Masaryk University • Faculty of Medicine • Brno • Czech Republic
NONINVASIVE METHODS
IN CARDIOLOGY
2015
Edited by: Kenner T., Cornélissen G., Siegelová J., Dobšák P.
Brno 2015
© 2015 Masarykova univerzita
ISBN 978-80-210-8031-7
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: doc. MUDr. Dušan Salát, CSc.
CoNtents
The properties of blood and its modifications by body position and by
vascular reactions.................................................................................................................. 5
Thomas Kenner and Dieter Platzer
Why 7-day/24-hour Ambulatory Blood Pressure Monitoring?
Day-to-Day Variability in Blood Pressure
and the Novelty Effect.......................................................................................................... 9
Germaine Cornélissen, Kuniaki Otsuka, Yoshihiko Watanabe, Cathy Lee Gierke, Larry Beaty,
Alena Havelkova, Jiri Dusek, Jarmila Siegelova
Applications of Chronobiologically-Interpreted 7-day/24-hour
Ambulatory Blood Pressure Monitoring: From Health
Maintenance and Primary Prevention to Chronotherapy............................. 19
Germaine Cornélissen, Kuniaki Otsuka, Yoshihiko Watanabe, Francine Halberg,
Julia Halberg, Larry Beaty, Jiri Dusek, Alena Havelkova, Jarmila Siegelova
Demonstration of Cosinor-Based Analyses Using the Chronomics
Analysis Toolkit in R.............................................................................................................. 37
Cathy Lee Gierke, Yoshihiko Watanabe, Jarmila Siegelova, Jiri Dusek, Kuniaki Otsuka,
Germaine Cornélissen
Recent Progress in the study
of the Cardio-Ankle Vascular Index (CAVI)............................................................... 49
Tomoyuki Yambe, Yasuyuki Shiraishi, Hidekazu Miura, Yusuke Inoue,
Yusuke Tsuboko, Akihiro Yamada, Yasunori Taira, Shota Watanabe,
Yuri A Kovalev, Irina A Milyagina, Mitsuya Maruyama
Current progress of a non-invasive peripheral perfusion
evaluation during mechanical circulatory support........................................ 55
Yasuyuki Shiraishi, Kazumasu Sasaki, Tomoya Kitano, Kyosuke Sano, Shota Watanabe,
Yusuke Inoue, Yasunori Taira, Yusuke Tsuboko, Hidekazu Miura, Akira Tanaka,
Makoto Yoshizawa, Tomoyuki Yambe
PROF. MUDR. ZDENĚK PLACHETA, DRSC. 4. 4. 1931 - 1. 11. 2014............................................ 61
Jarmila Siegelová
PROF. MUDR. MIROSLAV MIKULECKÝ, DRSC. 22. 6. 1927 - 25. 1. 2015.................................. 67
Jarmila Siegelová
SEVEN-DAY AMBULATORY BLOOD PRESSURE MONITORING
AT REST AND DURING EXERCISE: VARIABILITY
OF NIGHT-TO-DAY BLOOD PRESSURE RATIO.......................................................................... 69
Siegelová J., Havelková A., Dušek J., Dunklerová L., Pohanka M., Dobšák P., Cornélissen G.
SEVEN DAY BLOOD PRESSURE VARIABILITY AT REST AND DURING
EXERCISE IN HEALTHY MEN AND PATIENTS......................................................................... 79
Siegelová Jarmila, Havelková Alena, Dušek Jiří, Pohanka Michal, Dunklerová Leona,
Dobšák, Petr, Cornélissen Germaine
INTRA-DIALYTIC EXERCISE TRAINING COULD IMPROVE VASCULAR
TONE IN HEMODIALYZED PATIENTS: A PRELIMINARY REPORT....................................... 99
Palanova P., Mrkvicova V., Reichertova A., Brychtova S., Nedbalkova M., Vank P., Sosikova M.,
Homolka P., Havelkova A., Soucek M., Kohzuki M., Siegelova J., Dobsak P.
The use of neuromuscular electrical stimulation in early
phase of rehabilitation in patients after total knee
arthroplasty to enhance quadriceps femoris muscle strength...............111
Mrkvicová V., Palanová P., Turoňová R., Siegelová J., Dobšák P.
THE ROLE OF STRUCTURAL AND FUNCTIONAL
ASYMMETRY IN THE CIRCULATION........................................................................................117
Thomas Kenner, Dieter Platzer
WHAT WE CAN LEARN FROM MODELING CARDIAC FUNCTION?................................... 125
Dieter Platzer, Klaus Zorn-Pauly, Thomas Kenner
NONINVASIVE METHODS IN CARDIOLOGY 2015
5
The properties of blood and its modifications
by body position and by vascular reactions
Thomas Kenner and Dieter Platzer
Medical University Graz, Austria
Overview
In 1977 we had the opportunity to use a so called oscillator technique for the continuous measurement
of the mechanical density of fluids. The device was developed by O. Kratky and coworkers (1969)
and constructed by A. Paar KG  in Graz. The working group at the department of physiology
performed measurements of blood in animal experiments and also in a patient during hemodialysis.
A summary of the first results were published at the 13th International Conference on Medical and
Biological Engineering (1982).  Here I report about the doctoral dissertation by F. Vauti in 1984. Body
temperature, heart rate, blood pressure, blood density, plasma density and hematocrit, hematocrit,
number of erythrocytes and of leucocytes were measured in capillary blood during day and night
for 48 hours. In addition to the results in Dr. Vauti’s dissertation [1], measurements performed in a
healthy person in a laboratory of the Surgical Clinic have been made. The most surprising result was
that the oscillations of the arterial blood density were synchronized with the respiration. In summary,
all measurements demonstrated synchronizations. This could be observed between blood density and
time of day and between blood density and respiration. 
Blood Density and Vascular Reactions
Many physiological as well as pathological processes of life exhibit periodic patterns. As
repeatedly presented and discussed by Professor Franz Halberg these processes exhibit characteristic
interconnections as well as frequencies. Chronobiological research has therefore important diagnostic
as well as therapeutic relevance. Also in daily life with its circadian rhythms effects of environmental
changes strongly depend on the specific timing. Additional influences include the body position and
gravitational changes e.g. during space flight.
As mentioned above, data from blood density measurements reveals respiration as significant
determinant of blood density fluctuations. Registrations from the cubital artery of a human person
demonstrate the influence of the breathing on the arterial blood density. Figure 1 shows that the
amplitude of the density changes depends on the breathing period: in this case the amplitude exhibits
a maximum at a period of 20 seconds.
NONINVASIVE METHODS IN CARDIOLOGY 2015
6
Figure 1: Density of arterial blood in the cubital artery during rhythmic breathing.
(4 experiments in one person.)
Evans and Lee (1987) [2] reported equivalent results from measurements on artificially ventilated
dogs. They deduced from the density fluctuations the percentage volume change of pulmonary
capillaries. Both investigations indicate the potential of blood density measurement technique for in
vivo assessment of the viscoelastic properties of the pulmonary capillaries. A comprehensive overview
of density measurement applications can be found in Kenner (1982) [3].
Body Position and Gravitation
Many physiological parameters are influenced by gravitation and its direct effect on the body fluids.
Tilting a person from horizontal into upright position induces hemoconcentration and increase of the
hematocrit as a consequence of the increased fluid filtration in the lower body (Figure 2).
Figure 2: Time course of Ht (hematocrit, dashed line) and ρ (blood density, dottet line) – during changes the
body position.
NONINVASIVE METHODS IN CARDIOLOGY 2015
7
Vauti [5] sampled capillary blood from the earlobes of six healthy young men in supine (0°) and
upright (70°) head up tilt position. The subjects rested on a tilt table in supine position for 50 minutes.
Subsequently blood was sampled 4 times in intervals of 10 minutes. Tilting the body into upright
position, blood was taken after 30 and 40 minutes of orthostatic load. The subjects were instructed to
minimize tonus in the respective muscles. The protocol was repeated every three hours over a period
of 48 hours (Figure 3)
Figure 3: Circadian rhythms of blood values in supine (continuous line) and standing (dotted line) position.
Data are plotted as deviations from the 24h average.
NONINVASIVE METHODS IN CARDIOLOGY 2015
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Blood samples were used for the determination of hemoglobin (Hb), hematocrit (Ht) and erythrocyte
count (EC), whole blood density (BP) and plasma density (PD). The observed variations of parameters
can be explained by corresponding changes of water content in the plasma. It has to be noted that the
investigations by Vauti also reveal a pronounced circadian modulation of the hematological parameters.
This finding underlines the importance of chronobiological research.
References
	 1.	F. Vauti: Der Einfluss der circadianen Rhythmik auf hämatologische und cardiovasculäre
Parameter beim Menschen in der Orthostase unter besonderer Berücksichtigung der transkapillären
Flüssigkeitsverschiebung.  INAUGURAL-DISSERTATION,  Graz, 1984
	 2.	M.V. Evans, E.S. Lee, L.P. Lee: Time shift in ventilation-induced density fluctuations of arterial
blood. Annals of Biomedical Engineering 15, 1-17, 1987
	 3.	T. Kenner: Physiological Measurement in Circulation Research. Med. Prog. Through Technol. 9,
67-74, 1982
	 5.	F. Vauti, M. Moser, H. Pinter, T. Kenner: Day course of blood and plasma density in relation to
other hematological parameters. Physiologist 28 (6 Suppl), 171-2, 1985
NONINVASIVE METHODS IN CARDIOLOGY 2015
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Why 7-day/24-hour Ambulatory Blood
Pressure Monitoring?
Day-to-Day Variability in Blood Pressure
and the Novelty Effect
Germaine Cornélissen1
, Kuniaki Otsuka2
, Yoshihiko Watanabe2
,
Cathy Lee Gierke1
, Larry Beaty1
,
Alena Havelkova3
, Jiri Dusek3
, Jarmila Siegelova3
1
Halberg Chronobiology Center, University of Minnesota,
2
Tokyo Women‘s Medical University, Daini Hospital, Tokyo, Japan,
3
Masaryk University, Brno, Czech Republic
Dedicated to the memory of Franz Halberg and Bohumil Fiser
Abstract
Blood pressure (BP) and heart rate (HR) vary greatly, from one individual to another and from
moment to moment in any longitudinal record. Variability in BP and HR can be accounted for by
genetics, epigenetics, and in response to a variety of stimuli. Reference values in health provide
guidelines to distinguish between usual and abnormal variability in BP and/or HR, in terms of deviant
circadian characteristics and/or excess/deficit relative to time-specified limits of acceptability. This
investigation examines the day-to-day variability in circadian rhythm characteristics determined from
analyses of 7-day/24-hour records obtained by ambulatory BP monitoring (ABPM) in Brno, Czech
Republic. A novelty pressor effect is quantified by comparing circadian parameters in consecutive
days of monitoring. Results interpreted in terms of clinical implications indicate the need to monitor
BP around the clock for longer than 24 hours, preferably for 7 days at the outset, in keeping with
recommendations from the 2008 consensus meeting held in Brno.
Introduction
Blood pressure (BP) and heart rate (HR) vary greatly, from one individual to another and from
moment to moment in any longitudinal record [1-4]. An example is illustrated in Figure 1. A 24-hour
ABPM profile of systolic (S) BP is shown from two different patients. The circadian variation is
present in both cases, with lower values by night and higher values by day. Despite a similar 24-hour
MESOR (Midline Estimating Statistic Of Rhythm, a rhythm-adjusted mean), the two profiles differ
greatly in their circadian amplitude. Inter-individual differences are found not only in MESOR but also
in terms of their circadian variation, among others.
NONINVASIVE METHODS IN CARDIOLOGY 2015
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Figure 1: Different circadian patterns of systolic blood pressure (SBP) in two clinically healthy men.
© Halberg Chronobiology Center.
As documented in detail previously [5-7] and illustrated in Figure 2, 7-day/24-hour ABPM records
allowed the demonstration of a great deal of day-to-day variability in circadian rhythm characteristics
observed in the same subject. In part, this variability can be accounted for by differences between
work days and weekends/holidays [8].
Inter-individual differences in BP and HR can be accounted for genetics [9-12] and epigenetics [13].
BP and HR are also greatly influenced by a variety of stimuli (diet, exercise, emotions, temperature,
cosmic radiation, etc.) [14-21].
Elevated BP is asymptomatic, as are other abnormal patterns of BP variability, until there is target
organ damage. Like high BP, abnormal circadian characteristics of BP and HR variability are associated
with increases in cardiovascular disease risk, as documented by several outcome studies that led to the
2008 Brno consensus document [22].
For these reasons, it is important to accurately assess the circadian variation in BP and HR, and
to determine the extent of day-to-day variability in their circadian rhythm characteristics. This is the
purpose of this investigation which focuses more specifically on any novelty pressor effect, that is an
elevated BP at the start of monitoring, related to the habituation to repeated cuff inflation that may
bring about anxiety and inability to fully relax. The definition given in Wikipedia is “The novelty effect
is the tendency for an individual to have the strongest stress response the first time that individual is
faced with a potentially threatening experience”.
NONINVASIVE METHODS IN CARDIOLOGY 2015
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Figure 2: Extent of day-to-day variability in the circadian characteristics of systolic blood pressure from two
different subjects [6]. Data are shown with 24-hour cosine model fitted separately to consecutive days (left).
Daily estimates of the circadian amplitude (top, right), acrophase (middle, right), and day-night ratio (bottom,
right) are interpreted in the light of reference values from clinically healthy subjects matched by gender and age.
© Halberg Chronobiology Center.
Subjects and Methods
BP and HR were measured around the clock, mostly at 30-minute intervals for 7 days by 297
subjects in Brno, Czech Republic. The oscillometric readings from the TM-2421 ABPM monitor
(A&D, Tokyo, Japan) were used for analysis, as outlined previously [23]. Each record was analyzed
by sphygmochron [24] over the entire record, and separately during consecutive days. Specifically, a
2-component model consisting of cosine curves with periods of 24 and 12 hours was fitted to the data
by cosinor [25-28]. To assess the novelty pressor effect, the parameters of the 24-hour component on
days 2-7 were compared to those of day 1 by paired t-test.
Results
Because not all subjects monitored for 7 days, and in view of interruptions preventing a reliable
estimate of circadian parameters on some days, the reference group on day 1 differed slightly for
NONINVASIVE METHODS IN CARDIOLOGY 2015
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comparison with results on days 2-7. Data from 262, 258, 253, 246, 242, and 231 subjects were available
for comparisons on days 2-7 vs. day 1. Average estimates of circadian parameters on day 1 did not
differ whether all subjects or only subjects providing sufficient data on days 2-7 were considered.
The MESOR of SBP, diastolic (D) BP, HR, pulse pressure (PP, difference in MESOR between SBP
and DBP), the 24-hour amplitude of SBP, DBP, and HR, and the standard deviation (SD) of HR were
compared.
Figure 3: As compared to estimates on day 1 (used as reference; equated to 0), all circadian parameters are
lower when they are estimated on the entire record. SBP: Systolic BP; DBP: Diastolic BP; PP: Pulse Pressure;
-M: MESOR; -2A: double 24-hour amplitude (extent of predictable change within one cycle).
SBP, DBP, PP in mmHg; HR in beats/min.
© Halberg Chronobiology Center.
By contrast, all circadian parameters are elevated on day 1 as compared to estimates obtained from
the entire record, Figure 3. Moreover, all circadian parameters are elevated on day 1 as compared to
estimates obtained on subsequent days. As shown in Figure 4, the extent and duration of the novelty
effect depends on the circadian parameter considered. The MESOR of SBP and DBP is consistently
lower on days 2-7 as compared to day 1 (P<0.001). In the case of DBP, the MESOR continues to
decrease from day 2 to day 4, suggesting that the novelty effect may last more than one day. Pulse
pressure is also consistently lower on days 2-7 as compared to day 1 (P<0.05), but the difference is
small on average (about 1 mmHg or less). Only a small decrease in the MESOR of HR is observed on
days 2 and 3 (about 1 beat/min) before returning toward values similar to those of day 1.
NONINVASIVE METHODS IN CARDIOLOGY 2015
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Figure 4: Estimates of circadian characteristics on day 1 are used as reference (zero) to assess change on days
2-7, on the average across all subjects.
© Halberg Chronobiology Center.
NONINVASIVE METHODS IN CARDIOLOGY 2015
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The circadian double amplitude of SBP and DBP is also larger on day 1 as compared to subsequent
days. By contrast, no statistically significant change is found for the double amplitude of HR. The
initial decrease in the SD of HR observed on days 2 and 3 is small and is followed by a progressive
increase toward values assumed on day 1, Figure 4.
Part of the day-to-day variability in BP and HR is contributed by the about-weekly (circaseptan)
and half-weekly (circasemiseptan) variation, invariably detected (N=276 subjects) with statistical
significance by population-mean cosinor (P<0.005). Maxima occur on Mondays with a secondary
peak toward the end of the week, as illustrated in Figure 5 for SBP, DBP, and HR.
Figure 5: Model about-weekly variation in SBP (left), DBP (middle),
and HR (right) based on results from the population-mean cosinor (N=276 subjects).
© Halberg Chronobiology Center.
Clinical Implications
Whereas there is consensus that 24-hour ABPM is superior to clinic measurements in terms of
diagnosis and prognosis [25], the limitations of 24-hour ABPM are not widely recognized. Both the
novelty pressor effect and the circaseptan variation contribute to these limitations, as do the many
events in everyday life. As shown herein, not only is the 24-hour average (MESOR) BP affected, so
are the circadian rhythm characteristics. From a clinical point of view, this means that a bias from the
novelty pressor effect can be expected to affect not only the diagnosis of MESOR-hypertension, but
also that of CHAT (Circadian Hyper-Amplitude-Tension, defined as an excessive circadian amplitude
of BP, a condition associated with an increased cardiovascular disease risk [22]).
In order to gain a better understanding of the actual limitations associated with ABPM limited to 24
hours, the data from the Brno database were further analyzed by sphygmochron to compare results of
analyses of data collected on consecutive days with those considering the entire record. We found that
abnormality on at least 1 day was found in all but 7 subjects. Different kinds of abnormalities of BP, HR
and their variabilities, known as Vascular Variability Anomalies (VVAs) were detected. They include
systolic MESOR-hypertension (S-MH), diastolic MESOR-hypertension (D-MH), excessive pulse
pressure (EPP: PP>60 mmHg), systolic CHAT (S-CHAT), diastolic CHAT (D-CHAT), deficient HR
variability (DHRV: HR-SD<7.5 beats/min), systolic ecphasia (S-ecPhi: an odd timing of the circadian
variation of BP but not of HR), and diastolic ecphasia (D-ecPhi). These conditions were found to occur
on at least 1 day in 33, 30, 14, 51, 46, 26, 56, and 68% of subjects, respectively. By comparison, only
15, 14, 5, 8, 6, 4, 7, and 6% of subjects were found to have these VVDs when the whole 7-day record
was analyzed. The ability to accurately diagnose these VVAs is important since they were predictive
of overall mortality in this population [26].
A novelty pressor effect has been reported in other studies [27-30]. It may account for the fact that
in another database of 7-day/24-hour records obtained in a Japanese town, the diagnosis of MESOR-
NONINVASIVE METHODS IN CARDIOLOGY 2015
15
hypertension based on the first day of a 7-day record could not predict the occurrence of adverse
cardiovascular events with statistical significance, but it did when the diagnosis was made based on
the 7-day record [31].
Discussion and Conclusion
The usefulness of ABPM has been recognized for the evaluation of white-coat hypertension,
masked hypertension, and BP responses during exercise and laboratory stress [32]. ABPM, however,
is often limited to a single 24-hour record, interpreted in the light of conventional fixed limits. Herein,
we showed that a novelty pressor effect affects not only the estimation of the BP MESOR, but also the
estimation of the circadian pattern of BP. The diagnosis of MESOR-hypertension is therefore biased,
as is the diagnosis of other VVAs. To obtain a more accurate diagnosis, it is thus necessary to monitor
BP around the clock for longer than 24 hours.
Results herein indicate that the novelty pressor effect may last longer than 24 hours, notably
in relation to the MESOR of DBP and to the circadian amplitude of SBP and DBP. In view of the
statistically significant circaseptan rhythm characterizing BP and HR that accounts for differences of
a similar extent as that observed in relation to the novelty pressor effect, it is recommended to monitor
BP for at least 7 days at the outset. This recommendation is in keeping with guidelines outlined during
the 2008 Brno consensus meeting [22].
References
	 1.	Halberg F, Cornélissen G, International Womb-to-Tomb Chronome Initiative Group: Resolution
from a meeting of the International Society for Research on Civilization Diseases and the
Environment (New SIRMCE Confederation), Brussels, Belgium, March 17-18, 1995: Fairy tale or
reality? Medtronic Chronobiology Seminar #8, April 1995, 12 pp. text, 18 figures.
	 2.	Cornélissen G, Halberg F. Impeachment of casual blood pressure measurements and the fixed
limits for their interpretation and chronobiologic recommendations. Ann NY Acad Sci 1996; 783:
24-46.
	 3.	Halberg F, Cornélissen G, Halberg J, Fink H, Chen C-H, Otsuka K, Watanabe Y, Kumagai Y,
Syutkina EV, Kawasaki T, Uezono K, Zhao ZY, Schwartzkopff O. Circadian Hyper-AmplitudeTension,
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in Cardiology, October 15, 2012, Brno, Czech Republic. Brno: Faculty of Medicine, Masaryk
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Middle East: case reports. World Heart J 2010; 2 (4): 261-277.
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updated conference report. World Heart J 2012; 4 (4): 237-245.
	27.	Tamura K, Wu J, Cornélissen G, Halberg F. Comparison of two consecutive ambulatory 24-h blood
pressure and heart rate profiles in Japanese hospital staff. Chronobiologia 1989; 16: 189.
	28.	Otsuka K, Okajima K, Yamanaka T, Oinuma S, Sasaki J, Taniwaki Y, Otsuka K, Cornélissen G.
Aging and the novelty pressor effect in men on the first day of 7-day/24-hour ambulatory blood
pressure monitoring. J Am Geriatrics Soc 2014; 62 (8): 1602-1605.
	29.	Mochizuki Y, Okutani M, Donfeng Y, Iwasaki H, Takusagawa M, Kohno I, Mochizuki S, Umetani
K, Ishii H, Ijiri H, Komori S, Tamura K. Limited reproducibility of circadian variation in blood
pressure dippers and nondippers. American Journal of Hypertension. 1998; 11(4 Pt 1): 403-409.
	30.	Cornélissen G. Instrumentation and data analysis methods needed for blood pressure monitoring
in chronobiology. In: Scheving LE, Halberg F, Ehret CF, editors. Chronobiotechnology and
Chronobiological Engineering. Dordrecht, The Netherlands: Martinus Nijhoff; 1987. p. 241-261.
	31.	Otsuka K, Cornélissen G, Halberg F. Chronomics and continuous ambulatory blood pressure
monitoring. Springer, in press.
NONINVASIVE METHODS IN CARDIOLOGY 2015
18
	32.	The Task Force for the Management of Arterial Hypertension of the European Society of
Hypertension and of the European Society of Cardiology. 2013 ESH/ESC guidelines for the
management of arterial hypertension. J Hypertens 2013; 31: 1281–1357.
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 2015
19
Applications of ChronobiologicallyInterpreted
7-day/24-hour Ambulatory
Blood Pressure Monitoring: From Health
Maintenance and Primary Prevention to
Chronotherapy
Germaine Cornélissen1
, Kuniaki Otsuka2
, Yoshihiko Watanabe2
,
Francine Halberg1
, Julia Halberg1
, Larry Beaty1
,
Jiri Dusek3
, Alena Havelkova3
, Jarmila Siegelova3
1
Halberg Chronobiology Center, University of Minnesota,
2
Tokyo Women‘s Medical University, Daini Hospital, Tokyo, Japan,
3
Masaryk University, Brno, Czech Republic
Dedicated to the memory of Franz Halberg and Bohumil Fiser
Abstract
Since ambulatory blood pressure monitoring (ABPM) became feasible, around-the-clock data have
been collected in health and disease by an international team of investigators within the scope of the
project on the BIOsphere and the COSmos (BIOCOS). The derivation of time-specified reference
values in health, qualified by gender, age, and whenever possible, ethnicity, led to the definition
of Vascular Variability Disorders (VVDs), abnormal patterns of blood pressure and/or heart rate
variability. Outcome studies documented their association with an increased cardiovascular disease
risk. These results served as the foundation for a consensus document agreed upon at the October 6,
2008, meeting held at St. Anna Hospital, Masaryk University, Brno, Czech Republic. Much added
data have accumulated since then. In their light, herein we review evidence underlying the need for
7-day/24-hour ABPM and for their chronobiologic interpretation (C-ABPM).
