and methods
Until now, we evaluated a group of patients with CAD (n = 171; 135 men, 36 women, mean age 65
± 11.7 yrs and mean EF 48.4 ± 12.4%). Forty two patients have hypertension, 120 dyslipidemia, 49
diabetes mellitus, 33 chronic heart failure (NYHA I-III), 19 valvular disease, and two patients were
transplanted. As mentioned above, a standard spiroergometric test („breath by breath“ analyzer Power
Cube, Ganshorn® Medizin Electronic, Niederlauer, Germany; 12-lead ECG monitoring by AT-104
PC, Schiller®
, Baar, Switzerland) on electromagnetically braked bike ergometer Ergoselect, Ergoline®
,
Bitz, Germany) was performed at baseline in all patients included in Phase II for assessment of peak
oxygen uptake (VO2 peak
), ventilatory anaerobic threshold (VT-1), peak workload (Wpeak) and peak
heart rate (HRpeak
) for determination of the functional capacity and training intensity setting. Arterial
stiffness was assessed by the cardio-ankle vascular index (CAVI) and measured by VaSera®
1500
(Fukuda Denshi Co, Tokyo, Japan) using a standard protocol described previously (8). Patients with an
ankle-brachial index (ABI) of less than 0.9 were excluded from this study.
Ethics
All the patients included have signed the “Patient´s Informed Consent”. The study was approved by
the local ethics committee and corresponds to the principles of the Helsinki Declaration (revised in
2013) and the GCP guidelines of the European Community.
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Statistics
Standard descriptive statistics was applied in the analysis: a) continuous variables: mean with 95%
confidence interval (CI) or standard deviation (SD) and median with 5th and 95th percentile; and,
b) categorical variables: absolute and relative frequencies. Statistical significance of CAVI changes
in time between admission and 6th week or 12th week was tested using paired t – test. All statistical
analyses were computed using SPSS 19.0.1 (IBM Corporation, 2010). A value p <0.05 was accepted as
boundary of statistical significance in all applied tests.
Results
Table 1 summarizes the results of main functional variables. Twelve weeks of supervised exercise
training significantly improved the aero-metabolic capacity (expressed as VO2peak
) and also the peak
workload. These findings are consistent with the previously published conclusions that purposeful
exercise in patients with CAD improves exercise tolerance and habitual activity and should be
considered as important lifestyle component. Supervised CV-RHB program resulted in a significant
decline of mean value of the parameter CAVI after 6 weeks from 8.65 ±1.55 to 8.6 ± 1.47 (P<0.05), and
to 8.5 ± 1.61 (P<0.01) after 12 weeks (Graph 1). Similarly, a prominent decrease of mean CAVI was
observed in the group of men (n = 135): from 8.85 ± 1.61 to 8.60 ± 1.48 (P<0.01), and to 8.50 ± 1.67
(P<0.01) at the end of CV-RHB program (Graph 2). The mean CAVI value in the group of women (n
= 36) declined after 6 weeks of exercise training from 8.60 ± 1.30 to 8.5 ±1.42, but the reducing trend
did not show a significant change (P< 0.061). Nevertheless, after the completion of 12-weeks CV-RHB,
the decrease of mean CAVI in this group was statistically significant (8.4 ±1.34; P<0.01; Graph 3). It
is likely that the non-significant decline of CAVI after 6 weeks of exercise training was influenced by
lower number of female patients included.
Table 1: Results of main functional parameters
NONINVASIVE METHODS IN CARDIOLOGY 2017
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Graph 1: Time-course of CAVI changes at baseline, after 6 and 12 weeks of CV-RHB (whole group; n = 171)
Graph 2: Time-course of CAVI changes at baseline, after 6 and 12 weeks of CV-RHB (group men; n = 135)
Graph 3: Time-course of CAVI changes at baseline, after 6 and 12 weeks of CV-RHB (group women; n = 36)
NONINVASIVE METHODS IN CARDIOLOGY 2017
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The applied training protocol was well tolerated by all the patients included in the study. No
abnormalities or life-threatening events were observed during the training period. There was no
evidence of severe arrhythmias, and pathologic changes of HR or blood pressure.
