Aging and spectral characteristics of the nonharmonic component of 24-h heart rate variability

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Aging and spectral characteristics of the nonharmonic component of 24-h heart rate variability

Seiichiro Sakata, Junichiro Hayano, Seiji Mukai, Akiyoshi Okada, and Takao Fujinami

Third Department of Internal Medicine, Nagoya City University Medical School, Nagoya 467-8601, Japan

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

To examine whether heart rate variability (HRV) during daily life shows power law behavior independently of age and interindividualdifference in the total power, log-log scaled coarse-grainingspectra of the nonharmonic component of 24-h HRV were studiedin 62 healthy men (age 21-79 yr). The spectra declined with increasingfrequency in all subjects, but they appeared as broken lines slightlybending downward, particularly in young subjects with a largetotal power. Regression of the spectrum by a broken line witha single break point revealed that the spectral exponent ( $beta$ ) wasgreater in the region below than above the break point (1.63 ±0.23 vs. 0.96 ± 0.21, P < 0.001). The break point frequency increasedwith age (r = 0.51, P < 0.001) and $beta$ correlated with age negativelybelow the break point (r = 0.39) and positively above the breakpoint (r = 0.70). The contribution to interindividual differencein total power was greater from the differences in the power spectraldensity at frequencies closer to both ends of the frequency axisand minimal from that at $-$ 3.25 log(Hz), suggesting hingelike movementof the spectral shape at this frequency with the difference intotal power. These characteristics of the 24-h HRV spectrum weresimulated by an artificial signal generated by adding two noiseswith different $beta$ values. Given that the power law assumption isfundamental to the analysis of dynamics through the log-log scaledspectrum, our observations are substantial for physiological andclinical studies of the heartbeat dynamic during daily life andsuggest that the nonharmonic component of HRV in normal subjectsduring daily life may include at least two 1/f fluctuations that differ in dynamics and agedependency.

power spectral analysis; fractal; nonlinear; complex system; ambulatory electrocardiogram

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

THE POWER SPECTRUM of the nonharmonic component of heart rate variability (HRV), when plotted as the logarithm of power spectraldensity (PSD) on the logarithm of frequency (log-log scaled spectrum),has been reported to show a linear decay with increasing frequency(8, 15). This phenomenon is referred to as power law behaviorand known as a feature of 1/f fluctuation. When power law behavior is observed in the outputsignal from a dynamic system, the complexity of the system canbe estimated by the steepness of the slope of the log-log scaledspectrum, i.e., spectral exponent ( $beta$ ): the steeper the slope,the lesser the complexity of the system (11). An earlier observationshowed that the spectral exponent of short-term (5-min) HRV increasedwith age, suggesting an age-related loss of complexity in theheartbeat regulation system (10). Also, an increase in the spectralexponent of HRV in 24-h ambulatory recording has been reportedto be an increased risk for mortality in the elderly population(6). Because HRV is thought to be an output signal from thecomplex information network of the cardiovascular regulation system(7), analysis of the HRV dynamics and their changes with agingwould provide useful information about the characteristics ofthe cardiovascular regulation system and itsaging.

However, the appearance of the log-log scaled spectrum of 24-h HRV during daily activities is not necessarily straightly linearbut similar to a broken line that bends slightly downward in healthysubjects, particularly in young subjects or those with a largetotal power of HRV. The HRV during daily life could include theresponses to various daily stimuli and activities as well as thefluctuations originating from the cardiovascular regulation system.Thus they could be the mixture of multiple fluctuations that differfrom each other in the dynamics and in the responses to variousfactors, such asaging.