Introduction
Circadian rhythms prominently characterize blood pressure (BP) and heart rate (HR), as well as
a host of other physiological variables [1]. Their characteristics differ as a function of gender and
age [2-8] as well as ethnicity [9] and health status [10-12]. The mapping of circadian rhythms in BP
and HR in health from neonates [13, 14], adolescents [15], adults of different ages [10, 11], and even
centenarians [16] led to the derivation of time-specified reference standards [17] in men and women of
different age groups [6].
Within the scope of our project on the BIOsphere and the COSmos (BIOCOS), BP and HR have
been monitored around the clock for 7 days or longer in different geographic locations [18-27]. These
data shed light on the extent of day-to-day variability in the circadian characteristics of BP and HR
NONINVASIVE METHODS IN CARDIOLOGY 2015
20
[28-30]. They also provide an opportunity to better understand how events in everyday life affect the
circadian variation in BP and HR [28, 31, 32].
All data collected within our BIOCOS project are analyzed in a standard fashion by sphygmochron
(in addition to any other analyses relative to each specific investigation). The sphygmochron is a twopronged
approach consisting of a parametric and non-parametric evaluation of the data. Parametrically,
a two-component model consisting of cosine curves with periods of 24 and 12 hours is fitted by least
squares to the data by cosinor [33-36], yielding estimates of the MESOR (Midline Estimating Statistic
Of Rhythm, a rhythm-adjusted mean, usually more precise and more accurate than the arithmetic
mean), and of amplitude (measure of half the extent of predictable change within a cycle) and
acrophase (measure of the timing of overall high values recurring in each cycle) of each component,
for comparison with reference norms (90% prediction limits from healthy peers matched by gender
and age [17]). This model was selected based on the observation that the 24- and 12-hour components
contributed most to the circadian waveform, on the average [12]. Non-parametrically data stacked over
an idealized 24-hour day are compared to the reference time-specified 90% prediction limits in health
to obtain the percentage time elevation, extent of blood pressure excess, and timing when most excess
occurs [6]. Deviations from norms are known as Vascular Variability Anomalies (VVAs), or Disorders
(VVDs) when they persist upon repeating the monitoring [37].
VVAs include an elevated MESOR of BP (MESOR-hypertension) when the BP MESOR exceeds
the upper 95% prediction limit of clinically healthy peers matched by gender and age; an elevated pulse
pressure (PP) when the difference between the MESOR of systolic (S) BP and the MESOR of diastolic
(D) BP exceeds 60 mmHg; an excessive circadian amplitude of BP (CHAT, brief for Circadian HyperAmplitude-Tension),
when the circadian amplitude of BP exceeds the upper 95% prediction limit of
clinically healthy peers matched by gender and age; an odd phase of the circadian rhythm of BP, but
not HR (ecphasia); a deficient HR variability (DHRV, brief for Deficient Heart Rate Variability), when
the standard deviation of HR is below 7.5 beats/min; and too high a systolic BP x HR product (above
100 mmHg.beats/min.%) [37].
We here review evidence for 7-day/24-hour C-ABPM serving several purposes: surveillance for
health maintenance, refined diagnosis and prognosis, personalized optimization of treatment by timing
(chronotherapy), and as a tool to gain a better understanding of environmental influences on human
physiology and pathology.
Surveillance and Health Maintenance
Routine monitoring may help us know ourselves better and improve our lifestyle. The transient
occurrence of VVAs such as CHAT has been related to loads in everyday life, as documented from
longitudinal records interpreted in the light of a diary in several individuals. As seen in Figure 1,
a mental task may be associated with higher elevations of BP than driving in a storm during a tornado
watch, or playing tennis [11]. Psychophysiological responses of BP, such as grief, anxiety and anger,
have also been reported, which were associated with abnormal circadian profiles for the first 5 days of
monitoring while no abnormalities were noted during a subsequent 11-day profile [38].
NONINVASIVE METHODS IN CARDIOLOGY 2015
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Figure 1: Different factors influence blood pressure, contributing to the large day-to-day variability in circadian
characteristics. © Halberg Chronobiology Center.
	 Figure 2: Large variability in circadian BP and HR. 	 Figure 3: Average SBP profile
	 © Halberg Chronobiology Center. 	 © Halberg Chronobiology Center.
As shown in Figures 2 and 3, BP variability can be very large and affect all circadian parameters.
When interpreted in the light of conventional fixed limits of acceptability, even the mean circadian
profile includes average measurements corresponding to contradictory diagnoses of normotension or
hypertension. The data stem from a 77-year old man treated with benidipine (4 mg/day in the morning).
In addition to a novelty effect observed at the beginning of the record when BP is higher, variability in
BP and the presence of CHAT may have been contributed by emotions as he was following a competitive
championship for the next 5 days [39]. Longitudinal monitoring over years and even decades has also
been invaluable for the early detection of the development of high BP, which was more pronounced
on work days than on weekends and holidays, thereby indicating how loads of everyday clinical duties
may contribute to the elevation in BP in this case [40].
These examples illustrate how much can be learned from data collected automatically as a function
of time. Information can thus be obtained to serve several purposes:
NONINVASIVE METHODS IN CARDIOLOGY 2015
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	v	To indicate whether there is a change in health well before there is abnormality in relation to
conventional thresholds;
	v	To indicate whether there is a change while on treatment, prompting adjustment in medication,
dosage and/or timing;
	v	To aid in diagnostic accuracy;
	v	To distinguish changes which are part of healthy aging versus the development of BP disorders. (In
clinical health, SBP was found to reach a maximum around 80 years of age, whereas DBP starts
decreasing after 50 years of age [8, 41, 42]; the circadian amplitude dampens and the circadian
acrophase becomes more labile in the elderly [11].)
Diagnosis and Prognosis
Whereas the relationship of the BP MESOR with cardiovascular disease risk is linear, that of the
circadian amplitude of BP and the standard deviation of HR is nonlinear: a threshold needs to be
exceeded for risk to increase [43]. Conditions such as CHAT were found to be associated with a large
increase in cardiovascular disease risk, notably in the case of cerebral ischemic events and hypertensive
nephropathy [44-46].
Figure 4: CHAT complicated by morning BP surge in 68-year old man treated for high BP. Despite successful
emergency operation for aneurysm, this patient died a few years later because of decreased renal function.
© Halberg Chronobiology Center.
One example is illustrated in Figure 4 which shows the case of a 68-year old man treated with
benidipine (4 mg/day taken in the morning). His hepatic and renal functions were normal at the time
of monitoring. His BP profile indicates the presence of a consistent morning surge. The circadian
amplitude of BP is also excessive (CHAT). After being monitored, an aneurysm of the abdominal
aorta was discovered, which ruptured before surgery. Several years after a successful emergency
operation, this subject passed away from a slowly progressively decreased renal function on a cold
winter morning [39]. Modalities need to be developed to treat not only an elevated BP, but also to
restore a healthy circadian BP profile by eliminating VVDs such as CHAT. Indications that such a
strategy may work stems from a cross-over study comparing treatment with benidipine in the morning
versus nifedipine twice a day, in the morning and evening: whereas benidipine lowered BP to a lesser
extent than nifedipine, it also reduced the circadian amplitude of BP, thereby being more likely to
NONINVASIVE METHODS IN CARDIOLOGY 2015
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eliminate or at least reducing the severity of CHAT, while nifedipine did not affect the circadian
amplitude of BP. Such a differential action of the two treatments is likely to have accounted for the
fewer adverse outcomes of patients treated with benidipine versus nifedipine according to the two
regimens tested, strokes in particular, in two large clinical trials comparing these two treatments [47].
Except for the BP x HR product [48], VVAs are mostly independent and additive [27, 41, 49]. In one
outcome study, an adverse event occurred within 6 years of the monitoring in only 8.7% of the subjects
diagnosed with uncomplicated MESOR-hypertension, but it occurred in 29.1% and in 53.3% of the
subjects with one or two additional VVAs complicating MESOR-hypertension; all 3 subjects with 3
additional VVAs suffered an adverse event [37, 50].
Uncomplicated MESOR-hypertension was found in 34.7% of the subjects, with 18.5%, 5.1% and
1.0% having 1, 2 or 3 additional VVAs in addition to MESOR-hypertension. Subjects diagnosed only
with CHAT or DHRV, accounting for 2.4% and 1.7% of the population, would not be treated under the
current standard of care [37].
In several outcome studies based on actual adverse events or on biomarkers such as the left ventricular
mass index, the circadian amplitude and acrophase interpreted in the light of reference values qualified
by gender and age, are better predictive of cardiovascular disease risk than the day-night ratio used for
a classification in terms of “dipping” [51].
Vascular Variability Disorders and Other Biomarkers
Several outcome studies have shown that an excessive pulse pressure (PP > 60 mmHg) is associated
with an increase cardiovascular disease risk [48]. A positive correlation has been documented between
pulse pressure and body mass index (BMI), as shown in Figure 5 for the Brno database and in Figure
6 for an American data set [52, 53]. In the latter study, PP correlated positively with BMI both in obese
(BMI > 30 kg/m2) (slope = 0.513±0.275, r=0.283, P=0.069) and non-obese (BMI < 30 kg/m2
) (slope
= 0.726±0.183, r=0.348, P<0.001) subjects. As PP correlates positively with body mass index, obese
people may be more likely to develop cardiovascular disease, in part because of an excessive PP.
Pulse pressure also correlates with markers of inflammation, such as C-reactive protein (CRP) and
TNF-α [52, 53], Figure 7.
Figure 5: Positive correlation of pulse pressure (PP) with body mass index (BMI). Data from J Siegelova.
© Halberg Chronobiology Center.
NONINVASIVE METHODS IN CARDIOLOGY 2015
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Figure 6: Positive correlation of pulse pressure (PP) with body mass index (BMI).
Data from J Abramson et al. [52, 53].
© Halberg Chronobiology Center.
Figure 7: Positive correlation of pulse pressure (PP) with C-reactive protein (CRP), an index of inflammation.
Data from J Abramson et al. [52, 53].
© Halberg Chronobiology Center.
Another reason why obese people may be at a higher risk for cardiovascular disease may relate to
their having a lower heart rate variability. In the Brno database, the standard deviation (SD) of HR,
here used as an index of heart rate variability, was found to correlate negatively with BMI, Figure 8.
NONINVASIVE METHODS IN CARDIOLOGY 2015
25
Figure 8: Heart rate variability decreases with increasing BMI. Data from J Siegelova.
© Halberg Chronobiology Center.
Ecphasia usually consists of a reversed circadian variation of BP peaking by night rather than by day,
while HR assumes higher values by day than by night. This condition has been reported for patients
with type-2 diabetes [54]. Its occurrence has also been associated with an increased cardiovascular
disease risk, gauged by the left ventricular mass index [51]. Subjects with SBP ecphasia have been
found to have a higher fasting blood glucose (F=13.938, P<0.001) and a higher glycosilated hemoglobin
(F=7.644, P=0.007) [55, 56], Figure 9. As seen in Figure 10, BP ecphasia is also associated with a
reduced heart rate variability (Student t = 6.138, P<0.001). These results suggest that BP ecphasia may
be more prevalent among patients with type-2 diabetes with autonomic nervous dysfunction. These
results [55, 56] have since been confirmed independently [57].
Figure 9: SBP ecphasia is associated with higher fasting glucose (left) and higher glycosylated hemoglobin
(right). Data of C Gonzalez et al. [55, 56].
© Halberg Chronobiology Center.
NONINVASIVE METHODS IN CARDIOLOGY 2015
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Figure 10: BP ecphasia is associated with a lower heart rate variability. Data of C Gonzalez et al. [55, 56].
© Halberg Chronobiology Center.
Chronotherapy
Treatment can be optimized by timing, using non-pharmacologic agents such as coQ10 [58] or antihypertensive
medication. They do not all have an effect on the circadian amplitude [59, 60]. Several
protocols have been designed. Timing treatment administration to when it is most needed, based on
the drug’s pharmacokinetics and the timing of BP excess, was compared to treating three times a day
in a study of propranolol, clonidine and α-methyldopa [61, 62]. Chronotherapy reduced BP more with
smaller doses, resulting in fewer side effects [61, 62], Figure 11.
Figure 11: Efficacy, safety and cost-effectiveness of chronotherapy (CT) compared with traditional treatment
(TT) 3 times a day. Data of R Zaslavskaya.
© Halberg Chronobiology Center.
Chronotherapy has also been applied by systematically testing the same dose of the same drug
regimen in the same patient studied longitudinally at 6 different treatment times. Different studies used
different spans during which treatment timing was kept the same in relation to the time of awakening,
NONINVASIVE METHODS IN CARDIOLOGY 2015
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varying from just one day [63] (Figure 12), to one week [64], and even one month or longer [65]. These
protocols present the advantage that the optimization of treatment by timing can be individualized. It
has indeed been demonstrated that optimal times of treatment can differ drastically from one patient
to another [65]. Personalized chronotherapy benefits from the development of statistical techniques
such as parameter tests [66] (Figure 13) and the self-starting cumulative sum (CUSUM) control chart
[67, 68] (Figure 14).
Figure 12: Effect of Telmisartan, administered at 6 different circadian stages, on the MESOR (left) and circadian
amplitude (right) of SBP. As compared to placebo (black, dashed line), Telmisartan alone (red, solid line) or with
low-dose aspirin (blue, dotted line) decreases SBP-M and SBP-A to a different extent depending on the time of its
administration. Data of P Prikryl [63].
© Halberg Chronobiology Center.
	 Figure 13: Parameter tests decrease in MESOR 	 Figure 14: Self-starting CUSUM detects lowering
	 and circadian amplitude of SBP associated with 	 of BP starting approximately at the time
	 a change in timing of the same dose of the same	 of treatment start.
	 anti-hypertensive drug to the same patient, 	 © Halberg Chronobiology Center.
	 © Halberg Chronobiology Center.
One lesson learned is the need to adjust treatment timing in the light of the diagnosis, a concept
known as chronotheranostics [69]. Indeed, patients with the same average BP may differ greatly
in terms of their BP variability that places them at different cardiovascular disease risk, Figure 15.
Personalized chronotherapy was shown to benefit more than 2/3 of patients examined. Treating VVAs
as well as an elevated BP can cut in half the number of strokes and overall cardiovascular events [47].
NONINVASIVE METHODS IN CARDIOLOGY 2015
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Environmental Influences
Longitudinal records spanning a decade or longer have shown the presence of cycles with periods
characterizing solar activity. About 5-month [70], about 16-month [71], and even about 11-year [72-75]
cycles have been found to characterize BP, HR and indices of variability in BP and HR. Figure 15
illustrates the about 11-year cycle modulating SBP. A histogram of nonlinearly-assessed spectral
components found in all longitudinal records available for analysis shows that an about 11-year
component is often present and detected with statistical significance, Figure 16 [75]. As reviewed
elsewhere [76-84], magnetic storms have also been associated with a decrease in HR variability and
in nocturnal melatonin.
	 Figure 15: About 11-year cycle modulates SBP 	 Figure 16: About 11-year cycles are often present
	 self-measured several times a day by a clinically 	 in longitudinal records, in preference
	 healthy man (EH) [73].	 to other periods [75].
	 © Halberg Chronobiology Center.	 © Halberg Chronobiology Center.
Discussion and Conclusion
Awareness of the merits of a chronobiological approach versus single clinic measurements should
be spread more widely, notably now that newer monitoring devices are addressing issues of comfort
and convenience, which have been deterrents to longer-term monitoring. Data collected automatically
as a function of time can
	v	Indicate whether there is a change in health well before there is abnormality in relation to
conventional thresholds;
	v	Indicate whether there is a change while on treatment, prompting adjustment in medication, dosage
and/or timing;
	v	Improve diagnostic accuracy; and
	v	Distinguish changes that are part of healthy aging versus the development of BP disorders.
NONINVASIVE METHODS IN CARDIOLOGY 2015
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159-164.
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(HR) and non-insulin-dependent diabetes mellitus (NIDDM) chronobiology. Abstract S8-06, 3rd
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circadian and circaseptan blood pressure (BP) amplitude (A) as well as MESOR. Abstract, X
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21-22, 1995. pp. 14-15.
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	63.	Prikryl P, Cornélissen G, Neubauer J, Prikryl P Jr, Karpisek Z, Watanabe Y, Otsuka K, Halberg F.
Chronobiologically explored effects of telmisartan. Clinical and Experimental Hypertension 2005;
2 & 3: 119-128.
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M, Regal P, Sothern RB, Wendt HW, Wang ZR, Zeman M, Jozsa R, Singh RB, Mitsutake G,
Chibisov SM, Lee J, Holley D, Holte JE, Sonkowsky RP, Schwartzkopff O, Delmore P, Otsuka
K, Bakken EE, Czaplicki J, International BIOCOS Group. Chronobiology‘s progress: season‘s
appreciations 2004-2005. Part I: Time-, frequency-, phase- variable-, individual-, age- and site-
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specific chronomics. J Applied Biomedicine 2006; 4: 1-38. Part II, Chronomics for an immediately
applicable biomedicine. J Applied Biomedicine 2006; 4: 73-86.
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blood pressure and a circadian overswing. Clin Exp Hypertens 2013; 35 (4): 257-266.
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methods for estimating and comparing cosinor parameters. Chronobiologia 1982; 9: 397-439.
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response by self-starting cumulative sums. J Medical Engineering & Technology 1997; 21: 111-120.
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In: Youan BC, ed. Chronopharmaceutics: Science and Technology for Biological Rhythm-Guided
Therapy and Prevention of Diseases. Hoboken, NJ: Wiley; 2009. pp. 257-323.
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melatonin cycles synchronization with the season, earth magnetism and solar flares. Scripta med
2010; 83: 16-32.
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and sudden cardiac death. The Autonomic Nervous System 2007; 44: 251-254.
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Kenner T, Cornélissen G, Siegelova J, Dobsak P. (Eds.) Noninvasive Methods of Cardiology.
Masaryk University, Brno, Czech Republic 2014; 59-64.
	73.	Haus E, Halberg F, Sackett-Lundeen L, Cornélissen G. Differing paradecadal cycles, semidecadal/
decadal amplitude ratios and vascular variability anomalies in the physiology of a physicianscientist.
World Heart J 2012; 4 (2/3): 141-163.
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D, Schwartzkopff O, Cornélissen G. Diagnosing vascular variability anomalies, not only
MESOR-hypertension. Am J Physiol Heart Circ Physiol 2013; 305: H279-H294. doi: 10.1152/
ajpheart.00212.2013.
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Hong S, Siegelova J. Decadal and multidecadal cycles in the cardiovascular system relating to
diagnosis and treatment? In: Kenner T, Cornélissen G, Siegelova J, Dobsak P. (Eds.) Noninvasive
Methods in Cardiology 2013. Masaryk University, Brno, Czech Republic 2013; 69-78.
	76.	Baevsky RM, Petrov VM, Cornélissen G, Halberg F, Orth-Gomér K, Åkerstedt T, Otsuka K, Breus
T, Siegelova J, Dusek J, Fiser B. Meta-analyzed heart rate variability, exposure to geomagnetic
storms, and the risk of ischemic heart disease. Scripta medica (Brno) 1997; 70: 199-204.
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K, Siegelova J, Fiser B, Bakken EE. Non-photic solar associations of heart rate variability and
myocardial infarction. J Atmos Solar-Terr Phys 2002; 64: 707-720.
	78.	Otsuka K, Cornélissen G, Weydahl A, Holmeslet B, Hansen TL, Shinagawa M, Kubo Y, Nishimura
Y, Omori K, Yano S, Halberg F. Geomagnetic disturbance associated with decrease in heart rate
variability in a subarctic area. Biomed Pharmacother 2001; 55 (Suppl 1): 51s-56s.
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	79.	Oinuma S, Kubo Y, Otsuka K, Yamanaka T, Murakami S, Matsuoka O, Ohkawa S, Cornélissen
G, Weydahl A, Holmeslet B, Hall C, Halberg F, on behalf of the „ICEHRV“ Working Group.
Graded response of heart rate variability, associated with an alteration of geomagnetic activity in a
subarctic area. Biomedicine & Pharmacotherapy 2002; 56 (Suppl. 2): 284s-288s.
	80.	Jozsa R, Halberg F, Cornélissen G, Zeman M, Kazsaki J, Csernus V, Katinas GS, Wendt HW,
SchwartzkopffO,StebelovaK,DulkovaK,ChibisovSM,EngebretsonM,PanW,BubenikGA,Nagy
G, Herold M, Hardeland R, Hüther G, Pöggeler B, Tarquini R, Perfetto F, Salti R, Olah A, Csokas
N, Delmore P, Otsuka K, Bakken EE, Allen J, Amory-Mazaudier C. Chronomics, neuroendocrine
feedsidewards and the recording and consulting of nowcasts forecasts of geomagnetics. Biomed
Pharmacother 2005; 59 (Suppl 1): S24-S30.
	81.	Kawasaki T, Yatagai A, Nakaoka T, Otsuka Ke, Otsuka Y, Watanabe Y, Otsuka Ku, Okumiya
K, Matsubayashi K, Norboo T, Cornélissen G, Halberg F. Astro-glocal spatially and temporally
(global and local) comprehensive health watch, especially at high altitude. In: Grigoriev AI, Zeleny
LM, eds. Proceedings, International Conference, Space Weather Effects in Humans: In Space and
on Earth, Space Research Institute, Moscow, Russia, June 4-8, 2012. Moscow: Space Research
Institute; 2013. pp. 539-550.
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Decadal solar activity cycles modulate neonatal health. In: Grigoriev AI, Zeleny LM, eds.
Proceedings, International Conference, Space Weather Effects in Humans: In Space and on Earth,
Space Research Institute, Moscow, Russia, June 4-8, 2012. Moscow: Space Research Institute;
2013. pp. 782-788.
	83.	Cornélissen G, Otsuka K, Halberg F. Remove and replace for a scrutiny of space weather and
human affairs. In: Grigoriev AI, Zeleny LM, eds. Proceedings, International Conference, Space
Weather Effects in Humans: In Space and on Earth, Space Research Institute, Moscow, Russia,
June 4-8, 2012. Moscow: Space Research Institute; 2013. pp. 508-538.
	84.	Cornélissen G, Watanabe Y, Otsuka K, Halberg F. Influences of space and terrestrial weather
on human physiology and pathology. In: Rosch PJ, ed. Bioelectromagnetic and Subtle Energy
Medicine, 2nd ed. Boca Raton: CRC Press; 2015. pp. 389-400.
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)
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NONINVASIVE METHODS IN CARDIOLOGY 2015
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Demonstration of Cosinor-Based Analyses
Using the Chronomics Analysis Toolkit in R
Cathy Lee Gierke1
, Yoshihiko Watanabe2
, Jarmila Siegelova3
, Jiri Dusek3
,
Kuniaki Otsuka2
, Germaine Cornélissen1
1
Halberg Chronobiology Center, University of Minnesota,
2
Tokyo Women‘s Medical University, Daini Hospital, Tokyo, Japan,
3
Masaryk University, Brno, Czech Republic
Abstract
A network of cell-based oscillators coordinates cardiac as well as other biological systems.
Understanding these rhythms demands versatile software than can characterize all aspects of an
oscillation in quantitative terms. The Chronomics Analysis Toolkit (CAT), an R package for analysis
of periodicities in time series, is a free and open source suite of rhythm analysis tools that runs on
UNIX, Windows and Macintosh platforms. Thus it is easy to acquire. It is also versatile, capable
of performing an array of simple to complex rhythm analysis techniques. It is illustrated herein to
quantitatively assess changes in the time structure (chronome) of heart rate (HR) of a Japanese infant
during the first 40 days of his life. Focus is placed on the development of the circadian rhythm in HR.