Discussion
Parameter CAVI is strongly associated with the presence and severity of coronary atherosclerosis
and is considered as useful predictor of coronary atherosclerosis in subjects with a risk factor for
cardiovascular disease (9). The obtained results confirmed our previously published data that regular
supervised CV-RHB program can promote a significant drop in arterial stiffness (10). Also in this
study the parameter CAVI has been shown to be a valuable diagnostic tool for precise monitoring
of adaptive vascular changes induced by long-term physical activity leading to reduced peripheral
resistance. The main mechanisms involved in vascular smooth muscle cell regulation include arterial
wall shear stress, nitric oxide production, vasomotor tone, oxidative stress and inflammation (11). Even
it seems that vascular functional adaptations following physical activity are independent of traditional
risk factors, concurrent BP drop may contribute to early de-stiffening (Figure 1).
Figure 1: Mean arterial pressure–stiffness curves demonstrate the biomechanical implications of arterial
functional vs. structural responses to aerobic exercise training. (1) Functional de-stiffening: Lower mean arterial
pressure translates to a reduction in stiffness by virtue of a shift in the curve’s operating point. (2) Structural
de-stiffening: A reduction in intrinsic stiffness of the arterial wall manifests in a downward shift of the entire
pressure-stiffness curve (dashed line). Reduced stiffness is evident for a given mean arterial pressure. (3)
Functional + structural de-stiffening: Combination of (1) and (2). Scheme modified (12)
Animal experiments proved long-term structural vascular adaptations by exercise training but
still remain difficult to demonstrate in humans (7). Increased arterial stiffness present in CAD may
have important implications for exercise capacity because it may determine the ischemic threshold
independent of stenosis severity (13). Physical activity such as endurance aerobic training can improve
endothelial dysfunction and arterial stiffness as well as myocardial perfusion in patients with CAD.
However, (14) in a detailed review article reported that the information about the effects of training
programs on AS in patients with CAD is still very rare (14). Thus, the generally observed reduction of
AS after exercise training is based only on a small number of studies. Moderate-intensity resistance
NONINVASIVE METHODS IN CARDIOLOGY 2017
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training seems to have a neutral effect on arterial properties in healthy individuals but given its
possible benefits for cardio-metabolic risk reduction (including BP lowering), further studies are
needed in populations with cardiovascular and metabolic diseases (15 and 16). Since exercise and
dietary interventions may reduce arterial stiffness by a variety of mechanisms, additive effects on
arterial stiffness are possible, but evidence is scarce. The present gold-standard lifestyle intervention
could arguably be based on the most successful interventions, such as regular aerobic exercise,
healthy diet habits, and body weight reduction. Although this combination should markedly reduce
arterial stiffness, poor adherence is a major drawback to intensive lifestyle modification. It must also
be acknowledged that even if it is possible to modify arterial properties non-pharmacologically, it
is still unclear whether this will translate to improved prognosis. However, given its fundamental
importance to arterial–ventricular coupling and cardiovascular function (Figure 2), the reduction of
arterial stiffness is crucially important and a challenge for future research. These observations suggest
that physical exercise is an effective, inexpensive lifestyle strategy for regeneration and stabilization of
the vascular system, which otherwise decreases with age and chronic vascular diseases.
Figure 2: Virtuous cycle by which enhancement of cardio-respiratory fitness and arterial de-stiffening may
promote each other. Improved fitness is associated with reductions in both arterial stiffness and blood pressure,
which not only lower central wave reflection and pulse pressure (in turn) but may also promote each other
within their own virtuous sub-cycle. Reduction in pulse pressure has distinct cardiac and vascular effects, the
former including a decrease in myocardial afterload coupled with enhanced coronary blood flow, and the latter
facilitating less endothelial damage and curtailing of atherosclerotic burden. These collective cardiovascular
adaptations serve to increase myocardial performance, a key determinant of exercise capacity (cardiorespiratory
performance) in patients with cardiovascular diseases. Scheme modified (13).
Conclusion
In conclusion, the supervised CV-RHB program applied in this study reduced significantly mean
AS in patients with CAD. Our study is very likely the first attempt to evaluate the effects of exercise
training program on arterial stiffness in patients with CD using the parameter CAVI (all published
trials evaluated AS by PWV, arterial augmentation index, etc. but no CAVI).
Acknowledgement
This study is supported by Fukuda Denshi Co. (Tokyo, Japan).
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Bibliography
	 1.	Tanaka H, Dinenno FA, Monahan KD et al. Aging, habitual exercise, and dynamic arterial
compliance. Circulation. 2000; 102: 1270–5.
	 2.	Zieman SJ, Melenovsky V, Kass DA. Mechanisms, pathophysiology, and therapy of arterial
stiffness. Arterioscler Thromb Vasc Biol 2005; 25: 932-43.
