Mechanisms of respiratory sinus arrhythmia in patients with mild heart failure

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Mechanisms of respiratory sinus arrhythmia in patients with mild heart failure

Magdi El-Omar, Attila Kardos, and Barbara Casadei

University Department of Cardiovascular Medicine, John Radcliffe Hospital, Oxford OX3 9DU, United Kingdom

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

The high-frequency (HF) component of the heart rate variability (HRV) is regarded as an index of cardiac vagal responsiveness.However, when vagal tone is decreased, nonneural mechanisms couldaccount for a significant proportion of the HF component. To testthis hypothesis, we examined the HRV spectral power in 20 patientswith mild chronic heart failure (CHF) and 11 controls before andduring ganglion blockade with trimethaphan camsylate (3-6 mg/miniv). A small HF component was still present during ganglion blockade,and its amplitude did not differ between CHF patients and controls.The average contribution of nonneural oscillations to the HF componentwas 15% (range 1-77%) in patients with CHF and 3% (range 0.7-30%)in healthy controls (P < 0.005). During controlled breathing at0.16 Hz, however, it decreased to 1% (range 0.2-13%) in healthycontrols and 5% (range 1-44%) in CHF patients. Our results indicatethat the HF component can significantly overestimate cardiac vagalresponsiveness in patients with mild CHF. This bias is improvedby controlled breathing, since this maneuver increases the vagalcontribution to HF without affecting its nonneuralcomponent.

autonomic nervous system; vagus nerve; stretch

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

SPECTRAL ANALYSIS of heart rate (HR) variability (HRV) is a widely accepted method for evaluating the cardiac autonomic modulationin physiological and pathological conditions (27). In particular,it is well established that in the supine position and at a breathingfrequency >0.15 Hz the high-frequency (HF) component of the HRVpower spectrum (i.e., respiratory sinus arrhythmia) provides ameasure of "cardiac parasympathetic responsiveness," since itreflects the modulation of vagal cardiac efferent activity bybreathing and the sinoatrial response to that modulation (23,24). However, a small HF component has been seen in the transplanteddenervated human heart (2, 3, 18, 25) and in healthysubjects after autonomic blockade (7, 23), suggesting thatbreathing-related changes in atrial transmural pressure (6,21) or in the direction of the cardiac axis (17) may be responsiblefor at least part of the HRV in the HF range. In young healthysubjects, the contribution of nonneural mechanisms to the HF powerof the HRV increases from 1% at rest to 30% during exercise (7).This implies that, in the presence of vagal withdrawal, the HFcomponent may significantly overestimate cardiac parasympatheticresponsiveness, especially when its power is normalized for theR-R interval (RR) variance (16). These findings may be applicableto patients with chronic heart failure (CHF) who are known tohave impaired cardiac parasympathetic responsiveness and a reducedHRV (5, 9, 22). Experimental data, however, indicate thatright atrial stretch may suppress neural and nonneural componentsof respiratory sinus arrhythmia (14), suggesting that the relativecontribution to the HF power in patients with CHF may remain small,despite a reduction in HRV. To test this hypothesis, we calculatedthe relative contribution of autonomic and nonneural inputs tothe HF power of the HRV in patients with mild CHF and in healthyage-matchedcontrols.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Twenty patients with stable heart failure [New York Heart Association (NYHA) Class II, mean age 61 ± 2 yr] and 11 age-matchedhealthy subjects (mean age 58 ± 2 yr) volunteered for the study.The latter were in good health as indicated by medical history,physical examination, electrocardiogram (ECG), and arterial bloodpressure (BP) measurements. None of healthy subjects was takingany medication. All patients had been in stable CHF for $>=$ 3 mo.Fifteen patients had had a documented myocardial infarction, onehad chronic ischemic heart disease, and four had dilated cardiomyopathy.All patients were on angiotensin-converting enzyme inhibitorsand furosemide, and one was on a $beta$ -blocker. None was on digitalisor antiarrhythmic drugs. The average radionuclide left ventricularejection fraction was 25 ± 6% (mean ±SD).

Subjects with a history of atopic allergy, glaucoma, diabetes mellitus, atrial fibrillation, angina pectoris, or ECG evidenceof ischemia-limiting exercise, chronic obstructive pulmonary disease,and liver or renal failure wereexcluded.

Written consent was obtained after the subjects were informed of the procedures and risks involved in the study. The protocolwas approved by the Central Oxford Research EthicsCommittee.

