Heart rate variability: How to assess effects of mild therapies on autonomic control in small groups of mild and borderline hypertensives?

Hypertension 2000, 35: e6-e7

Bettermann H, Cysarz D & Kümmell HC

To the Editor:

In their recent retrospective study [1] Singh et al. could demonstrate on the basis of the impressively huge data set of the Framinghan Heart Study that, first, short-term HRV is reduced in men and women with systemic hypertension and, second, among normotensive men, lower HRV was associated with greater risk for developing hypertension. The authors concluded that autonomic dysregulation is present in the early stage of hypertension. Their findings are important but were not very surprising because the reported HRV reduction was generally in accordance with findings of earlier studies [2]. However, what they inevitably left out of consideration was the analysis of the diurnal variation of blood pressure, heart rate and their respective variabilities. Particularly the asleep/awake ratios of blood pressure are probably more specific and sensitive than temporary daytime parameters [3]. From the methodical points of view, the study was characterized by the strong and uncompromising use of statistics, but unfortunately without showing any raw data, e.g. by using scatter or box plots of the blood pressure and HRV data. Moreover, one important question remained unanswered: How did the HRV parameters and the covariates change during 4 years of follow-up?

Independently and without knowledge of the results from the above study, we also studied the differences of linear and nonlinear HRV parameters in (only) 25 essential non-treated hypertensive subjects with respect to their status of hypertension. The study was carried out from spring to fall 1998 and the results are not yet published. The purpose of our study was to gain experience in the collection and interpretation of HRV data from hypertensives for further studies. When comparing our HRV mean values with the values from the Singh study, we were very surprised: After log transformation, the mean values of LF, HF, and LF/HF were approximately identical with those of Singh and colleagues in Table 2 of their paper. As a result of the small N, our SEM (standard error of the mean) values were up to 10 times higher than those of the huge Framingham group. Consequently, significant differences between subgroups could not be demonstrated and both specificity and sensitivity of all HRV parameters were extremely poor. The separation of subgroups was much better for the nocturnal BP fall which could not be observed by Singh et al. by reason of the Framingham study design. And we achieved better results analyzing the 24-hour blood pressure course and using nonlinear HRV parameters instead of the linear spectral HRV markers LF and HF. The most prominent correlation, for example, could be observed between the relative nocturnal blood pressure fall and the approximate entropy (ApEn) of daytime heart period dynamics [4]. As the clinical relevance of our observations remains to be proven, it makes sense if, in future, results like ours could be taken into consideration when analyzing large clinical databases of heart beat and blood pressure data. Particularly, it would seem to be very promising to analyze the time course of 24-hour BP level, if available, and to include also nonlinear measures in 24-hour HRV analysis.

Another problem is how to make use of subtle group differences of huge cross sectional studies, like those of Singh and colleagues, when dealing with only a few, but very individual subjects. And what does adjustment of measures for clinical covariates (e.g. age, gender, body mass index, alcohol consumption, and cigarette smoking) mean in the clinical practice?

These problems and others, occurring in clinical practice as well as in many clinical research settings, are not new, but most studies, e.g. in hypertension, have not adequately taken the constraints of daily clinical routine into consideration.

We therefore propose to design in future preferentially longitudinal sectional or single case HRV studies rather than cross sectional clinical HRV studies. These studies could address the question: How do HRV parameters change in individuals over longer periods of time with respect to the change of their status of hypertension and with respect to clinical covariates? These studies would not provide odds ratios or similar epidemiological parameters, but clinicians would be enabled to judge an increase or decrease of HRV parameters in individuals, e.g. during therapy, which may be more informative than one single starting value. It is a well known phenomenon that on the one hand sensitivity and specificity of 24-hour HRV measures are generally poor, but on the other hand reproducibility in individuals is excellent (cf. [5, 6]). Thus, small changes of autonomic control, e.g. as an effect of a mild anti-hypertensive intervention, may be well demonstrated in individuals, but may be smeared in large populations.

We suppose that, when following the above recommendations, HRV methods may help to gain further insight into subtle rhythmic and individually different regulatory processes in the human organism. All HRV parameters are per se mirrors of the whole human time organism, reflecting a multitude of internally and externally triggered physiological rhythms influencing each other. Mild therapies, like sports activities or psychosomatic therapies, are often individually conceptualised to stimulate rhythmical processes in the human organism and to enforce self-regulatory processes. Their therapeutic effects are naturally difficult to recognise because they are masked by various clinical or daily life activities that spontaneously influence many clinical parameters more than the therapy itself. The analysis of HRV in individuals, including methods from nonlinear dynamics and taking the 24-hour heart rate and BP variations into consideration, altogether could well have the power to become a useful diagnostic tool, particularly in mild and long-term anti-hypertensive treatments.