	 3.	Williams B. Evaluating interventions to reduce central aortic pressure, arterial stiffness and
morbidity–mortality. J Hypertens 2012; 30: 13-18.
	 4.	Vlachopoulos C, Aznaouridis K, Stefanadis C. Prediction of cardiovascular events and all-cause
mortality with arterial stiffness: a systematic review and meta-analysis. J Am Coll Cardiol 2010;
55: 1318–27.
	 5.	Cameron JD, Dart AM. Exercise training increases total systemic arterial compliance in humans.
Am J Physiol 1994; 266(2): 693–701.
	 6.	Kingwell BA, Cameron JD, Gillies KJ et al. Arterial compliance may influence baroreflex function
in athletes and hypertensives. Am J Physiol 1995; 268(1): 411–18.
	 7.	Safar ME, O’Rourke MF, Frohlich ED et al. In: Safar M., O’Rourke M., Frohlich E. (eds) Blood
Pressure and Arterial Wall Mechanics in Cardiovascular Diseases. Springer, London 2014. 552 p.
ISBN 978-1-4471-5198-2
	 8.	Shirai K, Utino J, Otsuka K, et al. A novel blood pressure-independent arterial wall stiffness
parameter; cardio-ankle vascular index (CAVI). J Atheroscler Thromb 2006; 13(2): 101-7.
	 9.	Nakamura K, Tomaru T, Yamamura S, et al. Cardio-ankle vascular index is a candidate predictor
of coronary atherosclerosis. Circ J 2008; 72(4): 598-604.
	10.	Havelková A, Mífková L, Palanová P et al. Effects of exercise training on arterial stiffness in
patients with ischemic coronary artery disease. In: Non-invasive Methods in Cardiology 2016.
Kenner T., Cornélissen G., Siegelová J., Dobšák P. (eds.). Masarykova univerzita Brno 2016, p.81-9.
ISBN 978-80-210-8391-2
	11.	Gates PE, Seals DR. Decline in large elastic artery compliance with age: a therapeutic target for
habitual exercise. Br J Sports Med. 2006;40:897-9.
	12.	Diourté B, Siché JP, Comparat V et al. Study of arterial blood pressure by a Windkessel-type
model: influence of arterial functional properties. Comput Methods Programs Biomed 1999; 60:
11–22.
	13.	Kingwell BA. Large artery stiffness: implications for exercise capacity and cardiovascular risk.
Clin Exp Pharmacol Physiol 2002; 29: 214–17.
	14.	Oliveira NL, Ribeiro F, Alves AJ et al.The effects of exercise training on arterial stiffness in
coronary artery disease patients: a state-of-the-art review. Clin Physiol Funct Imaging 2014; 34(4):
254-62.
	15.	Miyachi M. Effects of resistance training on arterial stiffness: a meta-analysis. Br J Sports Med.
2013;47:393-6.
	16.	Williams MA, Haskell WL, Ades PA et al. American Heart Association Council on Clinical
Cardiology; American Heart Association Council on Nutrition, Physical Activity and Metabolism.
Resistance exercise in individuals with and without cardiovascular disease: 2007 update: a scientific
statement from the American Heart Association Council on Clinical Cardiology and Council on
Nutrition, Physical Activity, and Metabolism. Circulation 2007;116:572-84.
NONINVASIVE METHODS IN CARDIOLOGY 2017
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CATkit: A Toolkit for Chronobiological Study with Diverse
Applications
Cathy Lee Gierke, Germaine Cornelissen
Halberg Chronobiology Center, University of Minnesota, Minneapolis, MN, USA
The study of biological rhythms is a rapidly growing area of study. Flexible, comprehensive tools
are key to successful research outcomes. A new tool is available to chronobiology researchers. CATkit
is freely available on CRAN, the Comprehensive R Archive Network, a repository of R packages.
As shown in Figure 1, CATkit includes both visualization tools and tools for quantitative analyses.
It has been used around the world for an array of applications and subject areas. The Halberg
Chronobiology Center received inquiries about CATkit from researchers at Universities across the US,
in India, United Kingdom, Norway, Scotland, The Netherlands, Turkey, Brazil, France and Germany
in biological, sociological, psychiatric, medical, computing and pharmacological subject areas (Lee
Gierke and Cornelissen, 2016).
Collaborations with CATkit
Chronobiology impacts can be seen across scientific domains. Here are a few of the people we have
worked with.