Introduction
Studying biological oscillations is a rapidly growing field. Some of the most accessible tools for
analysis, such as actograms, autocorrelation and periodograms, each have drawbacks. Some give only
subjective estimates of period; others do not assess statistical significance of the result. Researchers
are moving toward quantitative analyses that can fully characterize a rhythm, and provide a measure
of statistical significance. A rhythm is characterized by its period, phase, amplitude, and MESOR
(Midline Estimating Statistic of Rhythm, a rhythm-adjusted mean). A rigorous analysis will quantify
and consider all aspects of a rhythm. Scripting environments such as R [1], Mathematica, and
MATLAB contain extensive signal processing libraries, as well as other functions that can be used for
custom development of analytical tools, for those who want to do the programming themselves. For
the general-purpose analysis of biological cycles in time series data, there are only a few full-featured,
user-friendly packages aimed at the non-programmer [2].
Analytical Tools Available in the Chronome Analysis Toolkit (CATkit)
The Chronomics Analysis Toolkit (CATkit) package is written in R, a statistical programming
language and environment [1]. CATkit is a flexible general-purpose time-series analysis suite aimed
at the non-programmer, but easily modified and extended by the programming-inclined. Techniques
implemented in CATkit allow data that has gaps, and in the case of the cosinor, non-equidistant data.
It includes visual analysis tools to get an overview of the data, as well as tools that provide complete
numeric rhythm characterization. CATkit tools are listed in Table 1.
NONINVASIVE METHODS IN CARDIOLOGY 2015
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Table 1: Rhythm analysis tools in CATkit
Qualitative functions.
Equidistant data required
Quantitative functions.
Applicable to non-equidistant data
Actogram Single-component cosinor
Smoothing Least squares spectrum by cosinor
Autocorrelation Multiple-component cosinor
Crosscorrelation Single- or multiple-component cosinor serial section
Periodogram *
Gliding spectrum
*
The periodogram gives a quantitative estimate of power (or amplitude) and phase at Fourier frequencies.
© Halberg Chronobiology Center.
Smoothing, Autocorrelation, and Periodogram
The first step is to get an overall idea of what the data look like. The CATkit smoothing function
plots the heart rate (HR) data from the first 40 days of life, and overlays it with a smoothed curve that
helps see the major features present in the data [3]. Figure 1 illustrates the procedure, where data are
averaged over 11 consecutive values, using interpolated HR data rendered equidistant with filled gaps
in CATkit.
Figure 1: Smoothing curve of data from first 40 days post-natally. 1992/10/20 - 1992/11/28
Eleven data points averaged for smoothing. Data from Y Watanabe.
© Halberg Chronobiology Center.
As apparent from Figure 1, HR is changing over time, notably at the beginning of the record. In
other words, the time series is non-stationary [4]. Since the data appear to be more stable toward the
end of the record, focus is first placed on the last 7 days, Figure 2. While a circadian variation can be
discerned, its full characterization requires several additional analytical steps.
NONINVASIVE METHODS IN CARDIOLOGY 2015
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Figure 2: Smoothing curve days 33 - 40. 1992/11/22 17:02:00 to 1992/11/29 16:02:00 Eleven data points
averaged for smoothing. © Halberg Chronobiology Center.
The periodogram of Figure 3 views the data in the frequency domain. In addition to this plot,
CATkit also produces a file with quantitative output for each spectral line, including power, amplitude,
phase, and corresponding period. The CATkit periodogram reports the four largest amplitudes and
their corresponding periods. For days 33-40 of the HR record (Figure 3), these periods are 10.5,
24, 7.6, and 28 hours. The dotted line represents the noise level, drawn at the 95% probability level,
assuming white noise. A single anticipated component that rises above this noise level can be considered
statistically significant (P<0.05) as long as underlying assumptions are met. In the case of Figure 3, the
anticipated 24-hour component has an amplitude exceeding the noise level: it is significant (P<0.05).
As for the other 3 spectral lines listed in Figure 3, they should be interpreted with caution. The 28-hour
component is likely part of the circadian signal as the actual period of a developing circadian system
may not be 24-hour synchronized yet. If so, the 7.6-hour component may be a harmonic term qualifying
the waveform of the circadian rhythm. The 10.5-hour component is somewhat problematic but may
correspond to the half-day that may constitute a component in its own right shortly after birth. If there
is evidence supporting this interpretation and it can be anticipated to be present with the circadian
rhythm, albeit not in harmonic relation with it, it may also be significant as its P-value would remain
below 5% after adjustment for multiple testing (e.g., Bonferroni).
NONINVASIVE METHODS IN CARDIOLOGY 2015
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Figure 3: Periodogram days 33 - 40. 1992/11/22 17:02:00 to 1992/11/29 16:02:00 Top largest amplitude lines
given by CATkit at periods of: 10.5, 24, 7.6, and 28 hours. Experienced interpretation required. © Halberg
Chronobiology Center.
Figure 4: Autocorrelation days 33 - 40. A period of about 22 rises above the 95% confidence interval.
Multiple fluctuations in the cycle envelope indicate more than one frequency.
© Halberg Chronobiology Center.
Whereas the periodogram has the advantage of preserving the variance between the time and
frequency domains, one limitation of the periodogram is the fact that Fourier frequencies are fixed by
the record’s length and the sampling interval. As a result, spectral lines may not correspond to periods
anticipated to be present in the data.
The autocorrelation is another method available to assess periodicity. The autocorrelation of Figure
4 shows recurring higher correlation coefficients for lags about 22-24 hours apart. The correlation
coefficient at a lag of 22 hours rises above the 95% confidence interval shown as horizontal dashed
lines around zero. It indicates the presence of a circadian rhythm, in keeping with the results of the
periodogram. The shape of the envelope of the autocorrelation function has multiple regular fluctuations
that are indicative of the presence of at least another component with a period shorter than 24 hours. A
quantitative characterization of the rhythm parameters cannot be obtained by this approach, however.
In all of the techniques described above, the data must be equidistant.
NONINVASIVE METHODS IN CARDIOLOGY 2015
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The Single-Component Single Cosinor and Least Squares Spectrum
The single cosinor was first developed as a regression technique to handle short and sparse series
of non-equidistant data [5]. Fitting a single cosine curve to the data, using trial periods corresponding
to the Fourier frequencies, reproduces results from the periodogram when the data are equidistant.
The analysis is known as a least squares spectrum. Results in Figure 5 are obtained on the original
non-equidistant data during a slightly shorter record than that used for the analysis in Figures 3 and 4.
Nevertheless, results are quite similar, with peaks corresponding to periods of 23.1, 10.5, and 7.7 hours.
The least squares spectrum can use as record length (fundamental period) a value slightly different
from its actual length, thereby changing the discrete trial frequencies. It can also use a harmonic
increment different from 1, thereby assessing additional (in-between) frequencies.
Figure 5: Least squares spectrum of non-equidistant data. 23.1, 10.5 and 7.7 hours
are significant at <.001, .0048 and .0138, respectively.
© Halberg Chronobiology Center.
At each trial period, estimates of the amplitude and acrophase (phase of the maximum) are
obtained. The proportion of the variance accounted for (percentage rhythm, PR) is also determined.
The corresponding P-values from the zero-amplitude (no-rhythm) test are only of relative value. They
are shown with a plot of amplitudes in Figure 5 for the last week of the HR data.
Because the least squares spectrum can assess frequencies intermediate to Fourier frequencies, we
were able to determine more closely the period at which the amplitude was maximal. The circadian
period was estimated as being 23.1 hours, suggesting that the circadian rhythm may not have been
24-hour synchronized yet. The peak at 7.7 hours may then represent the third harmonic of the circadian
rhythm and modify its waveform. Figure 6 is a sample excerpted from the output file. For each trial
period, PR, P, MESOR and its standard error (SE), amplitude and acrophase and their SEs are reported.
Slightly different estimates for the MESOR are obtained at different trial periods because the data are
non-equidistant.
NONINVASIVE METHODS IN CARDIOLOGY 2015
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Figure 6: Data output excerpts. For each period, PR, P, MESOR, MESOR se, Amplitude, Amplitude se,
Acrophase and Acrophase se are reported. © Halberg Chronobiology Center.
Chronobiologic Serial Section
In days 33 – 40, the circadian rhythm is detected with statistical significance, but it is not yet
24-hour synchronized. The chronobiologic serial section helps visualize how the circadian component
evolves during the first 40 days of life.
Figure 7: Chronobiologic serial section of HR from birth to 40 days, assessed for a period of 23.1 hours. A series
of overlapping spans, 168 hours long and offset by 12 hours each are estimated and results are plotted.
© Halberg Chronobiology Center.
The chronobiologic serial section analyzes data in a span (interval) shorter than the entire record
and moves it progressively throughout the record by a given increment. In the case of the 40-day HR
record, a 23.1-hour cosine curve has been fitted to data in a week-long span (168 hours), progressively
incremented by 12 hours throughout the 40-day record. CATkit produces several graphs to help
NONINVASIVE METHODS IN CARDIOLOGY 2015
43
visualize the changes taking place, as seen in Figure 7. The raw data are plotted in the first graph.
MESOR, amplitude and acrophase are plotted with their SEs around the curves, followed by a plot of
the P-values from the zero-amplitude test in each span.
The MESOR varies between 140 and 128 beats/min, and is fairly stable after an initial swing
up. The circadian amplitude varies from 0 to 10 beats/min, and gradually increases with time. The
increase in the amplitude shows that the infant’s circadian rhythm is becoming stronger. P-values are
below 0.05 during most of the 40 days, indicating that the circadian rhythm is present already at birth,
albeit with changing characteristics as a function of age. Early measurements were sparse, perhaps
accounting for the lack of statistical significance in the first few days after birth.
Multiple-Component Cosinor
To this point a single cosine curve has been used to model the data. Multiple-component models
can also be fitted in CATkit to better approximate more complex signals. Figure 8 illustrates a twocomponent
model consisting of cosine curves with periods of 23.1 and 7.7 hours fitted to data recorded
on days 33-40. It approximates the developing circadian variation, including the fundamental 23.1hour
component and its third harmonic term with a period of 7.7 hours.
Figure 8: Multi-component cosinor comprising 23.1 and 7.7 hours. One cycle shown in box; slightly more than 7
cycles of 23.1-hour periodicity present in HR record (days 33-40). (model and data are on different scales.)
© Halberg Chronobiology Center.
Figure 9: Rhythmometric summary for multiple-component cosinor using 23.1 and 7.7 hours. Magnitude 33, P <
.001, indicate this is a good model for heart rate on days 33-40.
© Halberg Chronobiology Center.
NONINVASIVE METHODS IN CARDIOLOGY 2015
44
Numeric results for the multi-component model are shown in Figure 9. In addition to estimates
for the amplitude and acrophase of each component in the model, the multiple-component cosinor
also provides estimates for the magnitude, orthophase and bathyphase, parameters that describe the
complex waveform from the composite model: the magnitude is the extent of predictable change within
one cycle; the orthophase and bathyphase are the times of overall high and low values recurring in
each cycle. In the case of the HR data on days 33-40, the magnitude is 33 beats/min. It is slightly larger
than the double amplitude from the single-component model as the 7.7-hour harmonic term contributes
to the extent of predictable variation within a cycle. As seen from Figure 9, the model is statistically
significant (P<0.001), both components contributing to the model with statistical significance (23.1hour:
P<0.001; 7.7-hour: P=0.005).
Gliding Spectrum
The chronobiologic serial section showed how the characteristics of the 23.1-hour cosine model
changed over time, from birth to 40 days. It is likely that frequency components other than the circadian
variation also changed during the first few weeks of life. About-weekly variations have indeed been
reported to be prominent at birth by several investigators [6-14]. The gliding spectrum is a cosinor
technique that can visualize any changes in amplitude and frequency (period) as a function of time
in a broader frequency range, not limited to a single trial period. Figure 10 shows the results for HR
during the first 40 days of life of a full-term healthy boy. A 1-week interval is progressively displaced
by 12 hours. In each weekly span, a least squares spectrum is performed in the frequency range of 1
to 90 cycles in 252 hours, using a fractional harmonic increment of 0.5.
Figure 10: Gliding Spectrum on 40 days of heart rate since birth. Few dark areas are visible on the left side, but
over time a few bands resolve around 23/24 h, 10.5 h and 7.7 h. Data from Y Watanabe.
© Halberg Chronobiology Center.
Immediately after birth, there is no coherent rhythmicity, except perhaps around the week which is
not rigorously assessable with the parameters chosen for this analysis. We see only unresolved shadings.
But toward the middle of the plot we begin to see bandings coalesce at specific periods. Eventually,
NONINVASIVE METHODS IN CARDIOLOGY 2015
45
bands appear near 23 hours and 10.5 hours, as well as around 7.7 hours. This graph provides a view of
how and when the circadian component develops in a healthy, full-term baby boy.
CATkit
These analyses have all been performed with CATkit, written in R. The call to CATkit is put into a
.r script file, and can be put on the desktop. Double clicking will run the script, and produce the output
displayed in the figures and tables herein, as well as additional files containing tab-delimited computer
readable output. Interpolated data can also be exported for later use.
Figure 11: Call to CATkit in .r script file. This script performs a least squares spectrum
on columns 2 and 5 using a single- component cosinor model.
© Halberg Chronobiology Center.
Each of these analyses uses only slightly different call lines in the .r script. Figure 11 is one example
of a call to CATkit. This particular call line performs a least squares spectrum using a single-component
cosinor. TimeCol identifies the column(s) containing the time. Any format can be used by setting
timeFormat. Y is used to indicate the column or columns containing data to be analyzed. Components
is set to the number of cosine components to use in the model. RangeDateTime can be used to limit
the rows of data used to only those times specified as Start and End of range. Progressive Interval and
Increment configure the program for serial section, or gliding spectrum. Period is used to determine
which periods should be considered for analysis. Set indicates the trial period or periods. Any valid R
structure can be used, so a single value can be used (Set=24), or a vector can be used (Set=c(24 12, 8)).
R allows ranges to be specified as well, so a range from 24 to 12, and also 8 [hours] could be specified
(Set=c(24:12,8). If Set=0 a least squares spectrum is performed using Start, Increment and End. Start
and End are given in hours. These will be the starting and ending trial periods. Increment refers to
frequency (harmonic increment).
CATkit produces a variety of output files (Figure 12). For each function, one or more plots are
produced. Also, for each column of data acted upon by a function, quantitative results are produced
in two formats, human-readable as well as tab-delimited computer-consumable. The functions that
require equidistant data, and therefore use interpolation when needed, will also export the interpolated
(and binned) data in tab-delimited format.
NONINVASIVE METHODS IN CARDIOLOGY 2015
46
Figure 12: Output files produced by CATkit. © Halberg Chronobiology Center.
Discussion and Conclusion
CATkit is used at the Halberg Chronobiology Center, and by other investigators worldwide.
It has been used, among other applications, for studying the day-to-day variability in circadian
characteristics of blood pressure [15], for determining the best timing to take daily anti-hypertensive
medication, extending results already published [16], and to assess the time structure of the incidence
of cardiovascular conditions in a comprehensive database of ambulance calls in Siberia.
R is freely available from the Comprehensive R Archive Network http://cran.r-project.org/ [1], and
can also be used as a scripting language, facilitating the creation of scripts to run CATkit iteratively
for multiple data files, or build other custom automations in the broader R environment. CATkit, and
instructions for installation and use, can be found at http://z.umn.edu/CATkit.
References
	 1.	R Core Team. R: A language and environment for statistical computing. 2014. R Foundation for
Statistical Computing, Vienna, Austria. http://www.R-project.org/
	 2.	Lee Gierke C, Cornélissen G. Chronomics Analysis Toolkit (CATkit). Biological Rhythm Research
(in press). http://dx.doi.org/10.1080/09291016.2015.1094965
	 3.	Church RM. How to look at data: A review of John W. Tukey’s Exploratory Data Analysis. J Exp
Anal Behav 1979; 31: 433–440.
	 4.	Chatfield C. The Analysis of Time Series: An Introduction, Sixth Edition. 6th ed. 2003. Boca
Raton, FL: Chapman and Hall/CRC.
	 5.	Halberg F, Tong YL, Johnson EA. Circadian system phase -- an aspect of temporal morphology;
procedures and illustrative examples. Proc. International Congress of Anatomists. In: Mayersbach
H v, ed. The Cellular Aspects of Biorhythms. Symposium on Rhythmic Research, Sponsored by
the VIII International Congress of Anatomy, Wiesbaden, 8.-14. August 1965. New York: SpringerVerlag;
1967. pp. 20-48.
NONINVASIVE METHODS IN CARDIOLOGY 2015
47
	 6.	Cornélissen G, Halberg F, Tarquini B, Mainardi G, Panero C, Cariddi A, Sorice V, Cagnoni M.
Blood pressure rhythmometry during the first week of human life. In: Tarquini B, ed. Social
Diseases and Chronobiology: Proc. III Int. Symp. Social Diseases and Chronobiology, Florence,
Nov. 29, 1986. Bologna: Società Editrice Esculapio; 1987. pp. 113-122.
	 7.	Halberg F, Wang Z, Cornélissen G, Bingham C, Rigatuso J, Hillman D, Wakasugi K, Kato K,
Kato J, Tamura K, Sitka U, Weinert D, Schuh J, Coleman JM, Mammel M, Miyake Y, Ohnishi M,
Satoh K, Watanabe Y, Otsuka K, Watanabe H, Johnson D. SIDS and about-weekly patterns in vital
signs of premature babies. In: Yoshikawa M, Uono M, Tanabe H, Ishikawa S, eds. New Trends in
Autonomic Nervous System Research: Basic and Clinical Interpretations, Selected Proc. 20th Int.
Cong. Neurovegetative Research, Tokyo, September 10-14, 1990. Amsterdam: Excerpta Medica;
1991. pp. 581-585.
	 8.	Wang ZR, Mammel M, Coleman JM, Hillman D, Xue ZN, Johnson D, Cornélissen G, Halberg
F. About-weekly patterns of vital signs in four very premature babies. In: Otsuka K, Cornélissen
G, Halberg F, eds. Chronocardiology and Chronomedicine: Humans in Time and Cosmos. Tokyo:
Life Science Publishing; 1993. pp. 57-58.
	 9.	Cornélissen G, Engebretson M, Johnson D, Otsuka K, Burioka N, Posch J, Halberg F. The week,
inherited in neonatal human twins, found also in geomagnetic pulsations in isolated Antarctica.
Biomed & Pharmacother 2001; 55 (Suppl 1): 32s-50s.
	10.	Cornélissen G, Siegelova J, Halberg F. Blood pressure and heart rate dynamics during pregnancy
and early extra-uterine life: Methodology for a chrononeonatology. In: Halberg F, Kenner T, Fiser
B, eds. Proceedings, Symposium: The Importance of Chronobiology in Diagnosing and Therapy
of Internal Diseases. Faculty of Medicine, Masaryk University, Brno, Czech Republic, January
10-13, 2002. Brno: Masaryk University; 2002. pp. 58-96.
	11.	Watanabe Y, Cornélissen G, Hellbrügge T, Watanabe F, Otsuka K, Schwartzkopff O, Halberg
F. Partial spectral element in the chronome of a human neonatal heart rate at term. Biomed &
Pharmacother 2002; 56 (Suppl 2): 374s-378s.
	12.	Siegelova J, Cornélissen G, Schwartzkopff O, Halberg F. Time structures in the development of
children. Neuroendocrinol Lett 2003; 24 (Suppl 1): 126-131.
	13.	Syutkina EV, Cornélissen G, Yatsyk G, Studenikin M, Baranov A, Halberg F. Over a decade
of clinical chrononeonatology and chronopediatrics in Moscow. Neuroendocrinol Lett 2003; 24
(Suppl 1): 132-138.
	14.	Watanabe Y, Nintcheu-Fata S, Katinas G, Cornélissen G, Otsuka K, Hellbrügge T, Schwartzkopff
O, Bakken E, Halberg F. Methodology: partial moving spectra of postnatal heart rate chronome.
Neuroendocrinol Lett 2003; 24 (Suppl 1): 139-144.
	15.	Cornélissen G, Lee Gierke C, Havelkova A, Dusek J, Siegelova J. Day-to-day variability of
circadian characteristics of systolic blood pressure and effect of exercise. In: Kenner T, Cornélissen
G, Siegelova J, Dobsak P. (Eds.) Noninvasive Methods of Cardiology. Masaryk University, Brno,
Czech Republic 2014; 25-32.
	16.	Watanabe Y, Halberg F, Otsuka K, Cornélissen G. Toward a personalized chronotherapy of high
blood pressure and a circadian overswing. Clin Exp Hypertens 2013; 35 (4): 257-266.
NONINVASIVE METHODS IN CARDIOLOGY 2015
48
Correspondence:
Germaine Cornélissen and Cathy Lee Gierke
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
NONINVASIVE METHODS IN CARDIOLOGY 2015
49
Recent Progress in the study of the CardioAnkle
Vascular Index (CAVI)
Tomoyuki Yambe1
, Yasuyuki Shiraishi1
, Hidekazu Miura1
, Yusuke Inoue1
,
Yusuke Tsuboko1
, Akihiro Yamada1
, Yasunori Taira1
, Shota Watanabe1
,
Yuri A Kovalev2
, Irina A Milyagina2
, Mitsuya Maruyama3
1
Pre Clinical Research Center, Institute of Development Aging and Cancer, Tohoku Unversity,
2
Department of Therapy, Smolensk State Medical Academy,
3
Fukuda denshi Co
To measure the stiffness of the aorta, femoral artery and tibial artery noninvasively, cardio-ankle
vascular index (CAVI) which was independent of blood pressure had been developed in cooperation
of the Tohoku University and Fukuda denshi Co. The reproducibility had been studied, and the
Independence from blood pressure have been studied till now. The results suggested that CAVI could
reflect arteriosclerosis of the aorta, femoral artery and tibial artery. Furthermore we can evaluate
the baroreflex sensitivity of an artery by the use of arterial tone. International cooperation study are
ongoing now. So various scientific reports are easily found in pubmed. Medical device maker is now
gathering these international papers for the presentation to the every doctors in the world for the
achievements of better medical care. If the evaluation by this methodology in not so good, all doctors
have a chance to use another devices. So, it is not necessary to use this method when the scientific
papers showed another device had been good. Every doctors in all over the world must check recent
progress in medical device in the scientific fields. By the use of the scientific, physical, quantitative
methodology, evaluation of the atherosclerosis will be embodied in near future based on the normal
value of every people in every country.
Key words
Cardio Ankle Vascular Index, Baroreflex, Pulse wave velocity, International cooperation
Introduction
In order to diagnose arteriosclerosis in any part of the body, pulse wave velocity (PWV) measurement
is a useful approach1-3). However, it is considered that the technique of PWV measurement should be
simplified. A new method for measuring PWV has therefore been proposed in Japan. The PWV of
the brachial artery and the ankle was measured by applying air pressure with the aid of a volume
plethysmograph3-5). Comparisons between the baPWV measurement method and the conventional
method are currently being performed. Since satisfactory results have been obtained to date, baPWV
has gained popularity throughout Japan.
Since this method measures PWV in the arm and foot, it may be said that aortic PWV is not
reflected though a large amount of past PWV measurements. BaPWV is influenced by blood pressure.
With the baPWV technique, blood pressure compensation is not carried out. Furthermore, the pulse
pressure is measured by air pressure; therefore any stimulus that exerts pressure on an artery may
influence these results. Due to these reasons, a cardie-ankle vascular index (CAVI) has been proposed
in which the pressure wave form indicating the closing of the aortic valve appears in the form of an
arterial pressure wave after a fixed delay time6-9).
NONINVASIVE METHODS IN CARDIOLOGY 2015
50
Formula for measuring this index is; CAVI=a{(2rho/DeltaP) x ln(Ps/Pd)PWV(2)} + b where, Ps and
Pd are systolic and diastolic blood pressures respectively, PWV is pulse wave velocity between the
heart and ankle, DeltaP is Ps - Pd, rho is blood density, and a and b are constants. This equation was
derived from Bramwell-Hill‘s equation, and stiffness parameter.