In the present study we examined whether the conventional power law assumption applies to the heartbeat dynamics in normalsubjects during daily life, particularly when the effects of agingand interindividual difference in the total power are considered.Our initial questions in this study were as follows: 1) Are thespectral exponents of the nonharmonic component of HRV and theeffects of aging on the spectral exponent invariant throughoutthe frequency range of the 24-h spectrum? 2) Is the total powerof the 24-h HRV contributed by PSD at each frequency as a linearfunction of the frequency or as a nonlinear function with certainfrequency specificity; in other words, is the fundamental shapeof log-log scaled power spectrum of 24-h HRV always straightlylinear independently of age and total power? Given that the powerlaw assumption is fundamental to the analysis of dynamics throughthe log-log scaled spectrum, the results of this study would besubstantial for the physiological and clinical investigationsof heartbeat dynamics during dailylife.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Subjects. We studied 62 healthy men [age 21-79 yr, 50 ± 18 (SD) yr] who had been rigorously screened for latent disorders through medicalhistory, physical examinations, blood cell count, blood biochemistry,and electrocardiogram (ECG). Elderly subjects ( $>=$ 65 yr old) hadalso been screened for occult cardiovascular disease by exercisetolerance test. None was taking any medications for >2 wk precedingthe study. Seven (11%) subjects were current smokers. AmbulatoryECG were recorded continuously for 48 h (days 1 and 2) in 43 subjectsand for 24 h (day 1) in 19 subjects. The ambulatory ECG data fromday 1 were used for the main analysis of this study, and thosefrom day 2 were used to examine reproducibility of measures. TheECG in all subjects were in sinus rhythm. The maximum number ofectopic beats observed in these recordings was 110/24 h. Noneof them showed significant ST segment changes, atrioventricularblock, or bundle branch block. The protocol of this study wasin accordance with the Ethical Guidelines of Nagoya City UniversityMedical School, and all subjects gave their written informedconsent.

Data collection. The ambulatory ECG was recorded on FM tape (1 tape/24 h) with a portable tape recorder (model DMC-3253, Nihon Kohden, Tokyo,Japan), with each subject performing usual daily activities. Alltapes were played back with a Holter ECG scanner (model DMC-4100,Nihon Kohden) at a rate 240 times faster than real time and digitizedto 12-bit data at a sampling frequency of 128 Hz. The effect ofwow flutter was canceled by a crystal-oscillator signal simultaneouslyrecorded on a timing track. All QRS complexes in each tape weredetected and labeled automatically. The results of the automaticanalysis were reviewed, and any errors in R wave detection andQRS labeling were edited manually. The 24-h sequence of the labelof each QRS complex with the preceding R-R interval was transferredto a computer workstation (model S-7/7000U, Fujitsu, Tokyo,Japan).

Time series analysis. The R-R interval time series was defined as the 24-h sequence of the intervals between two successive R waves of sinus rhythm.To avoid the adverse effects of remaining errors in the detectionof supraventricular ectopic beats on the analysis, all abruptlarge changes in the R-R interval (>20% of moving average of R-Rintervals) were reviewed interactively until all errors were corrected.The R-R interval sequence was interpolated by a linear step function;i.e., the value of the function between two successive R waveswas assumed to be constant at a value equal to the R-R interval,and the value during a gap resulting from artifacts, noises, andexclusions of ectopic beats was considered equal to the R-R intervalsubsequent to the gap. The length of interpolated gaps relativeto the total length of the recording was 0.024 ± 0.026% (median0.016%, range 0.001-0.127%), which showed no correlation withage (r = 0.02).

To evaluate exclusively the nonharmonic components of 24-h HRV without the harmonic components, we used coarse-graining spectralanalysis (CGSA) (21). The interpolated time series were submittedto the CGSA algorithm of Time Series Statistical Analysis System(version 3.01.01b) developed by Yamamoto and Hughson (21). Theprinciple and algorithm of this method have been described elsewherein detail (21, 22). Briefly, the extraction of nonharmoniccomponents was achieved by the cross-correlations between theoriginal and the rescaled data; the data were rescaled twice withdifferent methods: once by sampling every second data point andonce by sampling every data point twice. The power spectrum wasobtained as the geometric mean of two cross spectra between theoriginal and two sets of the rescaled data thus obtained. Onlynonharmonic components were preserved after the cross-correlationsbecause of their property known as "self-similarity" or "scaleinvariance," whereas the harmonic components were lost. The magnitudeof fluctuation at each frequency was expressed as PSD. Namely,power was multiplied by the number of spectral data points anddivided by the width of the frequency band for each datapoint.