A colleague at the Experimental and Systems Pharmacology College of Pharmacy, Washington State
University, analyzed qRTPCR data using the cosinor analysis in CATkit. Data contained expression
profiles of 7 patients measured at 2, 5, 8, 11, 14, 17, 20 and 23 hours. Using this gene expression data,
they made comparisons between two classes of patients (day shift vs. night shift). Data were collected
from approximately 750 genes. Cosinor analysis is being used to investigate whether rhythms need to
be modelled by single- or multiple-components, and what are their respective periods.
The Halberg Chronobiology Center worked with these researchers to determine whether their data
were adequate for qualitative analysis tools, as well as methodologies and program parameterization.
Researchers at the Department of Digestive Diseases at Rush University Medical Center, in Chicago,
IL, have been studying multiple aspects of circadian misalignment in GI health. A recent project was
on the impact of night shift work on alcohol-induced intestinal permeability, which is a marker for
alcoholic liver disease. Measurements were made at 20, 0, 4, 8, and 12 hours.
The Halberg Chronobiology Center consulted with them on how to represent the time for each
data point. Time can be represented in a number of formats to accommodate data collection formats,
including as a date and time format, or as a number of hours from a given reference time.
A research group in the Physiology and Biophysics Department of the Institute of Biomedical
Sciences at the University of São Paulo, Brazil, has been using Mini Mitter behavioral and temperature
time series (sampled every 30 seconds during 30 or more days) as well as several variables collected in
groups of animals killed every 3 hours along the 24-hour scale to estimate circadian changes. These
researchers were looking for time series or biological rhythms analysis software for Macs, specifically
for cosinor analysis. We assisted them in the installation and setup of R, Rstudio and CATkit. As a
platform-independent tool, CATkit is easily used on Macs as well as PCs.
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In Kırşehir, Turkey, at Ahi Evran University, Department of Biology, the circadian time structure of
body temperature in the Anatolian ground squirrel is being studied. Body temperature from 28 ground
squirrels was recorded intraperitoneally before, during and after hibernation. In order to determine
how temperatures change with approaching hibernation, we helped our colleague with detrending,
defining inflection points, demonstrating how to perform least squares spectral analysis, and single- as
well as multiple-component cosinor analyses with CATkit.
A doctoral student at the Department of Obstetrics and Gynecology at the Haukeland University
Hospital in University of Bergen, Norway is analyzing the circadian rhythm of fetal heart rate. With
her mentor, she collected fetal heart rate every two seconds for up to 20 hours continuously. Mean fetal
heart rate per minute was used to reduce noise.
Our lab helped with assessment of data quality needed for cosinor, and the impact of various
sampling/binning intervals for the data (from 2 sec to 10 min). Population-mean cosinor was applied.
We discussed the necessity of keeping the actual times associated with the data when recording crosses
midnight, and worked with these colleagues on criteria for including/excluding too-short records while
retaining as much of the data as possible.
Future Enhancements
CATkit was developed according to formulae and practices refined by the Halberg Chronobiology
Center in Minnesota. There are many papers on the methods and theory for cosinor which have been
recently reviewed (Cornelissen, 2014).
We are planning to add parameter tests of the cosinor results. These are used to compare rhythm
parameters (MESOR, amplitude and acrophase) between two or more individuals, i.e., testing equality
of parameters considered singly or jointly.
The Population-Mean Cosinor (PMC) is another method that is important when inferences need
to be made for a population. Parameter estimates are based on the means of estimates obtained from
individuals representing a random sample of the population, where confidence regions for the true
parameters depend on the variability among individual parameter estimates. PMC will be added to
CATkit as well.
Parameter tests of PMC results will also be added to CATkit. These are used to compare rhythm
parameters (MESOR, amplitude and acrophase) between two or more populations, testing the equality
of parameters considered singly or jointly.
R is a commonly used statistical, array-based programming language. Source code can be
customized directly. CATkit is found on CRAN (R Core Team, 2017) at https://cran.r-project.org/
package=CATkit .
References
	 1.	Cornelissen G. Cosinor-based rhythmometry. Theoretical Biology and Medical Modelling 2014;
11, 16. DOI: 10.1186/1742-4682-11-16
	 2.	Lee Gierke C, Cornelissen G. Chronomics analysis toolkit (CATkit). Biological Rhythm Research
2016; 47 (2):163–181. http://dx.doi.org/10.1080/09291016.2015.1094965
NONINVASIVE METHODS IN CARDIOLOGY 2017
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	 3.	R Core Team. R: A language and environment for statistical computing. R Foundation for Statistical
Computing, Vienna, Austria, 2017. https://www.R-project.org/.