Henrik Bettermann
Dirk Cysarz
Hans Christoph Kümmell
Department of Clinical Research
Gemeinschaftskrankenhaus
58313 Herdecke, Germany
References
  1. Singh JP, Larson MG, Tsuji H, Evans JC, Odonnell CJ, Levy D. Reduced heart rate variability and new-onset hypertension - Insights into pathogenesis of hypertension: the Framingham Heart Study. Hypertension. 1998; 32: 293-297
  2. Parati G, Frattola A, Omboni S, Mancia G, Di Rienzo M. Analysis of heart rate and blood pressure variability in the assessment of autonomic regulation in arterial hypertension. Clin Sci. (Colch) 1996; 91 Supl.: 129-132
  3. Kario K, Motai K, Mitsuhashi T, Suzuki T, Nakagawa Y, Ikeda U, Matsuo T, Nakayama T, Shimada K. Autonomic nervous system dysfunction in elderly hypertensive patients with abnormal diurnal blood pressure variation - Relation to silent cerebrovascular disease. Hypertension. 1997; 30: 1504-1510
  4. Bettermann H, Van Leeuwen P. Evidence of phase transitions in heart period dynamics. Biol Cybern. 1998; 78: 63-70
  5. Kleiger RE, Bigger JT, Bosner MS, Chung MK, Cook JR, Rolnitzky LM, Steinman R, Fleiss JL. Stability over time of variables measuring heart rate variability in normal subjects. Am J Cardiol. 1991; 68: 626-630
  6. Hohnloser SH, Klingenheben T, Zabel M, Schroder F, Just H. Intraindividual Reproducibility of Heart Rate Variability. PACE. 1992; 15: 2211-2214


Response:

We thank Bettermann et al for their comments and their interest in our work[1]. We were unable to assess the diurnal variation of heart rate variability (HRV) because our study was based on daytime ambulatory ECG recordings. It is reassuring, however, to know that the mean values of the LF, HF and LF/HF ratio (after log transformation) from our population-based study (931 men and 1111 women) was nearly identical to values in their study of 25 patients. This was despite the intermediate duration (2 hour) of our recordings compared with their 24-hour recordings.

Bettermann et al raise an interesting point concerning the change in HRV variables over time. Unfortunately, we did not have follow-up HRV data to include in our report. Such data are being acquired now and will allow us to address longitudinal changes in HRV in future studies. We agree that it would be interesting to analyze the time course of 24-hour blood pressure levels and nonlinear measures of HRV.

Power spectral measures of HRV are characterized by large inter- and intra-subject variations [2], which probably reflect the dynamics of physiological control mechanisms over time and even during steady-state conditions [2, 3]. This complicates the extrapolation of results from a population study to an individual patient in clinical practice. As mentioned in our paper, in theory, HRV, as a surrogate measure for autonomic tone, may aid in the management of hypertension [4] by guiding the selection of an appropriate drug. An extension of this concept by Bettermann et al, suggesting the use of longitudinal/single case studies evaluating changes in the autonomic profile of an individual patient over time and the effects of antihypertensive therapy on the HRV parameters, deserves evaluation. This is reinforced by recent data suggesting that postural changes in spectral profiles can be recognized and forecast within individuals [4].

Jagmeet Singh, MD, DPhil
National Heart, Lung, and Blood Institute’s
Framingham Heart Study
Framingham, Massachusetts


Martin Larson, DSc
Boston University School of Medicine
Boston, Massachusetts


Daniel Levy, MD
Massachusetts General Hospital Harvard Medical School
Boston, Massachusetts
References
  1. Singh JP, Larson MG, Tsuji H, Evans JC, O’Donnell CJ, Levy D. Reduced heart rate variability and new-onset hypertension: insights into pathogenesis of hypertension: the Framingham Heart Study. Hypertension. 1998;32:293–297.
  2. Task force of the European Society of Cardiology and the North American Society of Pacing and Electrophysiology. Heart rate variability standards of measurement, physiological interpretation, and clinical use. Circulation. 1996;93:1043–1065.
  3. Malliani A, Pagani M, Furlan R, Guzzetti S, Lucini D, Montana N, Cerutti S, Mela GS. Individual recognition by heart rate variability of two different autonomic profiles related to posture. Circulation. 1997;96:4143–4145.
  4. Salo TM, Viikari JS, Antila KJ, Voipio-Pulkki LM, Jalonen JO, Valimaki IA. Antihypertensive treatment and heart rate variability in diabetic patients: role of cardiac autonomic neuropathy. J Auton Nerv Syst. 1996;60:61–70.

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Created 04 Apr 2005, last modified 17 Jun 2005 07:39 (GMT+2)
Date of request 23 Aug 2019


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