Measurements of stiffness parameter of the Aorta and arteries are of course important in developed
countries, because progression of the atherosclerosis causes a chronic artery disease that develops over
many years without clinical symptoms.
Furthermore, it is an important point that the progression of atherosclerosis may be decelerated by
intensive treatment of the main cardiovascular risk factors. Various kinds of medical studies has been
carried out in all over the world. Soska V, Dobsak,P, et al. always have noted the importance of obesity
in the prevention of the stiffness parameter progression, and a lot of researchers in many countries
including Japan, USA, China, have showed the data concerning the obesity and CAVI in pubmed base.
International cooperative study
In the world, the Russian data was the most interesting thing. Because the worst obese population
in EU has been observed in Russia and Malta. In Smolensk, a lot of patients had been evaluated in
the Smolensk State Medical Academy. 1733 peoples had been measured and evaluated. For example,
390 healthy subjects without heart attack, stroke, hypertension, HCM, DM and smoking had been
compared with Aging.
Everybody knows that DM has been the worst risk factor in metabolic disorder. Of course, the
Russian data had supported the existence of this phenomenon.
	 	
	 Figure 1: CAVI in the Russian healthy subjects	 Figure 2: CAVI in DM patients in Russia
Baroreflex sensitivity of vascular tone
Baroreflex system is one of the most important regulatory systems to maintain the homeostasis of
the circulation. When blood pressure (BP) was increased, baroreceptor sensed this increase. Neural
information concerning the BP change was evaluated in the central control system. Heart rate (HR)
　was reduced and resistance vessels were dilated by the autonomic control system. BP was returned
to the normal range by the reduction of the pump out put and vascular resistance. Sensitivity of the
baroreflex system was evaluated by the various methodologies. Quantitative evaluation by the slope
NONINVASIVE METHODS IN CARDIOLOGY 2015
51
of the regression line between BP change and HR change was one of the typical method to evaluated
the baroreflex sensitivity of the heart. However, we could not evaluate the baroreflex sensitivity of the
vascular system by this method.
Autonomic nervous system control of the each internal organ was different. So, we must evaluate
the sensitivity of the baroreflex system of an artery. However, it is very difficult to evaluate the tonus
of the artery in the human body during awaking condition. Recently, brachial ankle pulse wave
velocity (baPWV) and cardio ankle vascular index (CAVI) were invented and commercialized. These
methodologies measured the pulse wave velocity of the human body and calculate the tonus of the
artery. So, if we use these methodologies to measure the tonus of the artery, we can measure the
characteristics of the baroreflex system of an artery.
New diagnosis tool to evaluate the baroreflex sensitivity of an artery was invented.
In order to evaluate the baroreflex sensitivity of an artery, we used the information of the pulse wave
velocity of the human body. Time series data of the ECG, pulse wave of the radial artery, and finger tip
pulse wave were recorded in the data recorder and analyzed in the personal computer system.. Pulse
wave velocity was calculated from the time lag between the R wave and pulse wave. Changes of the
pulse wave transmission time were plotted against the changes of the blood pressure. Slopes of the
regression line showed the baroreflex sensitivity of the peripheral resistance artery.
Quantitative evaluation of the baroreflex sensitivity may be useful when we consider the ideal
treatment of the patients with hypertension12-13)
Recent progress of CAVI
Further international cooperative studies are undergoing now. So various scientific reports are
easily found in pubmed. Medical device maker is now gathering these international papers for the
presentation to the every doctors in the world for the achievements of better medical care. If the
evaluation by this methodology in not so good, all doctors have a chance to use another devices. So, it
is not necessary to use this method when the scientific papers showed another device had been good.
Every doctors in all over the world must check recent progress in medical device in the scientific fields.
For example, Schillaci et al. had reported the usefulness of CAVI compared with cf PWV in LV mass
detection14). We need the further examination in future, but comparison of the various methodology
is always important.
Otsuka et al. reported the changes in CAVI after management of atherosclerotic risk factors15),
and the impact of these changes on future CVD outcomes. CAVI improved in 50% patients after 6
months, but remained high in 50% patients. CVD outcomes were worse in patients with persistently
impaired CAVI than in those with improved CAVI (P < 0.001). His study was the first to demonstrate
that persistent impairment of arterial stiffness was an independent risk factor of future CVD events.
Long time follow up is the most important issue. We must continue this kind of studies. Of course,
the obesity in one of the most important factors in Metabolic syndrome when we consider the healthy
population in every countries. Sato asahara et al. reported the incidence of cardiovascular events in
obese patients. And their study demonstrates for the first time that CAVI is an effective predictor of
CVD events in obese patients.
More and more studies are carried out now in all over the world.
There may be a possibility that another new diagnosis method will be invented.
We must continue our study for the more good treatment of the patients
NONINVASIVE METHODS IN CARDIOLOGY 2015
52
References
	 1.	The pulse wave arrival time (QKd interval) in normal children. Bercu BB, Haupt R, Johnsonbaugh
R, Rodbard D. J Pediatr. 1979 Nov;95(5 Pt 1):716-21.
	 2.	Clinical application of carotid electrosphygmography. Chlebus H. Bibl Cardiol. 1979;(37):73-83.
	 3.	Validity, reproducibility, and clinical significance of noninvasive brachial-ankle pulse wave
velocity measurement. Yamashina A, Tomiyama H, Takeda K, Tsuda H, Arai T, Hirose K, Koji Y,
Hori S, Yamamoto Y. Hypertens Res. 2002 May;25(3):359-64.
	 4.	Comparison of brachial-ankle pulse wave velocity in Japanese and Russians. Liu H, Yambe T,
Zhang X, Saijo Y, Shiraishi Y, Sekine K, Maruyama M, Kovalev YA, Milyagina IA, Milyagin VA,
Nitta S. Tohoku J Exp Med. 2005 Dec;207(4):263-70.
	 5.	A Japanese-Russian collaborative study on aging and atherosclerosis. Yambe T, Kovalev YA,
Milyagina IA, Milyagin VA, Shiraishi Y, Yoshizawa M, Saijo Y, Yamaguchi T, Shibata M, Nitta
S. Biomed Pharmacother. 2004 Oct;58:S91-4.
	 6.	A novel blood pressure-independent arterial wall stiffness parameter; cardio-ankle vascular index
(CAVI). Shirai K, Utino J, Otsuka K, Takata M. J Atheroscler Thromb. 2006 Apr;13(2):101-7.
	 7.	Association of serum albumin and homocysteine levels and cardio-ankle vascular index in patients
with continuous ambulatory peritoneal dialysis. Lee JA, Kim DH, Yu SJ, Oh DJ, Yu SH. Korean J
Intern Med. 2006 Mar;21(1):33-8.
	 8.	Chronoecological health watch of arterial stiffness and neuro-cardio-pulmonary function in
elderly community at high altitude (3524 m), compared with Japanese town. Otsuka K, Norboo T,
Otsuka Y, Higuchi H, Hayajiri M, Narushima C, Sato Y, Tsugoshi T, Murakami S, Wada T, Ishine
M, Okumiya K, Matsubayashi K, Yano S, Chogyal T, Angchuk D, Ichihara K, Cornélissen G,
Halberg F. Biomed Pharmacother. 2005 Oct;59 Suppl 1:S58-67.
	 9.	Brachio-ankle pulse wave velocity and cardio-ankle vascular index (CAVI). Yambe T, Yoshizawa
M, Saijo Y, Yamaguchi T, Shibata M, Konno S, Nitta S, Kuwayama T. Biomed Pharmacother.
2004 Oct;58 Suppl 1:S95-8
	10.	Increased cardio-ankle vascular index in hyperlipidemic patients without diabetes or hypertension.
Dobsak P, Soska V, Sochor O, Jarkovsky J, Novakova M, Homolka M, Soucek M, Palanova P,
Lopez-Jimenez F, Shirai K. J Atheroscler Thromb. 2015;22(3):272-83 3.
	11.	Cardio-ankle vascular index in subjects with dyslipidaemia and other cardiovascular risk factors.
Soska V, Frantisova M, Dobsak P, Dusek L, Jarkovsky J, Novakova M, Shirai K, Fajkusova L,
Freiberger T. J Atheroscler Thromb. 2013;20(5):443-51
	12.	Development of new quantitative diagnosis machine to evaluate the baroreflex sensitivity of an
artery for patients with hypertension. Yambe T, Sugita N, Yoshizawa M. Conf Proc IEEE Eng Med
Biol Soc. 2009;2009:888-91.
	13.	Baroreflex sensitivity of an arterial wall during rotary blood pump assistance. Yambe T, Imachi K,
Shiraishi Y, Yamaguchi T, Shibata M, Kameyama T, Yoshizawa M, Sugita N. Artif Organs. 2009
Sep;33(9):767-70.
	14.	Cardio-ankle vascular index and subclinical heart disease. Schillaci G, Battista F, Settimi L,
Anastasio F, Pucci G. Hypertens Res. 2015 Jan;38(1):68-73.
NONINVASIVE METHODS IN CARDIOLOGY 2015
53
	15.	Serial assessment of arterial stiffness by cardio-ankle vascular index for prediction of future
cardiovascular events in patients with coronary artery disease. Otsuka K, Fukuda S, Shimada K,
Suzuki K, Nakanishi K, Yoshiyama M, Yoshikawa J. Hypertens Res. 2014 Nov;37(11):1014-20
	16.	Cardio-ankle vascular index predicts for the incidence of cardiovascular events in obese patients:
A multicenter prospective cohort study (Japan Obesity and Metabolic Syndrome Study: JOMS).
Satoh-Asahara N, Kotani K, Yamakage H, Yamada T, Araki R, Okajima T, Adachi M, Oishi M,
Shimatsu A; Japan Obesity and Metabolic Syndrome Study (JOMS) Group. Atherosclerosis. 2015
Aug 8;242(2):461-468
NONINVASIVE METHODS IN CARDIOLOGY 2015
54
NONINVASIVE METHODS IN CARDIOLOGY 2015
55
Current progress of a non-invasive
peripheral perfusion evaluation during
mechanical circulatory support
Yasuyuki Shiraishi*1
, Kazumasu Sasaki1
, Tomoya Kitano2
, Kyosuke Sano2
,
Shota Watanabe2
, Yusuke Inoue3
, Yasunori Taira2
, Yusuke Tsuboko2
,
Hidekazu Miura3
, Akira Tanaka4
, Makoto Yoshizawa5
, Tomoyuki Yambe1,3
1
Department of Preclinical Evaluation, PreClinical Research Center, Institute of Development, Aging and Cancer
(IDAC), Tohoku University, 4-1 Seiryo-machi, Aoba-ku, Sendai 9808575, Japan,
2
Graduate School of Biomedical Engineering, Tohoku University,
3
Department of Medical Engineering and Cardiology, PreClinical Research Center, Institute of Development, Aging
and Cancer (IDAC), Tohoku University,
4
Faculty of Symbiotic Systems Sciences, Fukushima University,
5
Cyberscience Center, Tohoku University
*Email: yasuyuki.shiraishi.d1@tohoku.ac.jp
Centrifugal blood pumps have been commonly applied to the patients with severe heart failure
in recent years. Due to the extension of assisting period in patients with the reduced pulsation,
the prevention of long-term adverse effects in end-organs has been focused to keep the healthy
conditions in peripheral perfusion under the mechanical circulatory support conditions. We have
been developing novel approaches from the mechanical circulatory point of view, such as artificial
myocardial assist systems or pulmonary circulatory assist devices, which could represent and promote
either the ventricular contraction or the hemodynamic pulsatility delivered to peripheral organs. In
order to achieve the quantitative examination of these effects on perfusions on hemodynamics, a new
non-invasive approach to diagnostic procedures using a high-speed CCD image analyses has been
accomplished to estimate peripheral blood flow in animal experiments with centrifugal blood pumps.
Consequently, the sequential image-based analysis corresponding to the peripheral circulation may
permit detrimental and comprehensive validation in each patient during the low pulsatility condition
without direct measurement of blood flow.
Keywords
mechanical circulatory support, animal experiments, centrifugal blood pump, high-speed image
analysis, peripheral perfusion
Introduction
In recent years, many types of rotary blood pumps have been clinically and widely employed for
the surgical treatment as ventricular assist devices (VADs) in the patients with severe heart failure1–5.
As rotary blood pumps are mainly supplied as the implantable VAD, there might be reduction or
elimination of pulse in the patients with mechanical circulatory support. To overcome a trend in the
lack of donors for heart transplantation, the trajectory of surgical treatment with the use of VADs are
shifting from the bridge-to-transplant or the bridge-to recovery to the destination therapy or to the
bridge-to-decision as an alternative course. The long-term use of the rotary VADs causes mechano-
NONINVASIVE METHODS IN CARDIOLOGY 2015
56
physiological changes in cardiovascular systems, especially in end-organ peripheral function that
might be induced by adverse effects during the extensive mechanical circulatory support.
Steering the pressure-flow relations by the total artificial heart (TAH) is one of the control methods
for physiological regulation in the end-stage of heart failure by the use of pulsatile or non-pulsatile
TAHs6. Although the complication according to the circulatory balance might be reduced by using
the intellectual artificial control algorithm, the physiological response could be rearranged for the
maintenance of end-organ function en passant.
We have been developing several types of cardiovascular mechanical contractile support devices
as shown in Figure 1. Each system outputs a contraction force that is initially placed outside of the
ventricle or vascular vessels to support native blood pumping action without direct contacting surface
of blood. We proposed these mechanisms by combining the small components and the Ni-Ti alloy
fibers to achieve the miniature implantable design and highly flexible structure for the installation
into the small sized thoracic cavities. These novel artificial cardiovascular support systems could
provide the effective hemodynamic assistance with respect to the physiological demands. However,
the direction of the control design should include an alternative circumvented way preventing the
functional dislocation of artificial contraction and the afterload mismatch.
In order to obtain the peripheral perfusion data non-invasively and quantitatively, we applied a
pulse detection method by using a charge-coupled device (CCD) that provides RGB color absorbance
information of the region of interests of the skin surface7–9.
A new approach to indirect diagnostic methods using a set of high-speed sequential images involves
regional surveillance of surfaces of end-organs, such as skin, kidney, lung, heart, etc. This study
presents the design and capabilities of an evaluation method that could exhibit the rate of pulsatility in
peripheral perfusion during the mechanical circulatory support condition. The proof-of-concept was
examined on the ability to represent comprehensive variation of the pulse detected by using the highspeed
images obtained from the end-organ surfaces.
Materials and Methods
The current procedure of the estimation of peripheral perfusion involves the installation of a
centrifugal blood pump and the analyses of color changes of each organ by indirect measurements.
a) Installation of a centrifugal blood pump
Prior to the measurement of peripheral perfusion, we performed the left VAD installation using
a centrifugal blood pump (EVAHEARTTM, Sun Medical Technology Research Corporation,
Suwa, Japan). Saanen goats were used for the investigation of peripheral circulation. We operated
the device installation and the measurements via left thoracotomy under the normal anesthesia by
the administration of 2.5% isoflurane and by 0.2µg/kg/min remifentanil. The animal experimental
procedure was approved by the Institutional Animal Experiment Committee of Tohoku University,
Sendai, Japan.
b) Measurement of high-speed sequential images
High-speed image recordings were performed during the rotary blood pump support as well as the
control condition without the VAD support. The operating speed of the pump was varied from 1,000
to 2,200 rpm, providing a mean flow rate of 1 to 5 L/min, approximately. We recorded the images by
a digital video camera (NEX-FS100JK, Sony, Japan) at the rate of 480 fps under the white-colored
NONINVASIVE METHODS IN CARDIOLOGY 2015
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LED lighting condition (VL-1600C, LPL Co. Ltd., Tokyo, Japan) as shown in Figure 2. Numerical
separation of RGB color components and regional averaging of color levels in root mean square values
were calculated (Mathematica V10, Wolfram Research, IL, USA). We also carried out the simultaneous
measurement of tissue perfusion by a Laser flowmeter (FLO-C1, Omegawave Co. Ltd., Tokyo Japan)
for the comparison of the direct measurement of end-organ surfaces.
Figure 1: Small-sized implantable mechanical circulatory devices to generate additional contractile function
from outside of the heart and the vessels: A) an artificial myocardial assist system, and B) an extra aortic kinetic
support device.
Figure 2: An example of the measurement of high-speed sequential images by the digital video camera (CCD)
under the rotary blood pump support focusing to the kidney perfusion.
Results and Discussion
Sequential images obtained in previous studies using a CCD indicated that the absorbance of green
color exhibited end-organ pulse at the face skin during the mechanical blood pump support (Figure 3).
We compared the results of the conventional Laser tissue blood flow and the fluctuation of the data
obtained by the indirect measurement by the CCD at the surface of left kidney. As can be seen, base
NONINVASIVE METHODS IN CARDIOLOGY 2015
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frequencies calculated by the data in each method had a close similarity that was equivalent to the
heart
rate. Moreover, the oscillation of estimated pulse by the CCD corresponded to the changes in
amplitude of tissue perfusion (Figure 4, 5). Therefore, a quantitative analysis to detect peripheral
perfusion could be applied based on the green color component absorbance on end-organ surfaces by
using a high-speed DVC/CCD. Using this method, regional physiological changes might be predicted
in the failure heart hemodynamics with rotary blood pumps non-invasively. The method applied in the
study provides the simplified information of levels in green color absorbance by the blood based on
previous pulse detection methods. Nevertheless, these results suggest that data obtained using CCD
images may provide peripheral perfusion information as well, and it can be useful for assessing the
effects of end-organ blood supply. The simplified device could also provide an interactive system,
where there would be practical oversight by doctors for the patients at home via tele-communication.
More generally, employing these non-invasive diagnostic measurements to other organs’ physiological
function could improve the quality of care for patients with severe heart failure.
	 Figure 3: Changes in the waveform obtained 	 Figure 4: Changes in the waveform obtained
	 by the Laser tissue flowmeter and the data 	 by the Laser tissue flowmeter and the data 		
	 calculated by the CCD data from the surface.	 calculated by the CCD data from the kidney surface.
	 of a goat face skin
Figure 5: Comparison of normalized fluctuations obtained by the CCD and the Laser tissue flowmeter under the
different driving condition of the EVAHEART device from 1,000 to 2,200 rpm.
NONINVASIVE METHODS IN CARDIOLOGY 2015
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References
	 1.	Koerfer R, Spiliopoulos S, Finocchiaro T, Guersoy D, Tenderich G, Steinseifer U. Paving the way
for destination therapy of end-stage biventricular heart failure: the ReinHeart total artificial heart
concept. European Journal of Cardio-Thoracic Surgery. 2014;46(6):935–936.
	 2.	Pagani FD, Miller LW, Russell SD, et al. Extended Mechanical Circulatory Support With a
Continuous-Flow Rotary Left Ventricular Assist Device. JAC. 2009;54(4):312–321.
	 3.	Saito S, Yamazaki K, Nishinaka T, et al. Post-approval study of a highly pulsed, low-shear-rate,
continuous-flow, left ventricular assist device, EVAHEART: A Japanese multicenter study using
J-MACS. Journal of Heart and Lung Transplantation. 2014;33(6):599–608.
	 4.	Stewart GC, Givertz MM. Mechanical Circulatory Support for Advanced Heart Failure: Patients
and Technology in Evolution. Circulation. 2012;125(10):1304–1315.
	 5.	Westaby S. Circulatory Support for Long-Term Treatment of Heart Failure: Experience With an
Intraventricular Continuous Flow Pump. Circulation. 2002;105(22):2588–2591.
	 6.	Carpentier A, et al. First clinical use of a bioprosthetic total artificial heart:report of two cases. The
Lancet. July 2015:1–8.
	 7.	Nakajima K, Tamura T, Miike H, et al. Monitoring of heart and respiratory rates by
photoplethysmography using a digital filtering technique. Med Eng Phys. 2004;18:365–372.
	 8.	Poh M-Z, McDuff DJ, Picard RW. Advancements in Noncontact, Multiparameter Physiological
Measurements Using a Webcam. IEEE Trans Biomed Eng. 2010;58(1):7–11.
	 9.	McManus DD, Lee J, Maitas O, et al. A novel application for the detection of an irregular pulse
using an iPhone 4S in patients with atrial fibrillation. Heart Rhythm. 2013;10(3):315–319.
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NONINVASIVE METHODS IN CARDIOLOGY 2015
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PROF. MUDR. ZDENĚK PLACHETA, DRSC.
4. 4. 1931 - 1. 11. 2014
Jarmila Siegelová
Dept. of Physiotherapy and Rehabilitation, Faculty of Medicine, Masaryk University, Brno
Prof. MUDr. Zdenek Placheta, DrSc., died on November 1st, 2014. He will be remembered as an
exceptional expert in sport medicine, professor emeritus of Masaryk University and also an active
sportsman.
Prof. Placheta completed his studies of medicine in Brno in 1956 and started his medical career
in the Dept. of Anatomy, Masaryk University, under the leadership of excellent professor MUDr.
K. Žlabek. Later he worked in the II. Clinic of Internal Medicine, Masaryk University, under the
leadership of Prof. MUDr. Polčák and he qualified in internal medicine. He moved to work in the
Dept. of Sport Medicine, Masaryk University, Faculty of Medicine, St. Anna Hospital in Brno; in this
time Doc. MUDr. Vladimír Dražil, CSc., was the head of the Dept. of Sports Medicine.
The choice to work in the Dept. of Sports Medicine was based on the active sports career of Prof.
Placheta. He was an active sportsman, played football and in the years 1954-1960 was a member of
the national league of football and took part in the representation of the Czechoslovak Republic. In
the Dept. of Sports Medicine he not only taught medical students in the field of sport medicine but
also started his research career in sports medicine and functional investigations of cardiovascular and
respiratory system at rest and during exercise. From Masaryk University he was given an exceptional
possibility to continue working abroad in the field of sport medicine, namely in East Germany in
Leipzig in „Sportmedizinischem Zentrum“ in 1960, and on the basis of his thesis done in Germany
he was given the title Dr. Med. in Germany. In 1966 he was given the scientific degree CSc. at the
Masaryk University. His research was aimed to the physical fitness in young adults aged from 12 to 18
years. He published the results of his findings in the field of sports medicine in a lot of publications. The
most important were English written monographs Youth and Physical Fitness (1980) and Submaximal
Exercise Testing (1988). In 1986 he was given the title Assoc. Prof. in Charles University in Prague,
in 1987 he was given the research degree DrSc. In 1988 he replaced Doc. MUDr. Vladimír Dražil,
CSc., who retired, and became Head of the Dept. of Sports Medicine and in the same year he became
the professor of sport medicine. Under his leadership the research in the Dept. of Sports Medicine
was aimed not only to healthy sportsmen of the superior level, but also to the development of new
investigation methods of functional diagnostics of cardiorespiratory functions in health and disease.
In 1996 he retired and gave the head position to Prof. MUDr. Jarmila Siegelova, DrSc., but following
his retirement he continued to be active in the department and in 1999 he published another important
monography „ Zátěžová diagnostika v ambulantní a klinické praxi“, together with Prof. J. Siegelová
and Prof. M. Štejfa, and also contributed to the teaching program of the department until his death.
Prof. MUDr. Zdenek Placheta Dr.Sc., spoke English, French and German fluently and took part
in international symposia, congresses and workshops in 1996 – 2014, being organized in Masaryk
University every year by our department. Some of his participations are documented in the photographs
together with the speakers from abroad - Europe, USA and Japan. He was also coauthor of some
publications from our Congresses of Noninvasive Methods in Cardiology.
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Figure 1: Prof. MUDr. Z. Placheta DrSc. is standing and from the left we can see Prof. Dr. med. Thomas Kenner
d.h.c. mult., Graz, Austria, Brigitte Kenner, Graz, Austria, Prof. Dr. Jean-Paul Marineaud, Paris, France and
Prof. MUDr. Jarmila Siegelova DrSc., at the occasion of MEFA International Symposium, Brno, in 1998.
Figure 2: Prof. MUDr. Z. Placheta DrSc. in Brno “Trade Fair – MEFA” International Symposium, Brno, in
2003.
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Figure 3: Prof. Dr. Jean-Paul Marineaud, Paris, France and Prof. MUDr. Z. Placheta DrSc. in Brno “Trade
Fair - MEFA” International Symposium, Brno, in 2003.