Figure 1: CATkit includes a number of visualization tools, as well as toolsfor quantitative analyses
Correspondence:
Germaine Cornélissen
Halberg Chronobiology Center
University of Minnesota, Mayo Mail Code 8609
420 Delaware St. S.E. Minneapolis, MN 55455, USA
TEL +1 612 624 6976 FAX +1 612 624 9989
E-MAIL corne001@umn.edu
Website: http://halbergchronobiologycenter.umn.edu/
Support:
Halberg Chronobiology Fund
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NONINVASIVE METHODS IN CARDIOLOGY 2017
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Lessons Learned from Longitudinal Blood Pressure
Monitoring
Yoshihiko Watanabe1
, Larry Beaty2
, Kuniaki Otsuka1
, Jarmila Siegelova3
, Germaine Cornelissen2
1
Tokyo Women’s Medical University, Daini Hospital, Tokyo, Japan
2
Halberg Chronobiology Center, University of Minnesota, Minneapolis, MN, USA
3
Masaryk University, Brno, Czech Republic
Dedicated to the memory of Franz Halberg.
Abstract
A 12-year record of blood pressure measured automatically around-the-clock at 30-minute
intervals, with interruptions, by a 74-year old man treated for high blood pressure is analyzed to assess
blood pressure variability on a daily basis. The relative merits of a classification in terms of “dipping”
based on the day-night ratio are compared with those of a chronobiologic approach based on cosinor
rhythmometry to detect vascular variability disorders. Circadian rhythm characteristics show greater
stability than the day-night ratio. The circadian amplitude of this patient is found to be modulated by a
circannual variation that accounts for an about 10 mmHg larger blood pressure variation in the winter
than in the summer. Consequently CHAT (Circadian Hyper-Amplitude-Tension, a circadian amplitude
of blood pressure exceeding the upper 95% prediction limit in clinically healthy peers matched by
gender and age) is only diagnosed during winter months. This result may underlie the larger incidence
of adverse cardiovascular events in the winter than in the summer observed at mid-latitude geographic
locations.
Keywords
Blood Pressure, Cardiovascular Disease Risk, CHAT (Circadian-Hyper-Amplitude-Tension),
Circadian, Circannual, Day-Night Ratio, Dipping, Temperature, Vascular Variability Disorders.
Introduction
Many studies of blood pressure and blood pressure variability are performed based on clinic
measurements, some repeated during consecutive visits [1]. There has also been much interest in
ambulatory blood pressure monitoring (ABPM), which has correlated to cardiovascular disease risk
better than clinic measurements [1, 2]. These studies, however, are often limited to 24 or at best 48
hours. Longitudinal monitoring has been practiced by means of home measurements [1, 3], often
limited to morning and/or evening readings, which are insufficient to assess the circadian variation.
In addition to an elevated blood pressure, blood pressure variability has also been associated with
cardiovascular disease risk [4]. A measure of blood pressure variability often used is the day-night
ratio, used for a classification in terms of “dipping” [5], even though alterations in the 24-hour rhythm
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characteristics of blood pressure have been shown to have a higher predictive value in several outcome
studies [6, 7].
The relative merits of assessing alterations in the circadian variability of blood pressure and heart
rate in terms of Vascular Variability Disorders [8, 9] or the “dipping” status in terms of the day-night
ratio are assessed herein based on a longitudinal record spanning 12 years from a patient treated for
high blood pressure.
Subject and Methods
The patient (MM) is a 74-year old hypertensive man at the start of longitudinal monitoring on
15 April 2003. The diagnosis of MESOR-hypertension prompted the initiation of treatment with the
calcium antagonist benidipine hydrochloride (4 mg/day) on 22 April 2003. Several adjustments to his
treatment were needed to bring his blood pressure within acceptable limits. The dose of benidipine
hydrochloride was increased to 8 mg/day on 11 June 2003, then to 12 mg/day on 5 August 2003, and to
16 mg/day on 5 October 2003. On 3 February 2004, the angiotensin II receptor antagonist telmisartan
(20 mg/day) was added, and on 4 March 2004, the dose of telmisartan was increased to 40 mg/day.
Thereafter, the patient remained on this anti-hypertensive regimen until his death in January 2015.