Analysis of spectral characteristics. The characteristics of the nonharmonic component were evaluated by plotting log(PSD) vs. log(frequency). The spectral exponentwas defined as the value that satisfies the following equation

<IT>P</IT> = <IT>C</IT> ⋅ (1/<IT>f</IT><SUP>&bgr;</SUP>)

where P is PSD, f is frequency, $beta$ is the spectral exponent, and C is a proportionality constant (15). By taking the logarithmsof both sides of the equation, this equation can be rewrittenas

log <IT>P</IT> = log <IT>C</IT> − &bgr; ⋅ log <IT>f</IT>

which shows that $beta$ can be estimated by linear regression analysis of log(PSD) on log(frequency). The interpolated 24-h R-Rinterval function was resampled equidistantly so that 2¹⁷ data points were obtained. In the rescaling process of CGSA,every second data point was sampled, resulting in a 2¹⁶-point symmetrical power spectrum. We used the method of Saulet al. (15) to avoid the effects of uneven density of spectraldata points along the log(frequency) axis. Briefly, the log(frequency)axis was divided into equally spaced bins. Log(PSD) was averagedover each bin. If bins included no data point, particularly inthe lower-frequency range, the average values for such bins wereobtained byinterpolation.

Two different bin widths were used according to the purposes of analysis. A bin width of 0.00882 log(Hz) (512 bins for theentire frequency band of the 24-h log-log scaled power spectrum)was used for the regression analysis of log(PSD) on log(frequency),by which we examined whether the spectral exponents and the effectof aging on the spectral exponent are identical throughout thespectral region (question 1). A bin width of 0.1 log(Hz) (10 bins/decade)was used for the correlation and linear regression analysis ofthe relationships between the log(total power) and log(PSD) atdifferent frequencies, by which we examine whether the interindividualdifference in total power is contributed by PSD at each frequencyas a linear function of frequency or as a nonlinear function withcertain frequency specificity (question 2). Because the estimatedPSD for the lowest frequency was unreliable, datum of the firstbin was excluded from regression analysis in bothanalyses.

To examine whether the log-log scaled spectrum is considered as a straight line or as a broken line bending to a consistentdirection, each spectrum in the frequency range from 6.1 × 10⁵ to 4.0 × 10² Hz [ $-$ 4.2 to $-$ 1.4 log(Hz)] was regressed by a broken line thatwas composed of two least-square straight lines connecting ata break point (Fig. 1). The broken line best fitting the spectrawas determined as follows. All possible break points {( f_B,P_B)| $-$ 4.2 log(Hz) $<=$ f_B $<=$ $-$ 1.4 log(Hz), 2 log(ms²/Hz) $<=$ P_B $<=$ 9 log(ms²/Hz)} were examined with a resolution of 0.01 log(Hz) for f_B and0.01 log(ms²/Hz) for P_B, where f_B is frequency and P_B is PSD of the breakpoint. For each possible ( f_B,P_B), two least-square regressionlines crossing at ( f_B,P_B) were determined for the spectral regionsabove and below f_B, respectively, and the residual mean squaresfor the least-square regression lines were calculated for thecorresponding spectral regions. The best broken line was determinedas the broken line that minimized the sum of the two residualmean squares weighted by the numbers of data points regressed,i.e., the number of data points above and below f_B, respectively.Two spectral exponents ( $beta$ _a and $beta$ _b) were determined as the slopesof two least-square regression lines for the spectral regionsabove and below f_B, respectively, in each subject.

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Fig. 1. Log-log scaled power spectrum of nonharmonic component obtained by coarse-graining spectral analysis of 24-h heart rate variability (HRV) in a representative healthy young subject (26-yr-old man). Spectrum was regressed by a broken line with a break point [(f_B,P_B), where f_B is frequency of break point and P_B is power spectral density (PSD) of break point]. When f_B was set at $-$ 3.17 log(Hz) (6.8 × 10⁴ Hz), regression line yielded minimum value for sum of residual mean squares weighted by number of data points above and below f_B. Estimated spectral exponent for frequency region above f_B ( $beta$ _a) was 0.67, and that for region below f_B ( $beta$ _b) was 1.98.