Figure 4: Prof. Dr. Franz Halberg, d.h.c. mult., Minnesota, USA, Prof. Dr. Jean-Paul Marineaud, Paris, France
and
Prof. MUDr. Z. Placheta DrSc. in the “Trade Fair- MEFA” International Symposium, Brno, in 2003.
NONINVASIVE METHODS IN CARDIOLOGY 2015
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Figure 5: International Congress “Noninvasive Methods in Cardiolology in 2007”, held in Faculty of Medicine,
Masaryk University, Brno, Komenského nam. 2. From the left we can see Mgr. Dunklerova, Brigitte Kenner and
Prof. Thomas Kenner d.h.c.mult., Graz, Austria, Prof. MUDr. Zdenek Placheta DrSc. Prof. MUDr. Petr Dobsak,
CSc., and Prof. Jean Eric Wolf, Dijon, France.
Figure 6: International Congress “Noninvasive Methods in Cardiolology in 2007”, held in Faculty of Medicine,
Masaryk University, Brno, Komenského nam. 2. From the right we can see Prof. Thomas Kenner d.h.c.mult.,
Graz, Austria, standing in the discussion with Prof. MUDr. Zdenek Placheta DrSc. sitting Prof. MUDr. Petr
Dobsak CSc., Prof. MUDr. Bohumil Fišer CSc., Prof. MUDr. Jarmila Siegelova DrSc., and from behind Brigitte
Kenner.
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Figure 7: International Congress “Noninvasive Method in Cardiolology in 2007”, held in Faculty of Medicine,
Masaryk University, Brno, Komenského nam. 2. From the right we can see Prof. Masario Kohzuki, Sendai,
Japan, standing in the discussion with Prof. MUDr. Zdenek Placheta, DrSc. and Prof. MUDr. Petr Dobšak, CSc.,
both standing, and at the first table from behind Brigitte Kenner and Prof. Thomas Kenner d.h.c.mult., Graz,
Austria, and at the first table sitting Prof. MUDr. Bohumil Fišer, CSc., and Prof. MUDr. Jarmila Siegelova,
DrSc.
Prof. MUDr. Zdenek Placheta, DrSc., belongs to the generation of pioneering specialists in sports
medicine. He will be sorely missed because of his intellectual and scientific as well as clinical
contribution. Dear Prof. Placheta, we thank you very much for your friendship, collaboration,
endeavour, and for pushing ahead the frontiers of knowledge in medicine. We will continue your work
in the Department of Sports Medicine and Rehabilitation in St. Anna Hospital in Faculty of Medicine,
Masaryk University, Brno.
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NONINVASIVE METHODS IN CARDIOLOGY 2015
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PROF. MUDR. MIROSLAV MIKULECKÝ, DRSC.
22. 6. 1927 - 25. 1. 2015
Jarmila Siegelová
Dept. of Physiotherapy and Rehabilitation, Faculty of Medicine, Masaryk University, Brno
Prof. MUD. Miroslav Mikulecký, DrSc. finished studies of medicine in 1952.In the years 1952-
1994 he worked in the I. Dept of Medicine, Medical Faculty, University of Komenius in Bratislava,
now Slovakia. In 1967 he finished his scientific theses and got the scientific degree CSc., in 1974
he become associated professor, in 1980 he got scientific degree Dr.Sc. and in 1982 he got the title
professor in Internal medicine. In the years 1981 -1989 he was the head of I. Dept. of Medicine, Faculty
of Medicine University of Komenius in Bratislava.
In the scientific field he was the founder of gastroenterology in Slovakia. He published about 1
000 scientific publications in the internal medicine, biometrics and chronobiology of cardiovascular
parameters. He had excellent knowledge in mathematical and statistical methods and cooperated with
scientists in Halberg Chronobiology Center, University of Minnesota, and Bethesda USA, Liverpool,
Great Britan, Australia, Japan and others. He also cooperated with the III. Dept of Medicine, Faculty
of Medicine, Masaryk University, namely with Prof. MUDr. Konrad Ryšánek, Dr.Sc. and his team.
Figure 1: International Chronobiology symposium “Erna Halberg- Sun, Moon and Live” in Bratislava in 1990,
organized by Prof. MUDr. Miroslav Mikulecký, Dr.Sc., sitting in the middle of the first road, next to him to the
left sitting Prof. Dr. Franz Halberg, d.h.c.mult, from Universty of Minnesota, USA, in the second road standing
from the left MUDr. Jiri Dušek, CSc. and Prof. MUDr. Jarmila Siegelová, Dr.Sc., and also standing Prof. Dr.
med. Gunther Hildebrand, University of Marburg, Germany in the last road (under the inscription ERNA).
NONINVASIVE METHODS IN CARDIOLOGY 2015
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Professor MUDr. Miroslav Mikulecký, Dr.Sc. organized in Slovakia in Bratislava and in Košice
some important international symposia about chronobiology and also our Brno chronobiological team
took part with active participations in these symposia.
Prof. MUDr.Miroslav Mikulecký, Dr.Sc. was a talented scientist, he inspired, formed and influenced
countless researchers in chronobiology. He will be remembered as an outstanding physician for his
kind, open mood and great humanity.
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SEVEN-DAY AMBULATORY BLOOD PRESSURE
MONITORING AT REST AND DURING EXERCISE:
VARIABILITY OF NIGHT-TO-DAY BLOOD PRESSURE
RATIO
Siegelová J., Havelková A., Dušek J., Dunklerová L., Pohanka M., Dobšák P.,
Cornélissen G.*
Department of Physiotherapy and Rehabilitation,, Department of Sports Medicine and Rehabilitation, Faculty of
Medicine, Masaryk University, St. Anna Teaching Hospital, Brno, CZ,
*University of Minnesota, USA
Dedicated to the memory of Franz Halberg and Bohumil Fiser
Introduction
Franz Halberg and Germaine Cornelissen using ambulatory blood pressure monitoring showed the
need to account day-to-day changes of blood pressure and heart rate and the necessity to circadian
assessment of the hour-to- hour variability in cardiovascular parameters. The Chronobiology center
of Minnesota started with the international project BIOCOS with seven day/24 hours blood pressure
monitoring in Japan, Urausu, Hokkaido by Kuniaki Otsuka, In Department of functional diagnostics
and rehabilitation (Dept. of Sports medicine and Rehabilitation) St. Anna Teaching Hospital, Masaryk
University, Brno, Czech Republic under the guidance of Jarmila Siegelova, in Moradabad, India, under
the guidance of RB Sing, and others from Belgium, Italy, Mexico, Norway, Armenia, China as well as
USA California and Minnesota (1, 2).
From 1988, when O`Brien and colleagues reported that an abnormal circadian blood pressure
profile with a less marked decrease in night-time blood pressure led to an increased risk for stroke, the
clinical significance of night-to-day blood pressure ratio is known (3). Subsequent studies confirmed
the prognostic significance of night-to-day blood pressure ratio for prediction of a higher rate of
cardiovascular complications (4-10). One of large-scale studies based on International Database on
Ambulatory blood pressure monitoring in relation to Cardiovascular Outcomes was published in
2007 (11). The investigators did 24-hour blood pressure monitoring in 7458 people (mean age 56.8
years) from Denmark, Belgium, Japan, Sweden, Uruguay and China. Median follow-up was 9.6 years.
They found that night-to-day ratio of systolic and diastolic blood pressure adjusted for cohort, sex,
age, body-mass index, smoking and drinking, serum cholesterol, history of cardiovascular disease,
diabetes mellitus, and antihypertensive drug treatment predicted total mortality, non-cardiovascular
mortality and cardiovascular mortality. In fully adjusted models night-to-day ratio was additionally
adjusted for 24-hour blood pressure. The results for fully adjusted night-to-day ratio were similar
except systolic blood pressure and cardiovascular mortality where the hazard ratio 1.08 (0.99- 1.17)
was not statistically significant. After the patients were, according the night-to-day ratio, divided in 4
categories with night-to-day ratio >1.0 (reverse dippers), 0.9-1.0 (non-dippers), 0.9-0.8 (dippers) and <0.8
(ultra-dippers), the total mortality was increased in non-dippers and reverse-dippers in comparison to
NONINVASIVE METHODS IN CARDIOLOGY 2015
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dippers. Cardiovascular mortality was significantly increased in reverse dippers, as well as incidence
of all cardiovascular events.
Although the prognostic significance of night-to-day blood pressure ratio was proved in a large group of
patients, the clinical significance of this value depends on variation of repeated measurement in individual
patients.
In the year 2010 we evaluated the night-to-day blood pressure variability during 7 days/ 24 hour
of ambulatory blood pressure measurement in the healthy subjects and we found great variability in
night-to -day ratio in systolic and diastolic blood pressure in the same person in repeated 24-hour
blood pressure monitoring (12). In these study was the aim to evaluated night to day blood pressure
ratio in the days with exercise and compared it with the days without exercise during 7day/24hour
ambulatory blood pressure monitoring in patients with ischemic heart disease.
Methods
Thirty one patients with ischemic heart disease (all males), forty nine years to eighty four years
old, were recruited for seven-day blood pressure monitoring. TM 2421 A D Instruments (Japan) were
used for ambulatory blood pressure monitoring (oscillation method, 30-minute interval between
measurements) (13).The patients were monitored 7 days/ 24 h in the days with exercise and without
exercise. One-hour means of systolic and diastolic blood pressure were evaluated, when night-time
was considered from midnight to 06;00 h and day time from 10;00 to 22;00 h, avoiding the transitional
periods. Mean day-time and mean night-time systolic and diastolic pressures were evaluated every day
(14).
Dipper status was evaluated every day. Dippers were defined as those individuals with a 10-20 %
fall in nocturnal blood pressure. Non-dipping was defined as a less than 10 % nocturnal fall, and those
with no fall in blood pressure were defined as reverse-dippers (15).
The patients underwent phase II of cardiovascular rehabilitation in the Dept. of Sports Medicine and
Rehabilitation two times a week, controlled ambulatory rehabilitation program, composed of aerobic
and resistant training, three times a week, lasting three month.
Results
Variability of night-to-day ratio during 7-day/24 h monitoring in 31patients in the days without
exercise is seen in Figure 1 for SBP and in the days with exercise in Figure 2 for SBP.
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Figure 1: Seven-day ambulatory monitoring blood pressure monitoring in patients with ischemic heart disease:
variability of SBP night to day ratio in the days without exercise
In the days without exercise in SBP only 3 subjects (10 %) were found which could be classified as
SBP dippers or ultra-dippers every day. Most of the subjects were classified on various days differently,
even 3 subjects (10 %) were one day classified as ultra-dippers and the other day as reverse-dippers.
NONINVASIVE METHODS IN CARDIOLOGY 2015
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Figure 2: Seven-day ambulatory monitoring blood pressure monitoring in patients with ischemic heart disease:
variability of SBP night to day ratio in the days with exercise
In the days with exercise in SBP only 4 subjects (13 %) were found which could be classified as
SBP dippers or ultra-dippers every day. Most of the subjects were classified on various days differently,
even 3 subjects (10 %) were one day classified as ultra-dippers and the other day as reverse-dippers.
NONINVASIVE METHODS IN CARDIOLOGY 2015
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Figure 3: Seven-day ambulatory monitoring blood pressure monitoring in patients with ischemic heart disease:
variability of DBP night to day ratio in the days without exercise
In the days without exercise, similarly no subject were classified as DBP dipper or ultra-dipper
every day. Two subjects (7 %) were classified as DBP dippers, others were one day ultra-dippers and
the other day as reverse-dippers.
NONINVASIVE METHODS IN CARDIOLOGY 2015
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Figure 4: Seven-day ambulatory monitoring blood pressure monitoring in patients with ischemic heart disease:
variability of DBP night to day ratio in the days with exercise
In the days with exercise, similarly no subject were classified as DBP dipper or ultra-dipper every
day. Night subjects (27 %) were classified as DBP dippers, others were one day ultra-dippers and the
other day as reverse-dippers.
Discussion
Our finding of large night-day ratio variability in individual subjects corresponds to the results of
other studies. The night-to-day blood pressure ratio is subject to regression-to-the mean (16). In our
studies with seven day blood pressure monitoring in subjects with resting condition and the presented
results in patients with ischemic heart disease in the day without exercise and in the days with exercise
showed also large individual variability of night to day blood pressure ratio.
Dipping status has also a low reproducibility, with up to 40 % of individuals from Europe (17) and
Asia (18) changing status between repeat recordings.
In our former study we demonstrated that the relation between night-to-day ratio and risk of
cardiovascular events is not linear as it is in the case of mean 24-hour systolic and diastolic pressure
(19). We observed at low circadian double amplitude which roughly corresponds to the difference
between night and day blood pressure (5 mmHg of systolic and 4 mmHg of diastolic pressure) about
30 % higher incidence of cardiovascular events than at circadian double amplitude of 15 to 35 mmHg
systolic and of 12 to 20 mmHg diastolic pressure but at double amplitude higher than 35 mmHg in
systolic and 28 mmHg in diastolic pressure the incidence was double. This indicates the existence of
overswinging or Circadian Hyper-Amplitude-Tension (CHAT) syndrome which is associated with a
large increase in cardiovascular disease risk. The incidence of ultra-dipping is more frequent that the
NONINVASIVE METHODS IN CARDIOLOGY 2015
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incidence of CHAT but existence of CHAT alone can lead to misdiagnosis of risk based on night-today
blood pressure ratio (20 – 23).
In conclusion, despite the low night-to-day ratio of blood pressure predicted increased risk for
cardiovascular events in large studies, the determination of this value is useless for management of
arterial hypertension in individual patients.
Summary
The evaluation of night-to-day blood pressure variability during 7 days of ambulatory blood pressure
measurement was the aim of the present study. Thirty subjects (18 males, 12 females), twenty one years
to seventy three years old, were recruited for seven-day blood pressure monitoring. Colin Medical
Instruments (Komaki, Japan) were used for ambulatory blood pressure monitoring (oscillation method,
30-minute interval between measurements). One-hour means of systolic and diastolic blood pressure
were evaluated, when night-time was considered from midnight to 0600 h and day-time from 1000 to
2200 h, avoiding the transitional periods. Mean day-time and mean night-time systolic and diastolic
pressures were evaluated every day.
Dipper status was evaluated every day. Dippers were defined as those individuals with a 10-20 %
fall in nocturnal blood pressure. Non-dipping was defined as a less than 10 % nocturnal fall, and those
with no fall in blood pressure were defined as reverse-dippers.
The day-to-day variability of night-to-day ratio is large. The dipping status classification in
individual patients is not reliable.
References
	 1.	Halberg F, Cornelissen G, Wall D,Otsuka K, Halberg J, Katinas G, Watanabe Y, Halhuber M,
Müller-Bohn T, Delmore P, Siegelova J, Homolka P, Fiser B, Dusek J, Sanchez de laPena S, Maggioni
C, Delyukov A, Gorgo Y, Gubin D, Caradente F, Schaffer E, Rhodus N, Borer K, Sonkowsky RP,
Schwartzkopff O. Engineering and gowernmental challenge: 7-day/24-hour chronobiologic blood
pressure and heart rate screening: Part II. Biomedical Instrumentation & Technology 2002; 36:
183-197.
	 2.	Cornelissen G. Time structures (chronomes) in us and around us: tribute to Franz Halberg. In
Cornelissen G, Kenner T, Fiser B, Siegelova J. Chronobiology in Medicine, Brno, Masaryk
University, 2004. 8-43. http://www.med.muni.cz/index.php?id=1376
	 3.	E O‘Brien, J Sheridan and K O‘Malley, Dippers and non-dippers, Lancet 332 (1988), p.397.
	 4.	T Ohkubo, A Hozawa and J Yamaguchi et al., Prognostic significance of the nocturnal decline
in blood pressure in individuals with and without high 24-h blood pressure: the Ohasama study, J
Hypertens 20 (2002), pp. 2183–2189.
	 5.	TW Hansen, J Jeppesen, F Rasmussen, H Ibsen and C Torp-Pedersen, Ambulatory blood pressure
monitoring and mortality: a population-based study, Hypertension 45 (2005), pp. 499–504.
	 6.	E Ingelsson, K Björklund, L Lind, J Ärnlöv and J Sundström, Diurnal blood pressure pattern and
risk of congestive heart failure, JAMA 295 (2006), pp. 2859–2866.
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	 7.	G Mancia, R Facchetti, M Bombelli, G Grassi and R Sega, Long-term risk of mortality associated
with selective and combined elevation in office, home, and ambulatory blood pressure, Hypertension
47 (2006), pp. 846–853.
	 8.	P Verdecchia, C Porcellati and G Schillaci et al., Ambulatory blood pressure. An independent
predictor of prognosis in essential hypertension, Hypertension 24 (1994), pp. 793–801.
	 9.	JA Staessen, L Thijs and R Fagard et al., Predicting cardiovascular risk using conventional vs
ambulatory blood pressure in older patients with systolic hypertension, JAMA 282 (1999), pp.
539–546.
	10.	K Kario, TG Pickering, T Matsuo, S Hoshide, JE Schwartz and K Shimada, Stroke prognosis
and abnormal nocturnal blood pressure falls in older hypertensives, Hypertension 38 (2001), pp.
852–857.
	11.	José Boggia, Yan Li, Lutgarde Thijs et all. Prognostic accuracy of day versus night ambulatory
blood pressure: a cohort study. Lancet 370 (2007), p.1219-1229.
	12.	Fišer B, Havelková A, Siegelová J, Dušek J, Pohanka M, Cornelissen G, Halberg F Night-today
blood pressure ratio during seven-day ambulatory blood pressure monitoring. In: Halberg F,Kenner
T,Fišer B, Siegelová J eds: Noninvasive methods in cardiology 2010, Brno, Masaryk University,
p.128-132. http://www.med.muni.cz/index.php?id=1376
	13.	J. Siegelová, J. Dusek, B. Fiser, P. Homolka, P. Vank, M. Kohzuki, G. Cornellisen, F. Halberg.
Relationship between circadian blood pressure variation and age analyzed from 7-day ambulatory
monitoring. J Hypertension, 2006, vol. 24, Suppl.6, p. 122.
	14.	RedónJ,VicenteA,AlvarezVet.al.Circadianrhythmvariabilityofarterialpressure:methodological
aspects for the measurement. Med Clin, 1999 112:258-289.
	15.	Jerrard-Dune P, Mahmud A, Feely J. Circadian blood pressure variation: relationship between
dipper status and measures of arterial stiffness. J Hypertension 2007, 25: 1233-1239.
	16.	Staessen, CJ Bulpitt and E O‘Brien et al., The diurnal blood pressure profile. A population study,
Am J Hypertens 5 (1992), pp. 386–392.
	17.	S Omboni, G Parati and P Palatini et al., Reproducibility and clinical value of nocturnal hypotension:
prospective evidence from the SAMPLE study, J Hypertens 16 (1998), pp. 733–738.
	18.	Y Mochizuki, M Okutani and Y Donfeng et al., Limited reproducibility of circadian variation in
blood pressure dippers and nondippers, Am J Hypertens 11 (1998), pp. 403–409.
	19.	Cornélissen G, Delcour A, Toussain G et al. Opportunity of detecting pre-hypertension: world wide
data on blood pressure overswinging. Biomedicine and Pharmacotherapy 59 (2005) S152-S157.
	20.	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 Hypertens, 2011; 294: 818-819.
	21.	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.
	22.	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
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Member of World Health Organization:His Legacies for Public and Personal Health Care. World
Heart J 2011; 3,1:63 -77.
	23.	Cornelissen G, Siegelova J, Watanabe Y,Otsuka K,Halberg F Chronobiologically-interpreted
ABPM reveals another vascular variability anomaly: Excessive pulse pressure product. World
Heart J 2013;4,4:1556-4002.
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SEVEN DAY BLOOD PRESSURE VARIABILITY AT
REST AND DURING EXERCISE IN HEALTHY MEN AND
PATIENTS
Siegelová Jarmila, Havelková Alena, Dušek Jiří, Pohanka Michal,
Dunklerová Leona, Dobšák, Petr, Cornélissen Germaine.*
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
The International College of Cardiology; American Heart Association Council on Nutrition,
Physical Activity, and Metabolism; American Heart Association Council on Clinical Cardiology; and
American College of Sports Medicine call on all populations of the world, and their employers to
create a culture of physical activity and health for the prevention of cardiovascular diseases (CVDs)
and diabetes mellitus (1-4).Usually there is no prescribed time for exercise. 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. In a
majority of populations, some individuals work around the clock and disturb the sleep at night, what
impair the circadian cardiovascular control and many of them exercise not in accordance with natural
circadian rhythm. An exercise late in the evening might increase the risk of an increase of circadian
hyperamplitude tension (CHAT) and can have an adverse clinical event in increase of cardiovascular
disease risk, such as sudden cardiac death (SCD) or acute coronary syndrome (ACS), particularly in
vulnerable subjects (3- 6). In the Dept. of Sports medicine and rehabilitation, there is cardiovascular
rehabilitation for patients after coronary heart disease, organized according the guidelines of European
Society of Cardiology. There are not many data about the effect of exercise on 24h values of systolic
and diastolic blood pressure using ambulatory blood pressure monitoring.
The definition of hypertension with different types of measurement is included in the Guidelines for
Management of Hypertension, 2007 (8).
According to this table 1 the threshold for the diagnosis of hypertension for systolic blood pressure
is 140 mmHg in the office or clinic, in ambulatory blood pressure monitoring 125 – 130 mmHg during
24 hours, 130 -135 mmHg during day and 120 mmHg during night.
The corresponding values for diastolic blood pressure are 90 mmHg in the office and clinic, in
ambulatory blood pressure monitoring 80 mmHg during 24 hours, 85 mmHg during day and 75
mmHg during night.
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The values for home measurement are the same as for ambulatory monitoring during day.
Table 1: From J Hypertension 2007
SBP DBP
Office or clonic 140 90
24-hour 125-130 80
Day 130-135 85
Night 120 70
Home 130-135 85
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 patients (9 - 13). The cardiovascular rehabilitation
program in out-patients rehabilitation includes the exercise unit, lasting 60 min, three times in a week.
The purpose of the study
The aim of the study was to compare 24-hour profile from the 7-day blood pressure monitoring at
rest and during exercise in healthy subjects and in patients included in cardiovascular rehabilitation.
From seven day ambulatory blood pressure monitoring we compared the blood pressure 24 h profile
in the day with exercise (0-24 h) and in the day without exercise (25-48 h after exercise). We analyzed
aerobic training, resistant training, Nordic walking in healthy subjects and combined training in
patients with coronary heart disease.
Methods
Healthy Subjects Aerobic Training
We examined 21 men and 20 women, healthy subjects, mean age 28±5.2 years (from 23 to 39).
For exercise training we used bicycle ergometer Kettler, type X7, Germany, two times 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.
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Figure 1: Aerobic training in healthy subjects
Healthy Subjects Combined Training
We examined 5 men and 15 women, healthy subjects, mean age 28±9 years (from 23 to 39).
For exercise training we used aerobic and resistant training, 2x during week, constant load was kept
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. aerobic training 25 min., resistant
training 15 min. and cool-down period 10 min.
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Figure 2: Aerobic training as a part of combined training in healthy subjects
Figure 3: Resistant training as a part of combined training in healthy subjects
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Healthy Subjects Nordic Walking
We examined 7 men and 12 women, healthy subjects, mean age 26±7.1 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.
Figure 4: Nordic walking trace in the town Brno shows the red line
Patients with coronary heart disease
4. We examined patients with ischemic heart disease - infarctus of myocardium, mean age 62±8.9
years.
The set being monitored consisted of 53 patients after myocardial infarction in the past history
more than 3 months before. Mean ejection fraction of the left ventricle 43 ± 12.3 %. The patients were
diagnose and threated in the Dept. of cardio-angiology, Faculty of Medicine, Masaryk University, St.
Anne Teaching Hospital. The pharmacological therapy was not changed during the period of three
months during cardiovascular training.
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. Exercise unit was composed of 10
min. warm up period, 25 min aerobic training with the intensity on the level of anaerobic threshold
(measured using spiroegometry), 15 min resistant training on the level of 60% one repetition maximum,
10 min cool down period.