Experimental design. Subjects were familiarized with the procedures and asked to avoid exercise and alcoholic or caffeinated drinks on the dayof the experiment. Patients with CHF were asked to stop theirmedications 12 h before the experiments. Studies were conductedin a quiet room at a controlled temperature of 22°C $>=$ 2 h aftera light meal. After 20 min of rest in the supine position, leadII of the ECG, a breathing signal (obtained by a thermistor andfrom changes in chest impedance), and ventilation ( $V$ I, in l/min;Harvard Apparatus) were recorded in each subject for 10 min duringspontaneous breathing and for 10 min during controlled breathingat 0.16 Hz. Minute averages of tidal volume (VT, ml) were obtainedby dividing $V$ I by the breathingfrequency.

The pulse interval response to baroreceptor stimulation was then tested (26). Briefly, three to five rapid intravenous injectionsof phenylephrine hydrochloride (Boots Pharmaceuticals) were givenat ~3-min intervals. The initial dose of 0.05 mg was adjustedto obtain an increase in systolic BP between 10 and 20 mmHg. Beat-by-beatBP recordings from the finger were obtained noninvasively by aninfrared photoplethysmograph (Finapres 2300 BP monitor, Ohmeda)while the RR was measured from the ECG. The reflex lengtheningof the RR in response to the phenylephrine-induced increase insystolic BP [i.e., the "baroreflex sensitivity," in ms/mmHg (26)]was taken as an index of reflex vagalactivity.

A 0.1% NaCl solution of the ganglion blocker trimethaphan camsylate (Arfonad, Roche) was then infused through an indwellingcannula in an antecubital vein. Beat-by-beat BP and ECG were monitoredcontinuously during the infusion. The initial infusion rate of3 mg/min was slowly increased until the RR response to phenylephrinewas abolished. During ganglion blockade (GB), the dose of phenylephrinewas adjusted to achieve a peak systolic BP similar to that obtainedat baseline. The use of GB to inhibit the neural inputs to theheart was preferred to the more conventional $beta$ -adrenergic andmuscarinic receptor antagonism for two reasons: 1) Unlike propranololor atropine, trimethaphan camsylate has a very short half-life.This meant that we could reverse possible adverse reactions veryrapidly and shorten considerably the period of observation afterthe experiment. 2) In our hands, high doses of atropine (i.e.,0.04 mg/kg) do not block the cardiac baroreceptor reflex in allsubjects.

When GB was reached, recordings of ECG, breathing frequency, and $V$ I during spontaneous and controlled breathing wererepeated.

Power spectral analysis of HRV. The ECG and breathing traces were digitized on-line by a 12-bit analog-to-digital converter (AT-Codas, Dataq Instruments)at a sampling rate of 600 Hz. The QRS complex was detected byidentifying the points of the low-pass-filtered first derivativeof the ECG signal, which exceeded an adaptive threshold. EachQRS complex and its triggering were verified by visual inspection.The breathing signal was sampled once every cardiac cycle. Timeseries of 256 consecutive RRs were used for spectral analysis.The autoregressive method, which was used to evaluate the powerspectral density of the RR series, has been described in detailpreviously (7). Briefly, a computer program first calculatedthe autoregressive coefficients using the Levinson-Durbin algorithm,and the model order was chosen by the Akaike information criterionstarting from a minimum order of 12. A spectral decompositionmethod was then applied to evaluate the power and the centralfrequency of the low-frequency (LF, 0.04-0.15 Hz) and high-frequency(HF, 0.15-0.50 Hz) components. The relative contribution of nonneuralmechanisms to the HF power was calculated as follows

<FR><NU>HF power after GB (ms<SUP><IT>2</IT></SUP>)</NU><DE>HF power before GB (ms<SUP><IT>2</IT></SUP>)</DE></FR><IT>×100</IT>

The very-low-frequency component (<0.04 Hz) was examined to assess the presence of narrow peaks indicating periodic breathing(19).

Cross-spectral analysis. To assess the relationship between respiration and HF oscillations, the cross spectrum and squared coherence function of theHRV and the breathing signal were calculated as described by Paganiet al. (20). Briefly, cross spectra were computed by fast Fouriertransformation, using a triangular window, on successive 50% overlappingseries of 64 RRs each. The squared coherence function was usedto evaluate the correlation between breathing and RR oscillationsat the same frequency. The value of this function is regardedas an analog of the squared correlation coefficient (r²) and ranges from 0 to1.