Statistical analysis. The Statistical Analysis System program package (SAS Institute, Cary, NC) was used for statistical evaluations. The differencein the spectral exponent between two different frequency regionswas evaluated by paired t-test. The effects of aging on powerspectral variables were assessed by Pearson's correlation coefficientsand also by ANOVA after subjects were divided into three age groups:21-39 yr (group Y), 40-59 yr (group M), and 60-79 yr (group O).Bonferroni's test was used for post hoc multiple comparisons.To visualize changes in the shape of the log-log scaled spectrumwith age, the ensemble averages of log-log scaled spectra werecalculated for the three age groups. The effect of log(total power)on log(PSD) for each bin was assessed by Pearson's correlationcoefficients and linear regression analysis by means of SAS correlationand regression procedures. Reproducibility of the spectral characteristics(break point and spectral exponents) was evaluated through intraclasscorrelation coefficients for one-way random-effects ANOVA, withdefining subjects as the random factor (19) and the coefficientof repeatability of Bland and Altman (2). Values are means± SD. P < 0.05 was considered statisticallysignificant.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Characteristics of the log-log scaled power spectrum. The log-log scaled spectra of the nonharmonic component of 24-h HRV obtained by CGSA showed a monotonous decline with increasingfrequency in all subjects. Closer observations, however, revealedthat the spectra appeared as a broken line bending downward about $-$ 3 log(Hz) in most subjects, particularly in young subjects andin subjects with a large total power (Fig. 1). The regressionanalysis by a broken line with a single break point revealed thata break point existed at f_B of $-$ 2.89 ± 0.16 log(Hz) and that thespectral exponents above f_B ( $beta$ _a; 0.96 ± 0.21) were significantlysmaller than the spectral exponents below f_B ( $beta$ _b; 1.63 ± 0.23,P < 0.001). As shown in Table 1, the difference between $beta$ _a and $beta$ _b was significant, even when analyzed separately in the groupsdivided by age. This indicates that the log-log scaled spectrumof the nonharmonic component of 24-h HRV showed a significantdownward bending.

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Table 1. Differences in break-point frequency and in spectral exponents for frequency regions above and below break-point frequency among three age groups

Effects of aging. The ensemble averages of the log-log scaled spectrum for the three age groups are presented in Fig. 2. As shown in Fig. 2and Table 1, f_B was higher in group O than in group Y (P < 0.001).Interestingly, while $beta$ _a was greater in group O than in group M,which was in turn greater than in group Y (P < 0.001), $beta$ _b wassmaller in group O than in group Y (P = 0.03), although the differencein $beta$ _b was not discernible in Fig. 2. The relationships betweenage and spectral parameters in each subject are presented in Fig.3, which showed that f_B correlated positively with age (r = 0.51,P < 0.001). Although $beta$ _a correlated positively with age (r = 0.70,P <0.001), $beta$ _b correlated negatively (r = $-$ 0.39, P = 0.001); consequently,the difference between them ( $beta$ _b $-$ $beta$ _a), which reflected the degreeof bending of the spectrum, decreased with age (r = $-$ 0.60, P <0.001).

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Fig. 2. Averaged log-log scaled power spectra of nonharmonic component of 24-h HRV for 21- to 39- (group Y, n = 22), 40- to 59 (group M, n = 19)- and 60- to 79-yr-old men (group O, n = 21). Each data point represents ensemble average of log(PSD) over each of 33 equally spaced bins (10 bins/decade).

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Fig. 3. Effects of aging on spectral parameters of nonharmonic component of 24-h HRV. f_B, Break-point frequency; $beta$ _a, spectral exponent for frequency region above f_B; $beta$ _b, spectral exponent for frequency region below f_B; $beta$ _b $-$ $beta$ _a, difference between the 2 spectral exponents, an index reflecting degree of bending of log-log scaled spectrum.

Effects of interindividual difference in total power. The total power in all subjects ranged from 8.37 to 11.08 log(ms²) [10.08 ± 0.59 log(ms²) (SD)] and correlated negatively with age (r = $-$ 0.52, P < 0.001).Correlation and linear regression analysis of the relationshipsbetween the log(total power) and log(PSD) at different frequencybins showed significant positive correlations for all frequencybins from $-$ 4 to $-$ 1 log(Hz) (P < 0.001). Interestingly, however,the correlation coefficients and linear regression coefficientsshowed distributions similar to the letter "V," with a clear dipat $-$ 3.25 log(Hz) (Fig. 4). Thus the interindividual differencein total power was contributed more strongly by the differencesin PSD at frequencies closer to both ends of the frequency axisand minimally at $-$ 3.25 log(Hz), suggesting that the spectrum showshingelike movement at this frequency with the interindividualdifference in total power.

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Fig. 4. Relationships between total power and PSD of log-log scaled power spectra of nonharmonic component of 24-h HRV. Log(PSD) was averaged over each of 33 equally spaced bins (10 bins/decade). A: correlation coefficients between log(PSD) and log(total power). B: linear regression coefficient for log(PSD) regressed on log(total power). Both coefficients are presented as function of log(frequency) bin.