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Figure 5: Supervised aerobic training in patients with coronary heart disease
Figure 6: Resistant training in patients with coronary heart disease
Methods of 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.
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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).
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 exercise (0-24h) and the days without exercise (25-48h).
The study was approved by local ethic committee and the patients signed the informed consent.
Figure 7: Seven day ambulatory blood pressure monitoring
Figure 8: Blood pressure monitoring device A and D
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Results
Healthy subject –aerobic training
In healthy subjects the seven day blood pressure mean ± SE in systolic blood pressure was 115±1.1
mmHg, in diastolic blood pressure 69±1.4 mmHg in the whole group. Figure 9 shows seven day blood
pressure mean in men and women separately in systolic and diastolic blood pressure.
Figure 9: Seven day blood pressure mean in healthy subjects with aerobic training
In healthy subjects in the days with exercise (0-24h) blood pressure mean ± SE in systolic blood
pressure was 115±2.8 mmHg, in diastolic blood pressure 69±1.7 mmHg in the whole group. Figure 10
shows in the days with exercise blood pressure mean in men and women separately in systolic and
diastolic blood pressure.
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Figure 10: Blood pressure mean 0-24 h in the days with exercise in healthy subjects with aerobic training
In healthy subjects in the days without exercise (25-48 h) blood pressure mean ± SE in systolic
blood pressure was 116±3.4 mmHg, in diastolic blood pressure 69±2.2 mmHg in the whole group.
Figure 11 shows in the days without exercise blood pressure mean in men and women separately in
systolic and diastolic blood pressure.
Figure 11: Blood pressure mean 25-48 h in the days without exercise in healthy subjects with aerobic training
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Healthy subjects with combined training
In healthy subjects the seven day blood pressure mean ± SE in systolic blood pressure was 113±1.8
mmHg, in diastolic blood pressure 68±1.4 mmHg in the whole group. Figure 12 shows seven day blood
pressure mean in men and women separately in systolic and diastolic blood pressure.
Figure 12: Seven day blood pressure mean in healthy subjects with combined training
In healthy subjects in the days with exercise (0-24h) blood pressure mean ± SE in systolic blood
pressure was 112±1.9 mmHg, in diastolic blood pressure 69±1.5 mmHg in the whole group. Figure 13
shows in the days with exercise blood pressure mean in men and women separately in systolic and
diastolic blood pressure.
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Figure 13: Blood pressure mean 0-24 h in the days with exercise in healthy subjects with combined training
In healthy subjects in the days without exercise (25-48 h) blood pressure mean ± SE in systolic
blood pressure was 113±1.8 mmHg, in diastolic blood pressure 68±1.4 mmHg in the whole group.
Figure 14 shows in the days without exercise blood pressure mean in men and women separately in
systolic and diastolic blood pressure.
Figure 14: Blood pressure mean 25-48 h in the days without exercise in healthy subjects with combined training
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Healthy subjects with 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. Figure 15 shows seven day blood
pressure mean in men and women separately in systolic and diastolic blood pressure.
Figure 15: Seven day blood pressure mean in healthy subjects with Nordic walking
In healthy subjects in the days with exercise (0-24h) blood pressure mean ± SE in systolic blood
pressure was 111±1.5 mmHg, in diastolic blood pressure 67±1.4 mmHg in the whole group. Figure 16
shows in the days with exercise blood pressure mean in men and women separately in systolic and
diastolic blood pressure.
Figure 16: Blood pressure mean 0-24 h in the days with exercise in healthy subjects with Nordic walking
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In healthy subjects in the days without exercise (25-48 h) blood pressure mean ± SE in systolic
blood pressure was 113±1.8 mmHg, in diastolic blood pressure 69±1.4 mmHg in the whole group.
Figure 17 shows in the days without exercise blood pressure mean in men and women separately in
systolic and diastolic blood pressure.
Figure 17: Blood pressure mean 25-48 h in the days without exercise in healthy subjects with Nordic walking
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Patients with coronary heart disease
In patients with coronary heart disease the seven day blood pressure mean ± SD in systolic blood
pressure was 122±12.1 mmHg, in diastolic blood pressure 74±10.4 mmHg in the whole group. Figure 18
shows seven day blood pressure mean in men and women separately in systolic and diastolic blood
pressure.
Figure 18: Seven day blood pressure mean in patients with aerobic training
In patients with coronary heart disease in the days with exercise (0-24h) blood pressure mean ± SD
in systolic blood pressure was 121±10.1 mmHg, in diastolic blood pressure 74±7.8 mmHg in the whole
group. Figure 19 shows in the days with exercise blood pressure mean in men and women separately
in systolic and diastolic blood pressure.
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Figure 19: Blood pressure mean 0-24 h in the days with exercise in patients with combined training
In patients with coronary heart disease in the days without exercise (25-48 h) blood pressure mean
± SE in systolic blood pressure was 121±9.3 mmHg, in diastolic blood pressure 73±9.1 mmHg in the
whole group. Figure 20 shows in the days without exercise blood pressure mean in men and women
separately in systolic and diastolic blood pressure.
Figure 20: Blood pressure mean 25-48 h in the days without exercise in patients with combined training
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Discussion
Franz Halberg from University of Minnesota in the in the international project of Biospere
and Cosmos (BIOCOS) presented the cardiovascular parameters- blood pressure, heart rate in the
rhythmical predictable variation within the physiological range of multi-frequency rhythms, trends
and chaos, what he called broad chronomes, described also reference values for cardiovascular
parameters for gender and age. He described also with the international study of BIOCOS Vascular
Variability Disorders (14-17), which are connected with abnormal pattern of blood pressure and heart
rate, identified on the basis of ambulatory blood pressure monitoring (around the clock measurement)
and evaluated chronobiologically, are associated with increased cardiovascular disease risk (16). In an
internationally endorsed consensus (14,15) showed that these increased blood pressure, described as
MESOR hypertension, could be by Circadian Hyperamplitude tension increase (CHAT), by increased
Pulse pressure (17), by decreased heart rate variability much more further complicated and risky.
In one of studies, 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 (20). Exercise by a 46-year
old man in the Czech Republic was associ¬ated with an increase in the circadian amplitude of BP that
was more pronounced when exercise was done in the evening than in the morning, in his case leading
to an abnormal circadian pattern carrying an increased cardiovascular disease risk (6). Depending on
whether the circadian pattern of blood pressure tends to have too large an amplitude at the outset or
not, exercise should be timed to reduce both long-term and short-term blood pressure without bringing
about Vascular Variability Disorders that may be harmful and associated with a higher risk of a hard
ischemic event than MESOR-hypertension. Ambulatory blood pressure monitoring and chronobilogical
analysis can serve for the optimization of the timing of exercise on an individual basis (14 - 19).
High concentrations of homocysteine are associated with increased cardiovascular disease risk, by
causingendothelialdysfunctionandplateletaggregation.Exerciseintheeveningincreaseshomocysteine
more than exercise in the morning (20,21). In view of this finding, exercise may be preferred in the
morning compared to midday and evening, an observation also confirmed in our study in relation to
its effects on RB’ BP. There may be different conditions regarding the safety and usefulness of giving
priority for morning, evening or daytime exercise in different individuals. Clinical studies indicate
that acute ischemic events show a circadian rhythm in their incidence which correlates with increased
activity of the sympathetic nervous system and increased platelet aggregation during early morning.
Increased concentrations of plasma catecholamine and cortisol following sympathetic nervous system
activation can result in increased platelet aggregation (possibly by activating platelet α2-adrenergic
receptors), oxidative stress and deficiency of antioxidants and magnesium which are arrhythmogenic
(22). An interaction of circadian rhythm and exercise appears to be important in the pathogenesis of
atherothrombosis, because abnormalities in endogenous coagulation and fibrinolysis may contribute
in the development of an acute cardiovascular event (22,23). Circadian acrophases of fibrinogen and
platelet rhythms have been reported in the afternoon and evening but no study was found in a review
that related to the influence of exercise during morning and evening on fibrinogen and platelets (23).
There is some evidence indicating increased concentration of fibrinogen and decreased platelet counts
following an acute single bout of high intensity exercise (24).
Our results have shown that seven day blood pressure monitoring can give us better knowledge
about blood pressure values in every individual (9 – 13). To answer the question about the effect of
different kind of exercise on 24 h variability was not very easy. Our study showed in seven day blood
pressure record the days with and the days without exercise repeatedly and these day were analyzed
and they were compared with the seven day blood pressure results. On the basis of our results we have
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found that different kind of exercise does not change 24h blood pressure profile in healthy subjects.
The combined cardiovascular training in patients with coronary heart disease does not change the
systolic and diastolic blood pressure profile (9 – 19).
On the basis of the results we recommend the 7-day/24 h ambulatory blood pressure monitoring or
home blood pressure monitoring. The education for long-lasting self-monitoring is the best approach
for management of hypertension (16).
Conclusion
Our results showed that in healthy subjects one hour lasting aerobic training, combined training and
Nordic waking does not changed mean blood pressure from seven day/ 24h ambulatory blood pressure
monitoring.
In patients with coronary heart disease one hour lasting combined training (aerobic and resistant)
does not changed mean blood pressure from seven day/ 24h ambulatory blood pressure monitoring.
From the results we can conclude that 24-hours blood pressure profiles at rest and during exercise
from day-to-day vary in healthy subjects as well as in patients with coronary heart disease and 24h
blood pressure means were not different in the days with the exercise and without exercise.
References
	 1.	Singh RB, and Indian Consensus Group. Prevalence and prevention of hypertension, diabetes
mellitus, and coronary artery disease in India: A scientific statement of the International College of
Nutrition and International College of Cardiology. World Heart J 2010; 2: 31-44.
	 2.	Singh RB, Kumar A, Neki NS, Pella D, Rastogi SS, Basu TK, Acharya SN, Juneja L, Toru T,
Otsuka K, De Meester F and Wilson DW. Diet and Lifestyle Guidelines and Desirable Levels
of Risk Factors for Prevention of Cardiovascular Disease and Diabetes among Elderly Subjects.
A Revised Scientific Statement of the International College of Cardiology and International College
of Nutrition-2011.World Heart J 2011; 3: 305-18.
	 3.	American Heart Association Council on Nutrition, Physical Activity, and Metabolism; American
Heart Association Council on Clinical Cardiology; American College of Sports Medicine. Exercise
and acute cardiovascular events placing the risks into perspective: a scientific statement from the
American Heart Association Council on Nutrition, Physical Activity, and Metabolism and the
Council on Clinical Cardiology. Circulation. 2007; 115: 2358-68.
	 4.	Singh, RB, Halberg F, Cornelissen G, Siegelová J, Hristová K, Toda E, Toru T, Fedacko J, Otsuka
K. Personalized Circadian Timing of Exercise. World Heart J 2013, 5, 2, 79-90.
	 5.	Singh RB, Cornelissen G, Siegelova J, Halberg F. About half weekly pattern of blood pressure and
heart rate in men and women of India. Scripta Medica (Brno) 2002; 75: 125-128.
	 6.	Homolka P, Cornelissen G, Homolka A, Siegelova J, Halberg F. Exercise-associated transient
circadian hypertension (CHAT)? Abstract, III International Conference, Civilization diseases in
the spirit of V.I. Vernadsky, People‘s Friendship University of Russia, Moscow, Oct. 10-12, 2005, p.
419-421.
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	 7.	Siegelova J, Dusek J, Fiser B, Homolka P, Vank P, Kohzuki M, et al. Relationship between circadian
blood pressure variation and age analyzed from 7-day ambulatory monitoring. J Hypertens, 2006;
24 (Suppl.6):122.
	 8.	2007 Guidelines for the management of arterial hypertension: The task force for the management of
arterial hypertension of the European Society of Hypertension (ESH) and of the European Society
of Cardiology (ESC). J Hypertens, 2007
	 9.	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.
	10.	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.
	11.	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.
	12.	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.
	13.	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.
	14.	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.
	15.	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.
	16.	Cornelissen G.,Gierke C.L., Watanabe Y., Beaty L.A.,Siegelová J.,Decourt A., Deruyck Ch., Singh
R.B., Revilla M.A., Otsuka K. Ambulatory blood pressure monitoring for clinical application and
basic science. World Heart J 2015; 7(2),107-117.
	17.	Cornelissen G.,Siegelová J.,Watanabe Y., Otsuka K.Chronobiologically-interpreted ABPM reveals
another vascular variability anomaly (VVA):excessive pulse pressure product (PPP) updated
conference report. World Heart J 2012; 4(4),107-117.
	18.	Siegelová J, Havelková A, Dušek J, Pohanka M, Dunklerová L, Dobšák P, Cornelissen G. Blood
pressure variability at rest and during exercise in healthy men: Seven day blood pressure monitoring.
J Hypertension 2015, 33, 1,42.
	19.	Siegelová J, Dušek J, Havelková A, Dobšák P,Cornelissen G. Circadian rhythm in blood pressure in
newborns and adults. J.Hypertension 2015, 33,1,158.
	20.	Levine H, Saltzman W, Yankaskas J, Halberg F. Circadian state dependent effect of exercise upon
blood pres¬sure in clinically healthy men. Chronobiologia 1977; 4: 129-130.
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	21.	Thrall G, lane D, Caroll D, Lip GY. A systematic review of the effects of acute psychological
stress and physical activity on haemorheology, coagulation, fibrinolysis and platelet reactivity:
Implications for the pathogenesis of acute coronary syndromes. Thromb Res 2007; 120: 819-847.
	22.	Berger J. Chronohaematology. J Appl Biomed 2004; 2: 179-185.
	23.	van den Burg PJ, Hospers JE, van Vliet M, Mosterd WL, Bouma BN, Huisveld IA.Changes in
haemostatic factors and activation products after exercise in healthy subjects with different ages.
Thromb Haemost 1995; 74: 1457-1464.
	24.	Atkinson G, Edwards B, Reilly T, Waterhouse J. Exercise as a synchroniser of human circadian
rhythms: an update and discussion of the methodological problems. Euro J Applied Physiol. 2007;
99: 331-341.
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NONINVASIVE METHODS IN CARDIOLOGY 2015
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INTRA-DIALYTIC EXERCISE TRAINING COULD
IMPROVE VASCULAR TONE IN HEMODIALYZED
PATIENTS: A PRELIMINARY REPORT
Palanova P., Mrkvicova V., 2
Reichertova A., 2
Brychtova S., 2
Nedbalkova M.,
1
Vank P., 1
Sosikova M., 1
Homolka P., 1
Havelkova A., 2
Soucek M., 3
Kohzuki M.,
1
Siegelova J., 1
Dobsak P.
Department of Public Health, Faculty of Medicine, Masaryk University Brno, Czech Republic,
1
Department of Sports Medicine & Rehabilitation, St. Anne´s Faculty Hospital Brno, Cech Republic,
2
IInd
Department of Internal Medicine, St. Anne´s Faculty Hospital Brno, Czech Republic,
3
Department of Internal Medicine & Rehabilitation Sciences, Tohoku University Hospitál, Sendai, Japan
Abstract
We examined the effects of a 20-week intra-dialytic rehabilitation (ID-RHB) program on the
physical performance and arterial stiffness in a group of patients undergoing regular ambulatory
hemodialysis (14 men, 3 women; mean age: 45.4 ± 13.4 years; mean duration of dialysis: 5.9 ± 2.3
years). The patients underwent exercise aerobic training on programmable bed-side ergometers (letto2,
RECK MOTOmed®, GmbH, Germany) 2-3 times weekly. Seventeen patients completed the 20 weeks
of ID-RHB program. Five patients were excluded from the program for loss of motivation, 4 patients
for repeated failure to fulfill the prescribed training regimen and 1 patient was transplanted. Twenty
weeks of ID-RHB program led to significant increase of VO2peak (from 18.2 ± 5.8 to 19.7 ± 5.1 ml/
kg/min; P < 0.004); distance walked in 6 minutes (from 455.2 ± 98.2 to 526.7 m ± 139.6; P < 0.02);
muscle strength (from 271.7 ± 87.6N to 336.7 ± 97.7N; 0.02). Mean CAVI value significantly decreased
from the initial 8.02 ± 1.7 to 7.32 ± 1.9 (P < 0.02). The training protocol and workload intensity was
well tolerated by all the subjects and there were no adverse events, such as episodes of hypotension,
related to exercise. We conclude that structured intra-dialytic aerobic exercise training is safe and can
improve the endurance parameters and arterial stiffness in HD patients.
Key words
arterial stiffness - chronic kidney disease - functional capacity - exercise training - muscle strength
Introduction
According to the information from Institute of Health Information and Statistics (ÚZIS) there were
100 hemodialysis centers with 1.272 dialysis beds in Czech Republic by December 31, 2012. From
the 7.155 treated patients, 92% were on hemodialysis and 8% on peritoneal dialysis. The number of
executed treatments increased by 3.7 % compared to the previous year. More than half of these patients
were older than 65 years and almost 60% were men. The most frequent comorbidities were diabetes
mellitus and hypertension (1). The incidence of chronic kidney disease (CKD) shows tendency to
progression also in populations of other European countries. CKD has overall bad prognosis and its
diagnostics and therapy are demanding, from medical as well as economical point of view. Chronic
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uremia promotes neuro-humoral disturbances, endothelial dysfunctions, vasoconstriction, oxidative
and pro-inflammatory processes which potentiate one other (2, 3). These pathological changes in
patientswithCKDhaveimmenseimpactonskeletalmuscleswheredevastatingstructuralandmetabolic
changes and extensive atrophies take place (4, 5). Quality of everyday life drops and depressive mood
combined with premature muscle fatigue can be very dangerous incentive to sedentary life style (6).
For years, physical activity has been shown to improve cardiovascular and metabolic parameters in
healthy individuals and also in patients with a number of chronic diseases, including patients with
CKD. In patients on maintenance HD, moderate intensity intra-dialytic exercise training of aerobic
or resistance type have demonstrable effects, such as significant increase in functional capacity and
muscle strength (7, 8, 9, 10 and 11). Increased arterial stiffness is closely related to cardiovascular
mortality in patients with CKD on maintenance hemodialysis (HD). This is a direct consequence of
accelerated arteriosclerosis so that accurate monitoring of the extent of vessel wall damage could play
an important role (12, 13). However, still limited number of studies reported the beneficial effects
of aerobic exercise training on arterial stiffness in patients on HD (14, 15 and 16). These reports
were mostly based on the use of pulse wave velocity (PWV or baPWV); however, the accuracy of
this conventional non-invasive arterial stiffness assessment can be confounded by the elevated blood
pressure in the time of measurement (17). Cardio-ankle vascular index (CAVI) is a new parameter of
evaluation of arterial stiffness which reflects stiffness of aorta, femoral and tibial arteries as a whole
(17). CAVI, on the other hand, appears to be the parameter of choice because of its independence of
blood pressure changes and has been shown to be superior to the traditional PWV method.
Aim
This study aimed to assess the effects of 20 weeks of intra-dialytic exercise training on arterial
stiffness and on selected functional parameters in a group of patients on chronic HD.
Patients and methods
From the selected 35 regularly hemodialyzed patients with CKD only 27 started the ID-RHB
program (for more details see Figure 1 and the Results). The study was carried out in the Dialysis
Center at the IInd Department of Internal Medicine of St. Anne’s Faculty Hospital (Brno, Czech
Republic, EU) on the Fresenius 4008 S hemodialysis unit (Fresenius Medical Care®, Bad Homburg,
Germany) using Fresenius F70S or Fresenius F8HPS capillary dialyzers. Patients included in the study
underwent standard hemodialysis procedure 3 times a week. From the 35 selected patients 8 refused
to participate and 27 patients accepted to be included in the intra-dialytic rehabilitation (ID-RHB)
program (Figure 1).
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Figure 1: Flow-chart of the selection and participation of the HD patients in the ID-RHB program.
Exclusion criteria: uncontrolled hypertension, history of venous thromboembolism, implanted
cardiac pacemakers, unstable angina pectoris, heart failure, severe neurological diseases (epilepsy,
multiple sclerosis, parkinsonism), severe orthopedic complications (st.p.total hip or knee replacement),
chronic broncho-pulmonary disease, and urea clearance (spKt/v) >1.2. Inclusion criteria: at least 12
months of regular hemodialysis, symptomatic stability, and optimized pharmacological treatment
unchanged 1 month before the start of the study.
Performance testing Before the start of intra-dialytic RHB program, all patients underwent
standard spiroergometric test on bicycle for the evaluation of exercise performance and aerometabolic
capacity (peak O2 uptake), 6-min corridor walk-test (6-CWT) to evaluate the distance walked and
isometric dynamometry for measurement of maximal strength (Fmax) of leg extensors. To assess
peak aerobic capacity (VO2peak) and to determine the training intensity, each patient completed a
maximal incremental cardiopulmonary exercise test (CPX) with 12 lead electrocardiography (AT-104
PC, Schiller®, Baar, Switzerland) and blood pressure monitoring using standard methodology.
CPX was performed by all patients according to a standardized protocol by Wasserman et al. (18).
Spiroergometric test was done using calibrated electrically braked bicycle ergometer (Ergoselect,
Ergoline®, Bitz, Germany), with work rate increments of 10 watts, so as to provide test durations of
8–12min. Minute ventilation and gas exchange were measured breath-by-breath with an automated
metabolic measurement system (Power Cube, Ganshorn® Medizin Electronic, Niederlauer, Germany).
Peak oxygen uptake (VO2peak) was expressed as the highest value of O2 during last 30s of the test.
Maximal muscle strength of leg extensors was assessed by isometric dynamometry using the device
PC-2 SDT (EXAMO®, Recens Brno, CZ) with microprocessor. Measurements were carried out in a
sitting position; the chest of the examinee was fixed by 2 straps, pelvis and knees flexed at 90°. The
ankle of tested limb was attached to strength converter (D.OS SBEAM-1000N, EXAMO®, Recens
Brno, CZ). Subsequently, the tested subject performed 3 maximal voluntary extensions (contraction 3s
- relaxation 7s); the highest value of the three attempts was recorded as the maximal strength (Fmax;
N). 6-CWT is a standard diagnostic tool for assessing the physical performance at sub-maximal
intensities. At baseline and after 20 weeks the patients completed the 6-min walk on 30-meter lane
labeled by two plastic cones marking the turnaround points. During the test heart rate (HR) was
continuously monitored using the SF-Tester Polar S725-X (Polar Electro® Oy, Finland). Subjective
NONINVASIVE METHODS IN CARDIOLOGY 2015
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fatigue and dyspnea according to Borg scale was registered at 1-min intervals. The test was carried out
while respecting the principles and recommendations of the ACSM under the supervision of physician
and physiotherapist (19).
Training protocol After baseline testing, patients underwent 20-weeks of intra-dialytic aerobic
exercise training program consisting of cycling 3 days/week on programmable bicycle ergometers
(adapted on the subject’s dialysis chair or bed (Figure 2).
Figure 2: Examples of the aerobic exercise training program on programmable bicycle ergometers letto2 (RECK
MOTOmed®, GmbH, Germany) in the 2 IInd
Dept. of Internal Medicine, St. Anne´s Faculty Hospital Brno).
Training was done always between the 2nd
and the 3rd
hour of HD. The standard training session
was designed as follows: a) initial stretching of leg muscles before connecting to dialyzer (5min),
b) relaxing exercises of leg muscles (5min), c) passive cycling on bed-side ergometer (1min forward
+ 1min backward), d) active aerobic training on ergometer (30min), e) passive cycling on ergometer
(1 min forward + 1 min backward), f) relaxing exercise of leg muscles (5min), and g) terminal stretching
of leg muscles after disconnection from dialyzer (5min). Average time of 1 training session was 54
minutes. All training sessions were supervised by a professional staff (physiotherapists and nurses).
During first 10 weeks the active cycling was set for 30 min at an intensity representing 50% of the
peak workload rate determined by the incremental exercise test; from 11th
to 20th
week of ID-RHB
the training intensity was increased to 75% of the initial peak workload. Such design of the training
protocol enabled all the subjects to well adapt and tolerate the prescribed intensity and duration of
exercise.