Statistical analysis. Values are means ± SE. ANOVA (SuperANOVA, Abacus Concepts) was used to compare the data within the protocol stages and betweenpatients with CHF and healthy subjects. To achieve a normal distributionand to normalize the variance of the data between stages, comparisonswere made using the square root of the power of the spectral components(i.e., their amplitude, in ms). Nonparametric statistic was employedto compare the contribution of nonneural mechanisms to the HFpower in CHF patients and controls. For this variable, data aregiven as geometric means. Statistical significance was acceptedat P < 0.05.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Two CHF patients and one control subject could not complete the study, since they developed a vasovagal reaction (bradycardia,nausea, sweating, and hypotension) shortly after the start ofthe infusion of trimethaphan camsylate. In two CHF patients andone control subject, the infusion of trimethaphan camsylate wasnot attempted, since the presence of frequent ectopic beats didnot permit a satisfactory analysis of the baseline ECGrecordings.

GB was usually obtained with an infusion rate of trimethaphan camsylate between 5 and 6 mg/min. At these doses, the increasein BP induced by the intravenous injection of phenylephrine wasassociated with a modest shortening of the RR in four subjects(Fig. 1) and no change in the others, with the exception of oneCHF patient, in whom a trimethaphan camsylate infusion of 6 mg/mindid not completely abolish the RR lengthening associated withphenylephrine. Since high doses of trimethaphan camsylate cancause respiratory depression, it was considered unsafe to increasethe rate of infusion further, and the data from this patient werenot included in the final analysis. During GB, all subjects experienceddry mouth and cycloplegia.

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Fig. 1. Beat-by-beat plot of systolic blood pressure (SBP) and R-R interval (RR) after intravenous phenylephrine before (A) and during (B) ganglionic blockade (GB) in a patient with heart failure. During GB, the increase in SBP secondary to intravenous phenylephrine is associated with shortening (rather than lengthening) of the RR.

Baseline measurements. The mean RR did not differ between CHF patients (n = 15) and age-matched control subjects (n = 9); however, the standard deviationof the RR was lower in CHF patients during spontaneous (P < 0.05)and controlled (P < 0.001) breathing (Table 1). Likewise, patientshad lower baroreflex sensitivity (4.34 ± 0.81 vs. 10.85 ± 2.31ms/mmHg, P < 0.05) and a reduced HF component (Table 1). Therewere no significant differences in $V$ I, VT (Table 2), or spontaneousbreathing frequency between control subjects and CHF patients(0.24 ± 0.02 and 0.28 ± 0.03 Hz, respectively). Controlled breathingat 0.16 Hz increased VT (Table 2) and the amplitude of the HFcomponent (Table 1) in both groups.

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Table 1. HRV before and during GB in patients with mild heart failure and age-matched controls

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Table 2. $V$ I and VT before and during GB

The amplitude of LF oscillations was significantly greater in healthy controls than in CHF patients during spontaneous breathing;this difference, however, was no longer present during controlledbreathing (Table 1). The center frequency of the LF componentdid not differ between the two groups (0.09 ± 0.01 vs. 0.10 ±0.01 Hz during spontaneous breathing and 0.09 ± 0.01 vs. 0.09± 0.01 Hz during controlledbreathing).

During spontaneous breathing, narrow peaks in the very-low-frequency range (centered at ~0.02 Hz) of the HRV power spectrumwere found in two CHF patients. Analysis of the respiration signalshowed that they were due to periodic breathing. This abnormalbreathing pattern was not seen during controlled breathing orGB (data notshown).

GB. GB caused a significant reduction in the mean RR and its standard deviation (Table 1) in both groups. The RR fluctuationsin the LF range were completely abolished by GB, but some degreeof respiratory sinus arrhythmia persisted in all subjects anddid not differ in magnitude between CHF patients and healthy controls(Table 1, Figs. 2 and 3). The correlation between RR fluctuationsin the HF range and the breathing signal was not affected by GB(coherence values of 0.82 ± 0.03 and 0.89 ± 0.02, respectively),indicating that a close relationship between these signals persistedafter neural control of sinoatrial node activity was abolished.

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Fig. 2. Tachogram (top) and power spectra of the HRV (middle) and breathing signal (bottom) before and during GB in a healthy subject. Whereas the low-frequency (LF) component (centered at ~0.1 Hz) is completely abolished by GB, the high-frequency (HF) component (0.15-0.50 Hz) is still present, albeit greatly reduced in amplitude (note the different scale in the y-axis).