Reproducibility. Among 43 subjects subjected to ECG recordings for 2 consecutive days, the spectral parameters showed good within-individualreproducibility: f_B, $beta$ _a, and $beta$ _b for day 1 were $-$ 2.89 ± 0.16 log(Hz),0.95 ± 0.22, and 1.63 ± 0.24, respectively, and those for day2 were $-$ 2.90 ± 0.15log(Hz), 0.96 ± 0.21, and 1.60 ± 0.24, respectively.The intraclass correlations (0.44, 0.92, and 0.62 for f_B, $beta$ _a,and $beta$ _b, respectively, P < 0.001 for all) indicated good within-subjectreproducibility over 2 consecutive days for $beta$ _a and $beta$ _b. The intraclasscorrelation for f_B was relatively low because of small interindividualvariance; however, the coefficient of repeatablity of Bland andAltman (2) for f_B was acceptable [0.33 log(Hz)].

Simulation study. Our observations showed that the log-log scaled spectrum of 24-h HRV during daily life appeared as a broken line bending downwardand that the degree of the bending ( $beta$ _b $-$ $beta$ _a) decreased with aging.To examine whether these characteristics of the power spectraare explained as the results of a combination of two 1/f fluctuations differing in dynamics and its age dependency, weperformed simulation studies (Fig. 5).

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Fig. 5. Simulation study of nonharmonic component of 24-h HRV during daily life observed in group Y (A-F) and group O (G-L). Time series of fractal noises (A and G) were generated through inverse fast Fourier transformation of colored Fourier series, which were obtained by 2¹⁸-point fast Fourier transformation of 2 independent 86,400-point time series of Gaussian white noise. Fractal noise in A and G had a spectral exponent ( $beta$ ) of 0.7 and 1.2 and total power of 3,114 and 1,463 ms², respectively, and their log-log scaled power spectra are shown in B and H. Time series of square-wave noise (C and I) simulated adaptive responses of R-R interval during daily life; they had a total power of 28,355 and 7,423 ms², respectively, and showed power law spectra with a spectral exponent of 2.0 (D and J). Time series in E and K were generated by adding 2 time series [(A and C) and (G and K)] in time domain, respectively. F and L: log-log scaled spectra of E and K; f_B, $beta$ _a, and $beta$ _b of spectrum in F were $-$ 2.96 log(Hz), 0.85, and 1.84, respectively, and those in L were $-$ 2.80 log(Hz), 1.24, and 1.62, respectively.

We generated a combined noise signal by adding fractal noise to square-wave noise simulating adaptive responses of the R-Rinterval during daily life. As shown in Fig. 5F, a broken-linelog-log scaled spectrum similar to those observed in group Y wasobtained from the combined noise signal composed of fractal noise( $beta$ = 0.7, total power = 3,114 ms²; Fig. 5A) and square-wave noise (total power = 28,355 ms²; Fig. 5C). Additionally, as shown in Fig. 5L, the effects ofaging observed in the characteristics of the log-log scaled spectrumin group O were simulated by an increase in $beta$ (1.2) and a decreasein total power (1,463 ms²) of the fractal noise (Fig. 5G) and a decrease in total power(7,423 ms²) of the square-wave noise (Fig. 5I).

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

In healthy men we studied the power law behavior of the nonharmonic component in 24-h HRV during daily life and the effectsof aging and total power on the behavior. The major findings ofthis study are as follows: 1) the log-log scaled spectrum of thenonharmonic component of the 24-h HRV was considered as a brokenline bending downward at around $-$ 2.9 log(Hz) (1.3 × 10³ Hz), and the shape of the spectrum was stable over 2 consecutivedays within each individual, 2) the spectral exponents above andbelow the break-point frequency changed to opposite directionswith aging so that the degree of bending decreased with aging,whereas the break-point frequency itself increased with age by0.27 log(Hz) per decade, 3) the shape of the spectrum was affectedalso by interindividual difference in total power and showed hingelikemovement at a break point of $-$ 3.25log(Hz), and 4) the spectralcharacteristics and their age-related changes were simulated bythe model composed of two different 1/f fluctuations. These findings are inconsistent with the conventionalpower law assumption that ascribes the nonharmonic component of24-h HRV to a single 1/f fluctuation, but, conversely, they support the hypothesis that24-h HRV may be composed of at least two 1/f fluctuations differing from each other in dynamics and agedependency.