CAVI assessment CAVI was measured by the vascular screening system VaSera® 1500 (Fukuda
Denshi Co, Tokyo, Japan) using standard protocol (17). Examination was performed in supine position;
4 pressure cuffs were placed on limbs, 1 microphone (phonocardiogram) above upper margin of
sternum and 2 ECG leads on both upper limbs. CAVI was automatically calculated according to
following formula:
CAVI = a [{2ρ × 1/(SBP – DBP)} × ln {(SBP/DBP) × PWV2]} + b
(ρ = blood density; a and b = constants)
In order to minimize adverse effects of cuff inflation on blood flow dynamics, the pulse waves were
recorded only when the cuffs were inflated to the pressure lower than the diastolic one (50mmHg).
Blood pressure (BP) on limbs was measured by oscillometric method; values of systolic BP (SBP),
NONINVASIVE METHODS IN CARDIOLOGY 2015
103
diastolic BP (DBP) and pulse pressure (PP) were obtained from record of BP on right a. brachialis.
Patients with ankle-brachial index (ABI) lower than 0.9 were excluded from the assessment.
Statistics
Microsoft Office Excel 2007 software for Windows Statistics and program version 10 MR1 were
used for data processing. All data are presented as mean and standard deviation. Non-parametric
Wilcoxon paired test was used for statistical analysis in order to exclude possible errors in normal data
distribution. The value P < 0.05 was considered as statistically significant.
Ethics
All patients signed informed consent to participate in the study; the study was approved by the local
ethics committee and conforms to the principles outlined in the Declaration of Helsinki (as revised in
Fortalezza, Brazil 2013) and to the GCP guidelines of the European community.
Results
From the included 27 patients only 17 completed the 20 weeks of ID-RHB program (14 men, 3
women; mean age 45.4 ± 13.4 years; mean body weight 71.8 ± 17.6; mean height 172.3 ± 9.2; mean BMI
24.1 ± 5.0; mean duration of HD 5.9 ± 2.3 years). Summary of comorbidities in 17 analyzed patients:
anemia (n=13), hypertension (n=11), hyperparathyroidism (n=8), dyslipidemia (n=4), hyperuricemia
(n=3), diabetes mellitus (n=2); nephritic syndrome (n=1); coronary artery disease (n=1) and ischemic
stroke (n=1). Five patients were excluded for loss of motivation, 4 patients for repeated failure to fulfill
the prescribed training regimen and 1 patient was transplanted. Mean adherence of the 17 analyzed
patients to the ID-RHB program was approximately 73%. The workload intensity was well tolerated,
all the patients were able to engage safely the prescribed intradialytic aerobic training program, and
there were no musculoskeletal, vascular access or hemodynamic complications (such as hypotension
episodes) as a consequence of the exercise intervention.
Peak oxygen uptake assessment. Statistical evaluation of VO2peak showed a statistically significant
increase after 20 weeks (from 18.2 ± 5.8 at baseline to 19.7 ± 5.1 ml/kg/min at the end of ID-RHB
program; P < 0.004). Changes of mean VO2peak values before and after ID-RHB are shown in Graph
1.
NONINVASIVE METHODS IN CARDIOLOGY 2015
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Graph 1: Results of the peak oxygen uptake assessed by spiroergometric bicycle testing.
6-CWT evaluation. Twenty weeks of supervised ID-RHB aerobic exercise program led to significant
increase of the distance walked in 6 minutes, assessed by 6-CWT (from 455.2 ± 98.2 to 526.7 m ±
139.6; P < 0.05). The changes of mean distance walked in 6min before and after ID-RHB are shown
in Graph 2.
Graph 2: Results of 6min CWT (distance walked).
Muscle strength evaluation. The measurements of maximal muscle strength (Fmax) assessed by
isometric dynamometry showed a significant increase after 20 weeks of ID-RHB (initial value 271.7
± 87.6N vs. 336.7 ± 97.7N in the 20th week; P < 0.02). The changes of mean Fmax values before and
after ID-RHB are shown in Graph 3.
NONINVASIVE METHODS IN CARDIOLOGY 2015
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Graph 3: Results of maximal strength of leg extensors assessed by isometric dynamometry.
CAVI assessment. The mean CAVI value significantly decreased after 20 weeks of ID-RHB from
the initial 8.02 ± 1.7 to 7.32 ± 1.9; P < 0.02). Based on the evaluation of initial CAVI the patients were
then divided into three groups according to the actual valid evaluation criteria: a) group with CAVI
<8.0 (normal range; n = 7; mean CAVI = 6.63 ± 1.2); b) group with CAVI 8.0 - 9.0 (borderline; n =
4; mean CAVI = 8.2 ± 0.2), and c) group with CAVI ≥ 9.0 (arteriosclerosis suspected, n = 6; mean
CAVI = 9.91 ± 0.6). After 20 weeks of ID-RHB the number of patients in the group with CAVI <8.0
(normal range) has increased to 11 (CAVI = 6.13 ± 0.9). This change was a direct result of a reduction
of CAVI in all the patients of the group 8.0 - 9.0 (borderline). There were no significant changes in the
group with CAVI ≥9.0 (arteriosclerosis suspected) and CAVI has remained at approximately the same
average value recorded at baseline (9.91 ± 0.6 vs. 9.94 ± 0.3; NS). The changes of mean CAVI values
before and after ID-RHB are shown in Graph 4.
Graph 4: Results of vascular stiffness assessment using parameter CAVI.
NONINVASIVE METHODS IN CARDIOLOGY 2015
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Discussion
The main problem of modern nephrology is the worldwide rapid increase in the number of patients
with advanced renal disease requiring hemodialysis or peritoneal dialysis. Typical symptoms of patients
on HD include extensive atrophy of skeletal muscles, decreased physical fitness and poor quality of life
(20, 21). The results of a series of studies published in the past 3 decades have clearly demonstrated
the positive effects of physical training on endurance, psychological well-being and quality of life (22,
23). Training on bed-side ergometers in a supine position during dialysis improves not only the cardiopulmonary
functions, but also muscle strength, fatigue, and physical ability. These results underline
the importance of endurance training during a dialysis treatment (24, 25). Results of the present study
showed an improvement in muscle strength of leg extensors and increase of maximal and submaximal
functional capacities after completing the ID-RHB program lasting 20 weeks. These findings are
in full concordance with those seen in previously published studies that used similar methodologies
and training equipment such as bed-side ergometers. It is widely recognized that decreased elasticity
results from structural changes which precede formation of atherosclerotic plaque or thrombus in
arteries. Increased arterial stiffness is an independent predictor of death from cardiovascular disease,
and cardiovascular diseases are the leading cause of death among patients with CKD. It has been
showed that incidence of arterial stiffness is higher also in hemodialysis patients (26, 27). Tanaka et
al. (2000) have demonstrated that regular physical activity appears to slow the loss of elasticity and
compliance in the human cardiovascular system (28). Miyaki et al. (2009) reported an increase in
central arterial distensibility after weight reduction by aerobic exercise training among over-weighted
and obese men (29). Physical activity enhances general cardiovascular fitness and it may also delay
or prevent age-related increase in arterial stiffness (30, 31). As mentioned above, only limited number
of trials in patients with CKD on maintenance hemodialysis showed that long-term exercise training
improves not only physical impairment and health-related quality of life but also the arterial stiffness
(14, 15 and 16). CAVI, a novel parameter of evaluation of vascular wall stiffness, accurately reflects
the extent of arterial fibrosis in HD patients and therefore should be considered as a useful indicator
in clinical practice (32, 33). The main and in actual scientific literature still unexplored topic of this
study was the evaluation of the effects of intra-dialytic aerobic exercise training on arterial stiffness in
HD patients with CKD using the parameter CAVI. CAVI reflects the condition not only of elastic, but
also of muscular arteries (34), and it means that CAVI value is strongly influenced by smooth muscle
cells activity in arterial wall, where a large variety of vasoconstrictive (angiotensin II, thromboxane
A2, endothelin, etc.) as well as vasorelaxative factors (NO●
, prostacyclin, natriuretic peptide, etc.) acts.
According to some recently published studies CAVI may reflect occurrence of global inflammatory
reaction of vessels in whole organism. Wakabayashi et al. reported that CAVI increases with plasmatic
level of C-reactive protein, amyloid A, sialic acid, fibrinogen and number of leukocytes in diabetes
mellitus type 2 (35). However, the mechanisms which cause increase of CAVI under these conditions
are not fully elucidated yet. Chronic uremic acidosis present in chronic renal failure is accompanied
by massive production of inflammatory and vasoactive substances which can trigger smooth muscle
cells reactions and initiate pathologic remodelation of vessel wall (27). Therefore it is very likely that
these bio-signals may also increase CAVI in patients with CKD. One study on patients under chronic
hemodialysis established a CAVI score of 7.55 as the cut-off value for suspecting the presence of
cardiovascular diseases highlighting the use of CAVI as a screening parameter that would help in
guiding subsequent treatment (28). The increased number of patients in the group with CAVI <8.0
(normal range) could be interpreted as a clear signal of positive effect of ID-RHB on the reduction
of cardiovascular risk (the final mean CAVI in this group was 6.13 ± 0.9, far below the cut-off value
of 7.55 in hemodialyzed patients as stated above). However, there were no significant changes in the
group with CAVI ≥9.0 (arteriosclerosis suspected) and it seems that CAVI was not influenced by the
NONINVASIVE METHODS IN CARDIOLOGY 2015
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exercise training. In other words, in the patients with higher CAVI the increased cardiovascular risk
persists. It is therefore possible to speculate about the suitability of prescribed training from the point
of view of intensity and composition. The subsequent detailed analysis of both CAVI groups (low and
high risk), however, showed that patients with CAVI <8 were significantly younger (mean age 39.7 ±
12 years) compared with the group with CAVI ≥9 (mean age 55.8 ± 8 years). Furthermore, younger
patients with low-risk had significantly lower average number of comorbidities (2.8 comorbidities
per person) compared to patients with high risk (4.2 comorbidities per person). These differences
undoubtedly influenced the final results. On the other hand, however, ID-RHB program in highrisk
patients (CAVI ≥9) led to significant improvement of the aerometabolic capacity and functional
performance at submaximal intensities. It is therefore evident that in the future trials it will be necessary
to pay more attention to the careful evaluation of the impact of physical activity on arterial stiffness in
patients on HD. One possible approach might be the analysis of plasmatic levels of different vasoactive
mediators (e.g., catecholamines, renin, angiotensin, endothelin, etc.) in relation to the value of CAVI,
etc. However, this was not included in the design of the present study. From general point of view it is
possible to conclude that the decrease of CAVI observed in this study could reflect the positive impact
of regular intra-dialytic aerobic exercise and may indicate a resulting beneficial effect on overall
vascular stability and endothelial functions, as well as a decrease of vasoconstrictive activity. This
opinion is based on findings from some above cited clinical studies wherein this effect was distinctly
demonstrated by changes of PWV. We assume that CAVI may be applicable complementary tool for
monitoring of CKD development and for monitoring of beneficial changes in vascular system elicited
not only by standard treatment (hemodialysis + pharmacotherapy) but also by regular exercise training
as was shown in the present study.
Conclusion
This study proved beneficial effect of intra-dialytic supervised aerobic training on functional
performance, muscle strength and vascular stiffness in patients on HD. We confirm that patients on
maintenance HD should engage intra-dialytic aerobic exercise training for at least 30 minutes per HD
session to prevent deterioration of their physical performance. Moreover, participation in the intradialytic
exercise program could be effective for maintenance of quality of life. However, it is necessary
to point out that our study provides only preliminary results because it did not deal with the changes
of the concentration of important plasmatic substances, such as urea, creatinine, etc. Other limitations
to be mentioned were also a limited number of analyzed patients and the absence of control (nonexercising)
group. While the positive influence of ID-RHB training on vascular stiffness is certainly
interesting, it is necessary to highlight one crucial point: the parameter CAVI has been introduced
into clinical practice only recently, and experience with its use with regard to the influence of physical
training on the human organism in healthy and unhealthy people is to date minimal. For this reason,
it is necessary to consider the presented findings with caution and to further study this potentially
important diagnostic methodology.
Acknowledgement
This study was supported by RECK MOTOmed®, GmbH, Germany.
NONINVASIVE METHODS IN CARDIOLOGY 2015
108
Disclosure
The authors declare no conflicts of interest.
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NONINVASIVE METHODS IN CARDIOLOGY 2015
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The use of neuromuscular electrical
stimulation in early phase of rehabilitation
in patients after total knee arthroplasty
to enhance quadriceps femoris muscle
strength
Mrkvicová V.1,2,3
, Palanová P.1,2,3
, Turoňová R.2
, Siegelová J.1,2
, Dobšák P.1,2
1
Department of Sports Medicine and Rehabilitation, St. Anne‘s Faculty Hospital and Masaryk University Brno,
2
Department of Physioterapy and Rehabilitation, Faculty of Medicine, Masaryk University Brno,
3
Department of Public Health, Faculty of Medicine, Masaryk University Brno
Summary
This study deals with early rehabilitation in patients after total knee arthroplasty combined with
neuromuscular electrical stimulation (NMES). The aim of this study was to evaluate the effect of
NMES to increase muscle strength of quadriceps femoris muscle (QFM).
Key words
rehabilitation, neuromuscular electrical stimulation (NMES), total knee arthroplasty (TKA),
quadriceps femoris muscle (QFM) strength
Background
Osteoarthritis is a chronic degenerative joint disease that negatively influences the quality of life of
many hundred thousands of elderly Czech people. More than 10.000 total knee arthroplasties (TKAs)
are performed each year in Czech Republic. Although TKA reliably reduces pain and improves
functional performance in older adults with knee OA, the recovery of QFM strength and function is
not optimal and predisposes patients to disability with increasing age. One month after TKA, QFM
strength declines up to 60% of preoperative levels, despite the initiation of rehabilitation early after
surgery. Even many years after surgery, QFM weakness persists in people with TKA compared with
healthy individuals. It has profound functional consequences – QFM weakness is associated with
decreased speed of gait, deteriorated balance and stair-climbing ability, and ability to rise from a
seated position, as well as with an increased risk for falls.
Effective physiotherapy strategies after TKA should focus to address QFM weakness. Impairments
in QFM strength are mainly due to deficits in voluntary activation and partially due to muscle atrophy
as well. Also spinal reflex activity from swelling or pain in the knee joint may modify afferent input
from the operated joint and result in decreased efferent motor drive to QFM that reduces muscle
strength (1 – 3).
Neuromuscular electrical stimulation (NMES) offers an innovative approach to potentially reduce
QFM voluntary activation deficits and prevent muscle atrophy early after surgery. Using NMES restores
NONINVASIVE METHODS IN CARDIOLOGY 2015
112
normal QFM function more effectively than voluntary exercise alone. Severe voluntary activation
deficits may limit improvements in muscle strength in response to rehabilitation that utilizes voluntary
exercise. It is probably because of the inability to generate muscle contractions of sufficient intensity to
promote strength gains (4 – 7). NMES has the potential to override voluntary activation deficits. Early
intervention with intensive NMES may offer greater benefits than the initiation of NMES 1 month and
later after TKA because it may be easier to prevent the decline of muscle function after surgery than
to reverse losses after they occur. It was found also in our earlier studies that NMES improves muscle
function in cardiac patients (8 – 12).
Objective
The aim of the study was to evaluate the influence of NMES of QFM by the assessment of isometric
strength of QFM in patients following TKA in early phase of rehabilitation The measurement was
done at the beginning and at the end of one-week rehabilitation program.
Methods
Twenty-eight patients of mean age 65.7 years after a primary unilateral TKA (tricompartmental,
cemented TKA with a medial parapatellar surgical approach), were randomly assigned to receive either
standard (non-NMES group) rehabilitation or rehabilitation supplemented with NMES (NMES group;
Figure 1). All the patients underwent surgery at The Orthopedic Clinic, and then the rehabilitation
program at The Inpatient Rehabilitation Department at St. Anne´s University Hospital.
Figure 1: Standard equipment for the application of NMES and positioning of the stimulating electrodes on the
thighs.
NONINVASIVE METHODS IN CARDIOLOGY 2015
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The stimulated muscles were the quadriceps of both legs. Self-adhesive surface electrodes
80x130mm (PALS® Platinum, Axelgaard Manufacturing Co., Lystrup, Denmark) were placed on
the thighs approx. 5cm below inguinal fold and 3cm above the upper patella border. Stimulation was
applied in supine position using portable, dual-channel battery-powered stimulators REHAB X-2
(CEFAR-COMPEX®, Switzerland). NMES characteristics were set up as follows: frequency 10Hz,
“on-off” mode stimulus (20s stimulation, 20s rest), pulse width 200msec, rise and fall time 1s, and
maximal stimulation amplitude 60mA. The intensity of NMES was always individually adjusted so
that it did not cause any unpleasant feelings or pain.
The rehabilitation program (Table 1.) lasted one week, patients were divided into two groups: nonNMES
group underwent a standard rehabilitation protocol with two physiotherapy sessions a day; the
physiotherapy of NMES group was supplemented with NMES of QFM that was applied once a day (1
session of NMES = 60 min).
All patients signed informed consent to participate in the study; the study was approved by the local
ethics committee and conforms to the principles outlined in the Declaration of Helsinki (as revised in
Fortalezza, Brazil 2013) and to the GCP guidelines of the European community.
Table 1: Rehabilitation program following TKA – subacute phase
Range of motion (ROM)
•	Active-assistive ROM for knee flexion
•	 Passive knee extension stretch
Strength
•	Quad sets, straight leg raises, hip abduction, hamstring curls, isometric strengthening
Functional activities
•	 Gait training, stairs climbing
Modalities
•	Local cooling by ice, positioning (flex-extend), NMES of QFM
Manual techniques
•	 Soft tissue techniques for scarf, patellar mobilization
Data for QFM strength was obtained using isometric dynamometer PS-2SDT. The initial testing
was done before the rehabilitation program started (12 ± 4 days after surgery); the final testing was
performed at the end of rehabilitation (19 ± 1 day after surgery). We analyzed the parameter of maximal
voluntary isometric contraction (MVIC).
Participants were positioned in an isometric dynamometer, stabilized with 90 degrees of flexion,
isometric contraction lasted 3seconds and was repeated up to 3 times, with 4seconds of rest between
attempts. The attempt with the largest MVIC output then was used for data analysis.
NONINVASIVE METHODS IN CARDIOLOGY 2015
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Results
Taking part at the rehabilitation program after TKA led to a beneficial outcome. Significant
improvement of QFM strength (average 46%) was obtained in both groups. In NMES group the values
of MVIC of QFM increased from initial 31.4 N/m to final 41.6 N/m (+62%; P < 0.01). In the nonNMES
group the improvement was from 26.3 N/m to 42,7 N/m (+32%; P < 0.01; Graph 2.).
Graph 2: Comparison of the initial and final values of MVIC of QFM in non-NMES and NMES group of patients
following TKA rehabilitation program
Discussion
The purpose of this study was to evaluate the efficiency of the NMES of quadriceps muscles,
combined with standard rehabilitation protocol. We expected that NMES would reduce QFM strength
loss by decreasing voluntary activation deficits and result in better functional performance outcomes
when compared with standard rehabilitation protocol.
A lot of studies refer to the fact that intensive rehabilitation care after TKA can accelerate patients
recovery and can lead in better functional outcomes (13 - 15).
Early rehabilitation programs should focus on improvement of QFM voluntary activation deficits,
which is mainly due to preoperative muscle artrogeneous inhibition and worsens with the operation
approach and pain (3, 13).
The addition of NMES initiated early after TKA attenuate loss of QFM strength in patients after
TKA and improve their functional performance; benefits of NMES treatment persist through 1 year
(6).
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Conclusion
One-week rehabilitation program in patients following TKA with or without addition of NMES
improves QFM strength. NMES seems to be an effective method complementary to standard
physiotherapy approaches, its´ application leads to rapid improvement of QFM strength and better
functional performance. Further research focused on early intervention after TKA is deserved to
optimize patient’s outcomes.
Disclosure
The authors declare no conflicts of interest.
References
	 1.	Lewek M, Stevens J, Snyder-Mackler L. The use of electrical stimulation to increase quadriceps
femoris muscle force in an elderly patient following a total knee arthroplasty. Phys Ther 2001; 81:
1565–71.
	 2.	Minns Lowe CJ, Barker KL, Dewey M, Sackley CM. Effectiveness of physiotherapy exercise after
knee arthroplasty for osteoarthritis: systematic review and meta-analysis of randomized controlled
trials. BMJ 2007; 335: 812. [PMCID: PMC2034713]
	 3.	Mizner RL, Petterson SC, Stevens JE, et al. Early quadriceps strength loss after total knee
arthroplasty: the contributions of muscle atrophy and failure of voluntary muscle activation. J Bone
Joint Surg Am 2005; 87: 1047–53. [PMCID: PMC1167681]
	 4.	Mizner RL, Petterson SC, Snyder-Mackler L. Quadriceps strength and the time course of functional
recovery after total knee arthroplasty. J Orthop Sports Phys Ther 2005; 35: 424–36.
	 5.	Petterson SC, Mizner RL, Stevens JE, et al. Improved function from progressive strengthening
interventions after total knee arthroplasty: a randomized clinical trial with an imbedded prospective
cohort. Arthritis Rheum 2009; 61: 174–83.
	 6.	Stevens JE, Mizner RL, Snyder-Mackler L. Neuromuscular electrical stimulation for quadriceps
muscle strengthening after bilateral total knee arthroplasty: a case series. J Orthop Sports Phys
Ther 2004; 34: 21–9.
	 7.	Stevens-Lapsley JE, Balter JE, Wolfe P, Eckhoff DG, Kohrt WM. Early Neuromuscular Electrical
Stimulation to Improve Quadriceps Muscle Strength After Total Knee Arthroplasty: A Randomized
Controlled Trial. Phys Ther 2012; 92(2): 210–26.
	 8.	Jančík J, Dobšák P, Eicher JC, Várnayová L, kožantová L, Siegelová J, Svačinová H, Placheta Z,
Toman J. Increase in muscle strength after low-frequency electrical stimulation in chronic heart
failure. Scripta medica, 2003; 76 (5) 285 – 290.
	 9.	Eicher JC, Dobšák P, Berteau O, Walker P, Verges B, et al. Rehabilitation in chronic congesrive
heart failure: comparison of bicycle training and muscle electrical stimulation. Scripta medica,
2004; 75 (5-6) 261 – 270.
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	10.	Dobšák P.; Nováková, M.; Fišer, B. et al. Electrical stimulation of skeletal muscles: An alternative
to aerobic exercise training in patiens with chronic heart failure? Japanese Heart Journal 2006, roč.
47, č. 3, s. 175-182.
	11.	Dobšák P, Nováková M, Siegelová J. et al. Low-frequency electrical stimulation increases muscle
strength and improves blood supply in patients with chronic heart failure. Circulation J, 2006,
roč.70, č.1, s. 75-82.
	12.	Dobšák P, Nováková M, Fišer B, Siegelová J, Balcárková P, Špinarová L, Vítovec J, Minami N,
Nagasaka M, Kohzuki M, Yambe T, Imachi K, Nitta S, Eicher JC, Wolf JE. Electrical stimulation
of skeletal muscles: An alternative to aerobic exercise training in patients with chronic heart failure?
International Heart Journal, Tokyo : International Heart Journal Association, 47, 3, od s. 441-453,
13 s. ISSN 1349-2365. 2006.
	13.	Berth, A. – Urbach, D. – Awiszus, F. Improvement of voluntary quadriceps muscle activation after
total knee arthroplasty. Arch Phys Med Rehabil, 2002, 83, 1432-1436.
	14.	Moffet, H. – Collet, Jp. – Shapiro, Sh. et al. Effectiveness of intensive rehabilitation on functional
ability and quality of life after first total knee arthroplasty. Arch Phys Med Rehabil. 2004, 85, 546-
556.
	15.	Silva, M. – Shepherd, Ef. - Jackson WO, Pratt JA et al. Knee strength after total knee arthroplasty.
J Arthroplasty. 2003, 18, 605-611.