From 15 April 2003 to 7 January 2015, MM measured his systolic (S) and diastolic (D) blood
pressure (BP) and heart rate (HR) at 30-minute intervals around the clock by ABPM (A&D, Tokyo,
Japan), with occasional interruptions. Mean arterial pressure (MAP=SBP/3+2DBP/3), pulse pressure
(PP=SBP-DBP), and the pulse pressure product (PPP=SBPxHR/100) were computed. Oscillometric
measurements were used for analysis. Unfortunately, data covering about 1 year (in 2007) were lost.
Figure 1 displays the entire record of SBP.
Figure 1: Complete 12-year record of systolic blood pressure of patient MM (M, 74 years at start).
© Halberg Chronobiology Center
The data were analyzed by sphygmochron [10], overall, by year, and for consecutive days.
Parametrically, a 2-component model consisting of cosine curves with periods of 24 and 12 hours
was fitted to the data to yield estimates of the MESOR (M, a rhythm-adjusted mean), the 24-hour and
12-hour amplitudes (A) and acrophases (φ) (measures of half the extent of predictable change within
a cycle, respectively). Non-parametrically, the percentage time elevation, extent and timing of excess
above time-specified reference values qualified by gender and age, were computed. The day-night ratio
(DNR) was also computed as DNR = (daytime mean – nighttime mean)/24-hour mean, where daytime
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is the span from 10:00 to 20:00 and nighttime is the span from 00:00 to 06:00. The DNR is used for
classification in terms of ‘dipping”: Reverse Dipping (RD) when DNR < 0; Non-Dipping (ND) when
0 < DNR < 10%; Dipping (DP) when 10% < DNR < 20%; and Extreme Dipping when DNR > 20%.
Circadian rhythm characteristics (M, A, φ) at a trial period of 24 hours were also estimated based
on hourly estimates of the original data. Diagnoses based on these estimates considered herein include:
MESOR-Hypertension (MH) when the SBP-M and/or DBP-M exceed(s) the upper 95% prediction
limit of clinically healthy peers matched by gender and age; Excessive Pulse Pressure (EPP) when
PP > 60 mmHg; CHAT (brief for Circadian Hyper-Amplitude-Tension) when SBP-A and/or DBP-A
exceeds the upper 95% prediction limit of clinically healthy peers matched by gender and age; ecphasia
(ecφ) when SBP-φ and/or DBP-φ, but not HR-φ lie(s) outside the respective 90% prediction intervals
of clinically healthy peers matched by gender and age; and Decreased Heart Rate Variability (DHRV)
when the standard deviation (SD) of HR is below 7.5 beats/min.
In view of occasional interruptions of monitoring, criteria needed to be defined to decide whether
data were sufficient to obtain reliable estimates of all parameters of the daily analyses. Estimates of
M, A, φ were deemed acceptable when they were computed based on at least 16 hourly average values.
Estimates of the DNR were viewed as acceptable when they were computed on at least 20 original data
that included at least 3 nightly and at least 4 daytime measurements. Over the 12-year record, there
were 1,969 (44.9%) days with sufficient data to yield acceptable estimates of both DNR and (M, A, φ)
for a comparison of the occurrence of abnormal patterns of BP and/or HR.
Results
Overall, dipping occurred only 35.6% (SBP) or 30.1% (DBP) of the time. Abnormal DNR values
were thus present most of time. They differed, however, from one day to another, with non-dipping
found 21.5% (SBP) or 14.1% (DBP) of the time, reverse dipping 4.2% (SBP) or 2.7% (DBP) of the time,
and extreme dipping 38.7% (SBP) or 53.0% (DBP) of the time. Daily estimates of the DNR varied
between -7.7 and 41.7 for SBP and between -8.4 and 44.6 for DBP, averaging (mean ±SD) 17.4 ± 8.8 in
the case of SBP and 20.9 ± 10.1 in the case of DBP. These values cover all 4 categories of “dipping”.
Even based on data collected over consecutive years, the diagnosis in terms of “dipping” changed
from one year to another. In the case of SBP, the DNR varied from 7.6 (ND) in 2003 to 20.8 (ED)
in 2006. Excluding 2003 when treatment was being adjusted, the DNR varied from 12.6 in 2013 to
20.8, averaging (mean ± SD) 17.6 ± 2.8. Likewise in the case of DBP, the DNR varied from 11.7/16.9
(including/excluding 2003) to 25.8, averaging 21.5 ± 3.1.