Analysis of the spectral exponent has been used as a method for estimating the complexity of HRV. Kobayashi and Musha (8)studied the log-log scaled power spectrum of 10-h HRV in an awakenormal young man during bed rest. They reported that in a frequencyrange of 1.0 × 10⁴-2.0 × 10² Hz, the shape of the spectrum was straightly linear with a spectralexponent near 1. Their observation was confirmed by Saul et al.(15). Lipsitz et al. (10) compared the spectral exponent of5-min HRV between 12 healthy young (18-35 yr) and 10 healthy older(71-94 yr) subjects and reported that the spectral exponent wasgreater in the older subjects than in the young subjects. Theysuggested that aging may be associated with a loss of dimensionalitydue to reduced autonomicresponsiveness.

Analysis of the spectral exponent of HRV may also have clinical significance. Bigger et al. (1) reported that the spectralexponent of 24-h HRV in a frequency range of 4.0 × 10⁴-1.0 × 10² Hz was increased in patients after acute myocardial infarction,and the degree of the increase was an independent predictor fordeath. Butler et al. (3) reported that the spectral exponentof a 256-beat HRV was greater in patients with heart failure thanin healthy men. Recently, Huikuri et al. (6), adopting thesame frequency range used by Bigger et al. for calculating thespectral exponent of 24-h HRV, reported that a spectral exponent>1.5 was an independent predictor for cardiac and cerebrovasculardeath in a randomly selected elderly population. These earlierstudies were based on the assumption that the nonharmonic componentof HRV is ascribed to a single 1/f fluctuation; however, the validity of this simple power law assumptionhas not been examined for 24-hHRV.

Estimation of the characteristics of the nonharmonic component, such as the spectral exponent, may be confounded by concomitantlyexisting harmonic components at various frequencies (12, 13,16, 18). Contamination of the power of harmonic componentscould result in a spurious bending of the log-log scaled spectrum.Because the power of high- and low-frequency components, well-knownharmonic components of HRV, decreases with aging (4, 9,17), the contamination of power of these components may alsoresult in an age-related increase in the spectral exponent ofthe frequency band including these components. To resolve theseproblems, we adopted CGSA, which extracted the nonharmonic componentfrom the harmonic components (21). Using CGSA, we observed thatthe log-log scaled spectrum of the nonharmonic component of 24-hHRV was a broken line bending downward, although the result wasbasically the same when we used conventional fast Fourier transformationin the analysis (data notshown).

To examine whether the spectra are straightly linear or bending, we performed regression analysis by a broken line with asingle break point. The statistical requirement to indicate thata spectrum is bending, in general, is a significant reductionin the residual variance with broken-line regression comparedwith simple linear regression. We determined the broken line,inasmuch as that minimized the residual variance, and our methodincluded straight-line regressions as a part of the solution;the difference in the residual variance between the broken lineand the straight line did not reach a significant level (datanot shown). Nevertheless, our observation of the statisticallysignificant difference in the spectral exponent between the regionsabove and below the break point ( $beta$ _a > $beta$ _b) seems enough to indicatethat the spectra were significantly bending downward; if the spectrawere straightly linear, the null hypothesis of $beta$ _a = $beta$ _b would notbe rejectedstatistically.

Two hypotheses may be considered for the mechanisms of the broken-line spectrum of 24-h HRV. One is that 24-h HRV does nothave characteristics of 1/f fluctuation. This possibility seems unlikely, however, becausedownward bending of the log-log scaled spectrum of 24-h HRV wasobserved, even with CGSA, in which only nonharmonic componentswith scale-invariant properties were preserved. The other andmore likely hypothesis is that 24-h HRV is composed of multiple1/f fluctuations with different spectralcharacteristics.

It seems possible that nonharmonic components of 24-h HRV during daily life have multiple origins with different dynamics.The cardiovascular regulation system is thought to be a multiplexinformation network with many strata, i.e., molecular, genomic,cellular, organic, and whole body levels (7). Given that HRVis an output signal from such a complex system, it could showfractal noiselike fluctuation with a spectral exponent close to1. On the other hand, the cardiovascular regulation system needsto adapt to the changes in circulatory demands caused by internaland external stimuli, such as sleep-wakefulness rhythm, food intake,physical and psychological activities, and social and environmentalconditions. One may speculate that adaptive responses to thesestimuli could result in a high degree of long-range temporal correlationin heart rate dynamics, which could result in nonharmonic fluctuationwith a spectral exponent near 2. Indeed, a broken-line spectrumsimilar to that of actual 24-h HRV was simulated by the artificialnoise generated by adding time series of fractal noise and timeseries simulating adaptive responses (Fig. 5, A-F).