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THE ROLE OF STRUCTURAL AND FUNCTIONAL
ASYMMETRY IN THE CIRCULATION
THOMAS KENNER1
AND DIETER PLATZER2
Center of Physiological Medicine, Medical University Graz, AUSTRIA, (1
Department of Physiology, 2
Department of
Biophysics)
Abstract
Asymmetry is a very remarkable property of biological structures and functions. Structure and
function of the human body are strong interrelated and depend on each other. Failures in structural
development often imply subsequent functional failures of the organism after the developmental
phase. It is the asymmetry in the cardiovascular system that plays an important role with respect to its
functional optimization. The time course of the contraction of the heart and of the ejection into the
large arteries is asymmetric in time in order to minimize energy consumption. The so-called Liebau
effect permits valveless pumping of fluids and essentially depends on the asymmetric properties of
conduits. One important example of the Liebau effect appears to be in the function of the coronary
vascular system. It can be shown that there are several mechanisms of so called valveless pumping that
contribute to the blood transport in the cardiovascular system. The common denominator of most of
these mechanisms is the dependence of the unidirectional pumping effect on asymmetry. It appears
that many additional examples of transport effects concerning fluids or gases in biology as well as in
engineering have their basis in the underlying structural asymmetry.
Introduction
As summarized in an excellent review by Mainzer [1], symmetry is an important property of many
systems in nature. Furthermore, as everybody knows, “the heart is on the left side of the body,” which
indicates that in the mammalian circulation asymmetry of structures and of functions is important
(Kilner et al.) [2].
During ontogenetic as well as during phylogenetic development the structure of the heart and of
the vascular system starts as a symmetric tube with symmetric branching. During phylogeny and with
the development of more sophisticated animals, the cardiovascular system develops more and more
asymmetric components. The same process also takes place in each individual during ontogeny.
Step by step the cardiovascular system becomes more asymmetric. Ewald Weibel in his book
Symmorphosis [3] has summarized the adjustment in human beings and in animals of the adequate
development of structures in relation to their function by the Greek term “symmorphosis”. The term
“symmorphosis” indicates that a certain structure is ideally adapted to performing specific functions.
Weibel describes “symmorphosis” as follows: “State of structural design commensurate to
functional needs resulting from regulated morphogenesis whereby the formation of structural elements
is regulated to satisfy but not exceed the requirements of the functional system. It is obvious that the
principles of adaptation, integration and economy are satisfied if structural design is commensurate to
functional needs throughout the organism.”
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There are many ways of economizing the function of the cardiovascular system. Of course, it cannot
be denied that many ideas about biological economy and optimization are incompletely understood.
Concerning the cardiovascular system, besides the heart, additional pump mechanisms help to propel
the blood through the arteries, capillaries, and through the veins back to the heart and the lung. If one
compares animals of different sizes, a strong indication for optimal function seems to follow clearly
from the similarity of structures and functions, which obey certain rules of similarity.
Finally, it is suggested that the so-called Liebau effect may be involved in improving vascular blood
transport (Kenner [4], Moser [5]).
The historic glass model of the aortic arch (Figure 1) not only shows how the fluid turns through
the aortic arch, but also depicts the functional role of the arch [6].
Figure 1: Glass model of aortic arch (from: Wetterer and Kenner, 1968)
Evolution and Development of Cardiovascular Asymmetry
The Austrian Nobel Laureate Karl von Frisch also pointed out the modification of the heart and
the main vessels among vertebrates, showing a distinct evolution from symmetry to asymmetry [7], as
shown in Figure 2.
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Figure 2: Evolution of the heart and large arteries - from gills to lung (from Frisch, 1960)
During the first weeks of embryonic life the heart as well as the vascular transport system consists
of a symmetric line of elastic and contractile tubes. As shown in the textbook of embryology by Moore
(1985) [8] this system is still symmetric on the 35th day of embryonic life. Therefore, the contraction of
the heart chambers, which are positioned in series between the veins and the aorta, at this time mainly
occurs in the circumferential direction. Even in this very early time of development, another type of
asymmetry exists in the following sense: The blood in circulation flows from more distensible veins
to the heart and lung and then is directed forward to less distensible arteries, and thereon circulates
through the capillaries back to the veins. In the early embryonic development valves have not yet
been formed. Therefore, the asymmetry in distensibilities is a condition that enables the generation of
unidirectional valveless flow as proposed by Liebau (1970) [9].
During the following days of life, the contractile part of the tubes, i.e. the early structural state of
the heart, folds and twists in a rather complex manner. The aortic–arterial outflow system divides,
giving rise to the double outflow into aorta and pulmonary artery. Furthermore, the aorta becomes
asymmetric because, from the early symmetric double arch only the left arch survives completely.
Finally, the left and right pumps are positioned side by side. All these developmental processes are
completed before the 49th day of embryonic life. Therefore, the two chambers of the heart are then
able to contract in circumferential as well as in lengthwise direction.
In addition recent hemodynamic data from living embryos further confirm that the pumping
function of the embryonic heart actually differs from a peristaltic pump in several respects and that
the embryonic heart tubes act as valveless “Liebau pumps” [10].
In adults, as indicated in Figure 3, both ventricles constrict and shorten during systole. By this
shortening the atria are extended. It follows that during ventricular ejection the atria are filled with
blood from the large veins. This is the “mechanism of the moving plane of the valves” mentioned
before. More recently, in the English literature the longitudinal shortening of the ventricles is included
in the term “long axis dynamics of the heart” [11].
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Figure 3: The left part of the figure shows the heart in diastole, the right part shows the heart in systole—both
from the left side. The movement of the plane of the valves can well be seen (from Boehme 1936) [12].
The simultaneous pumping action of the two ventricles of the heart has such a high effectivity
because of the asymmetry which is produced during early development by turning, folding, and
partitioning into two tubes pulmonary system and aorta. The so-called mechanism of the moving
plane of valves permits the heart to pump by combined circumferential and lengthwise contraction.
There seems to be a correlation between a highly adaptable cardiovascular transport capacity
and the degree of asymmetry in the heart and large vessels. One interesting example, well known
already in the 19th century is the “mechanism of the moving plane of the valves” (in German
“Ventilebenenmechanismus”). This mechanism is well summarized in a paper by Henke (1872) as
cited by Boehme [12]. The function of these mechanism is only possible through the asymmetric,
folded, and twisted configuration of the heart that develops during embryonic life. In addition, all
highly efficient fast-moving animals have an asymmetric one-sided aorta. It seems that the necessity
of blood mixing in the heart chambers may also be involved in the process of optimization [2].
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Figure 4: The plane of the AV-valves (from Braus 1921 [13])
Valveless Pumping, a Consequence of Structural Asymmetry
Liebau was a physician and practitioner interested in physical curiosities. He published several papers
and formulated patents about the principle of valveless pumping [9]. As discussed earlier (Kenner [4],
Moser [5]) there are certain conditions for the functioning of this effect. The first condition is an energy
driven source of fluid movement. The second condition is asymmetry of conduits. The components
of this asymmetry are inertia and compliance. The latter is a mechanism to store potential energy and
fluid volume and, in stiff-walled tubes, may be due to gravitational effects. The third condition is an
asymmetry of the time course of movements. An example for a model of the Liebau effect is a circular
tube, half of which is made of a rigid tube. The other half is made of a distensible rubber tube. If the
distensible tube is compressed periodically (with a finger) in an asymmetric location, fluid moves into
the direction of the more closely located rigid tube.
Another model is a straight elastic tube, which consists of a more distensible and wider part and of
a stiffer and narrower part. Compression of the wider part moves fluid from the wider to the narrower
(and stiffer) part of the tube. This model was especially studied by Liebau himself and was, as an
example of the effectiveness of the mechanism, depicted in one of his patent applications. This model
could also serve as a possible mechanism of valveless pumping of the early embryonic heart.
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Figure 5: Liebau-effect, a valveless pumping mechanism (from Moser, 1998 [5])
The simplest model that can be used to demonstrate valveless unidirectional flow was already
mentioned above. It consists of a fluid-filled circular tube [4,5]. The upper half of the model is a rigid
glass tube. For the other half a flexible and distensible rubber tube (e.g., Penrose rubber) is used. If
this distensible tube is compressed rhythmically by a finger at an asymmetric location on the right
side of the circle then the fluid moves in counterclockwise direction. If the tube is compressed in
the same manner in the symmetric middle of the distensible tube, then no net movement of the fluid
can be observed. If the tube is rhythmically compressed at the left side, the net movement starts in
counterclockwise direction.
This simple and impressive experiment, which, in different modifications, had already been
performed by Liebau himself [9], raises the following questions:
(1) What are the conditions for unidirectional net motion of fluid?
(2) What determines the direction of fluid movement?
As far as the pump (the source) is concerned it is interesting to note that this pump must be able
to change its characteristics during one cycle of action. We can assume that a fast and complete
compression, as shown in the upper part of Figure 4, generates more or less symmetric flow pulses.
Thus, the compressed site acts as a flow pump in both directions. It follows that the same volume is
pushed into both directions of the compression.
Immediately after the subsequent release of the compression the pressures on both sides of the
“pump” equalize (Figure 5, lower part). The location has now changed to a location with low internal
resistance, i.e., a pressure pump. During the following events the backward flow to the pump through the
tube with the high inertance is more delayed when compared to the flow on the other side of the pump.
This process generates, on average, a preferred flow direction toward the side of higher inertance. The
essential functional asymmetry in effect acts during the compression phase when the flow generating
part of the stroke forcefully pushes the fluid into the part of the tube with high inertance.
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Asymmetry of Time Course
Asymmetryoftimecoursecanbeobservedondifferenttimescales.Thetimecourseofenvironmental
variables as well as the wake and sleep pattern have a marked influence on physiological variables
like heart rate, blood pressure and many others. This is the major area of investigation in circadian
physiology.
On a fine time scale there also exist marked asymmetries e.g. as far as functions in the circulation
are concerned, the time course of blood ejection from the left ventricle into the aorta. Normal ejection
function starts from zero with a steep increase of the flow to reach a peak level. The flow then decreases
with a slow declining downslope, which, in a typical normal example, has a small bump. It can be
concluded that the optimal and most economic ejection flow is markedly asymmetric in terms of time
course.
In fact, there is another asymmetry regarding the time periods of the cardiac cycle. The normal
cardiac cycle can be divided into a shorter systole and a longer diastole. It can be shown that this
asymmetry is essential for optimal coronary perfusion.
On the level of individual cells the action potential, preceding the mechanical contraction also
exhibits a marked asymmetry, with typical steep potential change at the start of each individual
heartbeat.
Discussion and Conclusion
Asymmetry is an essential feature of the cardiovascular system. The Liebau effect is an interesting
phenomenon the importance of which is still uncertain. The circular model first chosen by Moser [5]
to analyze the Liebau effect, actually demonstrates that in an asymmetric system a net flow can be
generated by a symmetric pump. There is, in addition, an asymmetry of function and time course, in
particular, if the sequence of compression and release is considered. It is possible to generate valveless
flow in a number of systems under the condition of an energy-consuming input by a two-phase pump: a
circular model of elastic and rigid tubing and a system of rigid tubes, where the fluid surface simulates
elastic effects. It follows that the principle of asymmetric flow generation plays a role in several
biological or medical situations. One quite important location for the influence of asymmetry is the
coronary vascular system.
A systolic activation sequence that starts from the left side and proceeds to the right side would
produce a compression of the vessels similar to a peristaltic process. In addition, there is no question
that further asymmetries, including nonlinearities of the system, may also add to unidirectional flow
effects.
The overall efficiency of this type of pumping has been estimated by Moser [5] comparing a system
without valves to a system with valves. The unidirectional flow without valves, on average, is less than
half when compared to the flow generated with valves. In spite of the disadvantage of a rather small
efficiency, the Liebau phenomenon of valveless unidirectional flow serves well as a source of flow in
the embryonic circulation or in other valveless biological flow systems, and acts as an additional energy
source for a flow in the adult circulation. Therefore, the Liebau effect most probably contributes to the
optimal use of energy in the cardiovascular system. It is certain that there are more pump mechanisms
in the system than the heart alone [5].
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Finally it is necessary to mention the role of respiration. The periodic variation of thoracic pressure
certainly is an additional source of transport energy. In needs to be noted, that this mechanism in part
depends on the cardiac valves. However, the influence of a Liebau-effect type of blood transport has
to be taken into account as well [14].
References
	 1.	Mainzer K. Symmetrien der Natur, Berlin. New York: de Gruyter Verlag, 1988
	 2.	 Kilner PJ, Yang GZ, Wilkes AJ, Mohiaddin RH, Firmin DN, and Yacoub MH. Asymmetric
redirection of flow through the heart. Nature 2000 (404): 759–761
	 3.	Weibel ER, Symmorphosis, on Form and Function in Shaping Life, Cambridge, Mass.: Harvard
University Press 2000
	 4.	Kenner T, Moser M, Tanev I, Ono K. The Liebau-effect or: On the Optimal Use of Energy for the
Circulation of Blood. Scripta Medica – Brno (73), 9-14, 2000
	 5.	Moser M, Huang JW, Schwarz GS, Kenner T, Noordergraaf A. Impedance defined flow –
GeneralizationofWilliamHarvey’sConceptoftheCirculation–370YearsLater.IntJCardiovascular
Medicine and Science 1998 (1), 1: 205-11
	 6.	Wetterer E, Kenner T. Dynamik des Arterienpulses. Berlin, Heidelberg, New York: Springer, 1968
	 7.	von Frisch K. Biologie - I. Band, München: Bayerischer Schulbuch Verlag 1960
	 8.	Moore KL. Embryologie. Stuttgart: Schattauer Verlag, 1985.
	 9.	Liebau G. Über periphere Blutförderung. In Pestel E and Liebau G (Eds.) Phänomen der pulsierenden
Strömung im Blutkreislauf aus technologischer, physiologischer und klinischer Sicht. Mannheim,
Wien, Zürich: Bibliographisches Institut, pp. 67–78, 1970
	10.	Männer J, Wessel A, Yelbuz TM. How does the tubular embryonic heart work? Looking for the
physical mechanism generating unidirectional blood flow in the valveless embryonic heart tube.
Developmental Dynamics: 239(4): 1035.46, 2010
	11.	Juznik SCJE, Juznic G, Knap B. Ventricular Shape: Spherical or Cylindrical? In: Drzewiecki GM,
LI JK (eds.) Analysis and assessment of cardiovascular function. New York, berlin, Heidelberg:
Springer 1997
	12.	Boehme W, Über den aktiven Teil des Herzens an der Förderung des Venenblutes. Ergebnisse der
Physiologie (38): 251 -228, 1936
	13.	Braus H. Anatomie des Menschen, Berlin: Julius Springer Verlag 1921
	14.	Kenner T, Moser M, Huang, Noordergraaf A. Optimization of structure and function of the
cardiovascular system. Third World Congress of Biomechanics in Sapporo. Abstract, p. 44, 1998.
NONINVASIVE METHODS IN CARDIOLOGY 2015
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WHAT WE CAN LEARN FROM MODELING CARDIAC
FUNCTION?
DIETER PLATZER1
, KLAUS ZORN-PAULY1
AND THOMAS KENNER2
Center for Physiological Medicine, Medical University Graz, AUSTRIA,
(1
Department of Biophysics, 2
Department of Physiology)
Abstract
Physiology has always followed an integrative approach to gain insight into the functions of the
human body. The system approach considers biological processes as systems of interacting components.
Mathematical and computational modeling aims to bridge the gap between experimentally gained
observations of isolated components and the desired understanding of the whole living organism in
health and disease. This approach requires a clear definition of the purpose, the assumptions, and
the boundaries of the model. It is necessary that mathematical models have to be based on reliable
experimental data. At present we witness an amazing development and refinement of biophysical
methods to quantitatively describe biological phenomena with increasing accuracy. In parallel,
sophisticated computational techniques enable the increasingly efficient solution of ordinary and
partial differential equations, which are used to describe these systems in the language of mathematics.
The hierarchical nature of causal knowledge and understanding consequently leads to “multi-scale”
modeling, integrating important features across multiple levels of organizational, spatial or temporal
scales. Perhaps the most advanced area of computational physiology is computational cardiac
electrophysiology, investigating the electrical activity of the heart. Multi-scale cardiac modeling and
simulation have been crucial in improving our understanding of ionic mechanisms of normal and
abnormal heart rhythm, electrotherapy, and the electrocardiogram.
Introduction
Andreas Vesalius (+1564) not only was the father of modern anatomy, he was also an essential
contributor to modern medicine with his work on the vascular and circulatory system (Figure 1).
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Figure 1: The heart at the center of the circulation, Vesalius A. (1546)
Very early, as soon as the development of experimental techniques allowed first steps, cardiac
function has been in the focus of physiologists, with the ultimate aim to get more insight into one of
the most essential processes found in all higher developed life forms. With the advent of increased
computational capabilities, mathematical and computational modeling have become invaluable tools
to better understand complex phenomena. Particularly computational modelling of essential cardiac
functions (cardiac electrophysiology coupled to cardiac mechanics) is a current major effort with
notable results.
Scientific models are used to explain and predict the behavior of real objects or systems and are used
in a variety of scientific disciplines. Although modeling is a central component of modern science,
scientific models at best are approximations of the objects and systems that they represent—they are
not exact replicas. Thus, scientists constantly are working to improve and refine their models.
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Figure 2: Principle of scientific workflow when targeting mathematical modelling and computer simulation
towards a specific aspect of reality.
The heart of the workflow in natural sciences is the attempt to grasp reality with reproducible
measurements. This has been markedly expressed by Lord Kelvin, when he said: “… when you can
measure what you are speaking about, and express it in numbers, you know something about it; but
when you cannot measure it, when you cannot express it in numbers, your knowledge is of a meagre
and unsatisfactory kind; it may be the beginning of knowledge, but you have scarcely, in your thoughts,
advanced to the stage of Science whatever the matter may be.” [1]
Therefore experiments form an indispensable component in the scientific workflow to provide
the observations that reveal aspects of the reality. In other words, “scientific reality” is that part of
the information that natural scientists accept. However this is achieved by a reduction of dimensions
(Figure 2).
CARDIAC FUNCTION: A MULTI-SCALE MULTI-DOMAIN RUSSIAN
DOLL
To better understand an organism or a living system, multiple models, each representing a part of
the object or system, are needed. Collectively the particular submodels may be able to provide a more
complete representation, or at least a more complete understanding, of the real system.
Modular systems can be decomposed in first approximation into structurally and functionally
independent parts. Obviously the human mind “is looking for” modules.
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Figure 3: Investigating the cardiac function is actually like playing with a Russian doll
Highly sophisticated multi-scale (from cell-to-organ) computational models have been developed to
reproduce the electrophysiological activity of the heart.
These models span a hierarchy of scales. When we look at cardiac function we find different levels
(shells), ranging from macroscopic to microscopic scales:
a.	 systemic whole body/patient level
b.	 organ level
c.	 tissue level
d.	 cell level
e.	 subcellular
f.	 molecular
On each scale different experimental as well as modelling techniques are needed.
THE CLOSED LOOP DILEMMA: THE WHOLE IS MORE THAT IT’S
PARTS
In the living organism interconnected feedback loops enable a proper adjustment to internal and
external changes and provide a safety mechanism against failure of individual components (Figure 4).
The cardiovascular control system effectively maintains arterial blood pressure using heart rate and
heart contractility as primary regulating variables.
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Figure 4: The cardiovascular system as a set of interconnected feedback loops
Very early at the advent of “System Dynamics” in the late 1950s and early 1960s it became feasible
to study the circulatory system using the emerging analog computers [2].
About the same time when Hodgkin and Huxley were investigating the electrical properties of
isolated squid axons and were eventually able to formulate a set of equations – actually coupled
ordinary differential equations (ODEs) to adequately describe their experimental observations [3].
These formalisms have since then become the core basis for the vast majority of computational models
of excitable tissue.
To enable sharing of the growing number of basically ODE-based models, CellML – originally a
common model description language, has been used to establish a public model repository (https://
models.cellml.org/cellml). Currently it already contains several hundred models, whose properties are
encoded using a common convention of model specifications, components and annotations [4]. This
collection of models is constantly expanded, using refined sophisticated experimental setups, exciting
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cardiac tissue preparations and isolated cells in order to reveal cause effect relationships between
specific system variables.
While these cellular models are still not first principle based, but rather heuristic, they nevertheless
contribute essentially to the predictive power at the higher hierarchy level model (e.g. tissue or
whole heart). This reintegration into the higher level model of course implies knowledge about the
interconnections between the constituting submodels (i.e. understanding of the structure, see Figure 2).
The following experimental examples serve to illustrate the points made above. In optical mapping
potential sensitive dyes and laser light excitation together with field stimulation are used to reveal
hidden structural information of cardiac tissue at microscopic level.
Figure 6 and 7 show excitation experiments using either a local current stimulation or global external
electric field stimulation of atrial guinea pig tissue to visualize the resulting pattern of excitation.
Comparing the resulting activation maps, one can see that a tailored field stimulation experiment
visualizes structural discontinuities of the tissue [5].
Figure 5: Photograph of a typical adult isolated guinea pig atrium. The overlay visualizes the excitation, elicited
by a suprathreshold current pulse applied at point P, as isochrones. Instant depolarization of about 1/3rd of the
atrial tissue is followed by a well-defined wave front propagating at a velocity of ~0.2 mm/ms.
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Figure 6: Photograph shows the same preparation. The overlay depicts the isochrones of excitation, elicited
by a suprathreshold electric field pulse applied across the atrium. The activation map reveals distinct multiple
sources, where excitation start simultaneously. Consequently the time to excite the whole atrial tissue is reduced
to ~ 1.5 ms.
The next step towards a computational model is the translation of empirical data into the language
of mathematics (i.e. formulating the adequate ordinary and partial differential equations (see Figure 2).
For simulation purpose the mathematical model has now to be turned into a computational model.
Whereas time and space are continuous in the mathematical model, for computer simulations, we
have to describe the system in discrete time and space. The continuous arrow of time is replaced by
a sequence of discrete points in time. In additions space is discretized as well and replaced by a grid of
lumped entities, whose dynamic behavior generally can be described by ordinary differential equations
in time. Together with the knowledge of the coupling determined by the given spatial structure these
description forms a mesh, as shown in Figure 7.
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Figure 7: Discretization of time and space by formulating an equivalent discrete electrical circuit. For a twodimensional
approximation of in this case uniform cardiac muscle sheet with gAPm designating a generalized
action potential model and rx and ry being the intracellular coupling resistances in directions x and y. The
time development of the resulting electrical behavior is computed for discrete points tk along the arrow of time
(modified from [6]).
At this point, we now deal with the question of whether the properties of the continuous problem
are inherited to the discretized problem. Unfortunately, at the current stage of development, there is no
general answer to this question.
So far experiments have driven the model generation process, culminating in numerical simulation
studies. Computational modelling contains an additional potential, namely to inspire new experiments
and hypothesis (see Figure 2). For example in the case of field stimulation experiments of isolated
myocytes [7], the simulation experiments suggested the presence of a hitherto unknown ionic current,
which is under current experimental investigation.
The ultimate goal is to unify experiment and simulation, so that they are not viewed as separate
activities but that are a shared set of techniques to solve problems.
A new and exciting hierarchical level is opened by modeling the protein structures which are key
components of all life processes. Every heart beat relies on proper opening and closing of specific
proteins, the so called “ion channels”. Figure 8 shows computer based visualization of a yet not
determined three dimensional structure of the pore forming molecule of s specific cardiac ion channel
[8]. This adds new structural information to better understand ion channel functioning and also its
interactions with pharmacological relevant substances.
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Figure 8: Identification of residues that determine TRPC3 function based on its homology to TRPV1
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Conclusion
So,whatcanwelearnfromcomputationalcardiacmodelling?InanutshellIwouldsay,computational
cardiac modelling allows us to evaluate the relevance of scientific hypotheses targeting complex
biological phenomena and simultaneously deepens the insight into the material processes underlying
these phenomena. In both aspects modelling helps to improve our understanding of scientific reality
and thereby deblurring the image of reality provided by natural science.
References
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NONINVASIVE METHODS
IN CARDIOLOGY 2015
Edited by: Kenner T., Cornélissen G., Siegelová J., Dobšák P.
Published by Masaryk University in 2015
First edition, 2015
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ISBN 978-80-210-8031-7