As seen in Figure 2 for the case of SBP, the large variability in the DNR is not completely random. It
follows an about yearly variation. It tends to be higher during the winter and lower during the summer.
Similar results are also observed in the case of DBP.
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Figure 2: Daily estimates of the day-night ratio (DNR) vary greatly. DP occurs less than one third of the time.
While RD only occurs less than 5% of the time, ED occurs about twice as often as ND. The DNR tends to be
larger in winter and smaller in summer. © Halberg Chronobiology Center
As seen from Figure 3, once treatment has been adjusted, the MESOR of SBP remains within
acceptable limits most of the time. Only towards the end of the record does SBP-M decrease below
the lower 5% prediction limit of clinically healthy peers matched by gender and age. This trend is
in agreement with the time course of SBP-M as a function of age found in healthy populations [11].
Treatment was successful in keeping PP within the acceptable range most (91.1%) of the time, but at
the cost of lowering DBP-M below the lower 95% prediction limit during a non-negligible number of
days (22.8% of the time), mostly during the second half of the 12-year record.
Figure 3: Daily estimates of SBP-M are within acceptable limits most of the time once anti-hypertensive
treatment has been adjusted. © Halberg Chronobiology Center
Treatment may have contributed to lowering HR below the lower prediction limit in health, and
HR-SD below 7.5 beats/min 63.6% of the time. Whereas SBP-A and DBP-A are within acceptable
limits most of the time, SBP-CHAT and DBP-CHAT are present 31.9% and 16.2% of the time,
respectively. By comparison, ED was 38.7% (SBP) and 53.0% (DBP). The horizontal black line in
Figure 4 indicates the upper limit of acceptability for SBP-A for clinically healthy peers matched by
gender and age. Above this limit for SBP-A, outcome studies document a marked increase in adverse
cardiovascular outcomes.
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As seen in Figure 4, SBP-A is modulated by the circannual variation. It is larger in winter and
smaller in summer. Similar results are found for DBP. When data are analyzed over consecutive 7-day
records, as recommended in a consensus document [8, 9], CHAT is only found in winter.
The presence of VVDs from sphygmochron analyses performed over consecutive years shows
more consistency than results presented above for the DNR. MESOR-Hypertension and Excessive
Pulse Pressure are only found in 2003 when treatment was initiated and adjusted for dosing. Systolic
MESOR-hypotension is only found during the last year of monitoring and may have reflected a natural
decline in SBP-M with age [11]. All BP parameters are within acceptable limits, including SBP-A and
DBP-A. Only HR-M is consistently below the lower 5% limit of acceptability, varying between 57.3
beats/min during the last year of monitoring in 2014 and 63.6 beats/min in 2004. It may have resulted
from the anti-hypertensive treatment since in 2003 HR-M was 66.6 beats/min, within acceptable limits.
Likewise, HR-SD tends to be too low, decreasing below 7.5 beats/min from 2008 to 2011.
Figure 4: Daily estimates of SBP-A vary greatly. Modulation by the circannual variation accounts for the
fact that CHAT is found 31.9% of the time, but only in winter, SBP-A being larger in winter than in summer.
© Halberg Chronobiology Center
Discussion and Conclusion
Least squares spectral analysis of SBP-A as it varied over 12 years detects a peak at a frequency
of one cycle per year. Its amplitude is estimated to be about 5 mmHg. This means that SBP-A can
be expected to differ by about 10 mmHg between summer and winter. It is a much larger circannual
variation than what can be observed for the MESOR of blood pressure. A circannual variation in the
circadian rhythm characteristics of blood pressure was already noted earlier in another longitudinal
record of a clinically healthy man [12]. Depending on the clock hour of daily measurements, blood
pressure peaks in different seasons. The fact that measurements taken around midnight peak in the fall
whereas morning measurements peak in the summer and afternoon measurements peak in the winter
was interpreted as a circannual modulation of the circadian amplitude of blood pressure [12], Figure 5.
NONINVASIVE METHODS IN CARDIOLOGY 2017
154
Figure 5: The change in circannual peak in blood pressure measurements depending on the clock hour when they
were taken can be accounted for by a circannual modulation of the circadian amplitude of blood pressure.