In this study we observed that not only the spectral exponent but also its age-related changes were different between frequencyregions. Lipsitz et al. (10), who found an age-related increasein the spectral exponent of 5-min HRV, suggested that their findingsmay reflect a loss of dimensionality because of reduced autonomicresponsiveness with age. Our result indicates that $beta$ _a increaseswith age, whereas $beta$ _b decreases with age. Thus the concept of lossof dimensionality/complexity with aging may explain only a partof the age-related changes in 24-h heartbeat dynamics during dailylife.

Although the mechanisms of the age-related decrease in $beta$ _b cannot be deduced from the present study, this phenomenon indicatesan age-related decrease in the degree of long-range temporal correlationin the lower-frequency region. One may speculate that age-relatedchanges in the adaptive responses, including an indistinct day-nightcontrast and decreased autonomic responses to postural changesand exercise in the elderly (10, 17, 20, 23), might beinvolved in this phenomenon. We observed that the age-relateddecrease in $beta$ _b was simulated by the combination of decreased magnitudeof the adaptive responses as well as increased spectral exponentand decreased power of the fractal noise (Fig. 5, G-L).

The mechanisms for the age-related increase in f_B may be more complex. In the simulation model we proposed, the position ofthe break point could be a function of four independent variables,i.e., the spectral exponents and the total powers of the two setsof time series that were added. Although the detailed mechanismis unknown, Fig. 2 and simulation data suggest that an age-relatedincrease in the spectral exponent and/or a decrease in the totalpower in the fractal noise-like fluctuation may primarily contributeto the age-related increase in f_B.

Limitations. Although we observed that aging affected the spectral characteristics of the nonharmonic component of 24-h HRV, we studiedonly men. Because a gender difference in HRV has been reported(9, 14), our findings may not be applicable to women. Also,all subjects in this study were rigorously screened for medicalproblems, but the exercise tolerance test was performed only inelderly ( $>=$ 65-yr-old) subjects. We cannot exclude the possibleeffects of occult cardiovascular diseases in our subjects. Additionally,our subjects included seven smokers. Smoking has been reportedto affect HRV through acute and chronic impairment of autonomicfunction (5). Comparisons of spectral characteristics betweenthe 7 smokers and 55 nonsmokers showed no significant difference,even when the effects of age were taken into account (data notshown); however, the statistical power seems insufficient to drawany conclusions. Studies in larger populations arenecessary.

Perspectives

We found that a simple power law assumption does not apply to the heartbeat dynamics in normal subjects during daily life.The log-log scaled power spectrum of 24-h HRV during daily lifewas not straightly linear but similar to a broken line bendingdownward. Furthermore, the spectral exponents above and belowthe break-point frequency changed to opposite directions withaging. These observations and the results of the simulation suggestthat the nonharmonic component of 24-h HRV in normal subjectsmay include at least two 1/f fluctuations that differ in dynamics and age dependency. Thepotential values of our findings are substantial, consideringthe growing interests in the clinical values of the nonharmoniccomponent in HRV. Our study raises concerns about the interpretationof earlier observations demonstrating an increased spectral exponentin patients with heart failure (3), high-risk patients afteracute myocardial infarction (1), and an elderly populationwith an increased risk for cardiovascular death (6). Thesestudies differed not only in the method of spectral analysis butalso in the frequency band analyzed, both of which could affectthe obtained spectral exponent. Nonharmonic components of HRVobserved in different frequency regions could differ from eachother not only in mathematical properties but also in physiologicalorigins.

	ACKNOWLEDGEMENTS

This study was supported in part by Research Grants for Aging and Health (1996, 1997, and 1998) from the Ministry of Healthand Welfare of Japan (to J.Hayano).

	FOOTNOTES

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.§1734 solely to indicate thisfact.

Address for reprint requests and other correspondence: S. Sakata, Third Dept. of Internal Medicine, Nagoya City University Medical School, 1 Kawasumi, Mizuho-cho Mizuho-ku, Nagoya 467-8601, Japan (E-mail: sakata{at}med.nagoya-cu.ac.jp).

Received 22 May 1998; accepted in final form 9 February 1999.

	REFERENCES

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

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