© Halberg Chronobiology Center
Environmental cues have been reported to account for a larger proportion of the variability in
the day-to-night ratio as compared to genetics [13]. Season and temperature accounted for about 8%
of the variance in night-to-day ratio, whereas genetics accounted for less than 1% [13]. A similar
conclusion was reached in another study: variation in the day-night difference in blood pressure was
reportedly largely non-genetic [14]. Age, total cholesterol, plasma triglycerides, and current smoking
were found to be associated with the day-night difference in SBP, whereas age, plasma triglycerides,
and current smoking were reportedly associated with the day-night difference in DBP [14]. The direct
association between meteorological factors and circadian blood pressure variability has also been
examined in 158 subjects who provided 7-day/24-hour ambulatory records [15]. The magnitude of
the nocturnal decrease in blood pressure was larger by about 2 mmHg on average on the coldest day
than on the warmest day [15]. The incidence of adverse cardiovascular events is also larger in winter at
mid-latitude geographic locations [16]. An increase in blood pressure variability during spans of cold
weather may complicate the diagnosis and management of hypertension and may contribute to the
high cardiovascular mortality observed in winter [17].
In summary, day-to-day variability in circadian rhythm characteristics may account in part for the
larger-than-expected incidence of abnormalities detected based on 24-hour records. Results support
our recommendation of around-the-clock monitoring for at least 7 days at the outset [8, 9]. Both systolic
and diastolic CHAT are detected mostly during winter months.
Systolic MESOR-Hypertension was present at the beginning of the record and was corrected by
medication. While the DNR undergoes a yearly variation, RD, ND, DP, and ED occur throughout
the year. The limited reproducibility of a classification in terms of “dipping” has been noted earlier
[18]. CHAT is present only between October and May, mostly during the winter months. Reference
limits may need to account for the circannual variation. The higher incidence of CHAT in the winter,
however, is in keeping with the then-higher likelihood of adverse cardiovascular events observed on a
population basis [19, 20].
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Correspondence:
Germaine Cornélissen
Halberg Chronobiology Center
University of Minnesota, Mayo Mail Code 8609
420 Delaware St. S.E. Minneapolis, MN 55455, USA
TEL +1 612 624 6976 FAX +1 612 624 9989
E-MAIL corne001@umn.edu
Website: http://halbergchronobiologycenter.umn.edu/
Support:
Halberg Chronobiology Fund
University of Minnesota Supercomputing Institute
A&D (Tokyo, Japan)
NONINVASIVE METHODS IN CARDIOLOGY 2017
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Spaceflight and Geriatrics
Nandu GOSWAMI
Institute of Physiology, Medical University of Graz, Austria
Abstract
Physiological deconditioning similar to that seen in spaceflight also occurs on Earth, especially as
a consequence of the aging process and also due to bedconfinement and/ or immobilization. Illness or
injury in older persons frequently requires hospitalized based care. However, the immobilization that
occurs during hospitalisation is itself a major factor in physiological deconditioning and functional
decline and in older persons can further contribute to a downward spiral of increasing frailty, dizziness
upon standing up (orthostatic intolerance) and increased risk and incidence of falls.
Bedrest is used as a ground-based analog for studying the effects of weightlessness on physiological
systems as seen during space flight. As older persons spend up to 80% of their time in hospital bedconfined,
bedrest studies can also help in furthering our understanding of the deconditioning process
during hospitalization in older persons.
Astronauts in space spend substantial time doing physical training to counteract the deconditioning
due to the effects of microgravity and to alleviate orthostatic intolerance on return to Earth. Could such
physical activity programs carried out by astronauts in space be used during bedrest immobilization in
older persons to counteract deconditioning as well?
Recent data generated from bedrest studies related to space research suggest that resistance exercise,
together with proper nutrition, is effective in maintaining physiological functionality in astronauts
during spaceflights of up to six months duration. Similarly, some studies have suggested that nutritional
therapy (e.g high protein diet), along with resistance training, improves lean muscle mass and muscle
strength in older persons.
This presentation discusses how knowledge obtained from space research can provide guidance
towards optimising health care strategies to tackle bed-confined deconditioning, especially in older
persons (”Spaceflight meets Geriatrics!”).
Assoz. Prof. Priv.-Doz. Dr. med. Nandu Goswami, MMedSci PhD.
nandu.goswami@medunigraz.at
NONINVASIVE METHODS
IN CARDIOLOGY 2017
Edited by: Cornélissen G., Siegelová J., Dobšák P.
Published by Masaryk University in 2017
First edition, 2017
Print run: 60 copies
Printed by Tiskárna Knopp s.r.o., U Lípy 926, 549 01 Nové Město nad Metují
ISBN 978-80-210-8794-1