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Fig. 3. Tachogram (top) and power spectra of the heart rate variability (HRV, middle) and breathing signal (bottom) before and during GB in a chronic heart failure (CHF) patient. Note the reduction in amplitude of HF oscillations before GB compared with Fig. 2. As in Fig. 2, nonneural HF oscillations are responsible for most of the residual HRV during GB, whereas LF oscillations are completely abolished.

There was no significant change in $V$ I or VT in either group with GB (Table 2). Breathing frequency was not affected by GBand did not differ between controls and CHF patients (0.24 ± 0.03and 0.27 ± 0.02 Hz, respectively). Controlled breathing significantlyincreased VT (Table 2) but did not affect the amplitude of theHF component after GB (Table 1).

Nonneural contribution to the HF power in CHF patients and in healthy controls. During spontaneous breathing, the relative contribution of nonneural mechanisms to the HF power was 3% in healthy controls(range 0.7-30%) and 15% in patients with CHF (range 1-76%, P <0.005 vs. controls). During controlled breathing, nonneural mechanismsaccounted for 1% of the HF power in healthy controls (range 0.2-13%)and 5% in CHF patients (range 1-44%, P < 0.005 vs. controls andP < 0.01 for the effect of controlled breathing at 0.16 Hz inboth groups; Fig. 4).

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Fig. 4. Controlled breathing at 0.16 Hz significantly decreased the contribution of nonneural mechanisms to the HF power of the HRV in healthy controls ( $open circle$ ) and patients with CHF (

). Average data are geometric means ± SD. *P < 0.005, CHF patients vs. controls. ^¶P < 0.01 vs. spontaneous breathing for both groups.

In all subjects, the natural logarithm of the nonneural contribution to HF was inversely related to the RR standard deviation(Fig. 5; adjusted r² = 0.53 during spontaneous breathing and 0.50 during controlledbreathing, P < 0.0001 for both).

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Fig. 5. Relationship between the RR standard deviation and the nonneural contribution to the HF component in healthy controls ( $open circle$ ) and patients with CHF (

) during spontaneous (A, r² = 0.53, P < 0.0001) and controlled breathing (B, r² = 0.50, P < 0.0001).

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Heart failure is associated with neurohumoral activation and a reduction in cardiac vagal responsiveness (10). Spectralanalysis of the HRV in these patients has shown that the absolutepower in the LF range decreases with the worsening of the diseaseand is often absent in NYHA Class IV patients (18). Likewise,the absolute power of the HF component has been found to be significantlydecreased from the early stages of the disease (8, 11). However,HR fluctuations in the HF range are present even in the most advancedstages of CHF, where they can account for most of the short-termHRV (11, 18). To explain this finding, it has been suggestedthat respiratory sinus arrhythmia in severe CHF might be entirelymediated by nonneural mechanisms (11, 18). Experiments inanesthetized pigs, however, have shown a reduction in neural andnonneural HR oscillations in the HF range with atrial stretch(14), suggesting that nonneural modulation of HR may also besuppressed in patients withCHF.

The present study shows that small HR fluctuations synchronous with breathing persist after GB, and their magnitude is similarin healthy subjects and in patients with mild CHF. These residualHF fluctuations are unlikely to be vagally mediated, since, inthe dose range employed in this study, trimethaphan camsylatecompletely abolished the reflex bradycardia in response to thephenylephrine-induced increase in BP (Fig. 1). Moreover, the LFcomponent was abolished by GB in all subjects (Table 1). Sincesympathetic and vagal activities have been shown to contributeto the HRV in this frequency range (23), its disappearance withhigh doses of trimethaphan camsylate provides further evidencefor the adequacy of GB. We also show that, during spontaneousbreathing, nonneural mechanisms contribute significantly (i.e.,15%) to the HF power in patients with mild CHF but not in healthyage-matched controls (3%). Since nonneural modulation of HR waspreserved in CHF patients, its contribution to the HF componentwas inversely related to HRV (as assessed by the RR standard deviation,Fig. 5). Taken together, our results indicate that the HF powerof the HRV can overestimate cardiac parasympathetic responsivenessin patients with mild CHF and, indeed, whenever the HRV is significantlyreduced. This is especially the case when HF is expressed in "normalized"units (i.e., as a percentage of the RR variance) or as LF-to-HFratio (1). Our findings would have been more dramatic if wehad included patients with severe CHF. Indeed, we found that thecontribution of nonneural oscillation to the HF component of theHRV was ~50% in four NYHA Class III patients (data not shown).However, high doses of trimethaphan camsylate are poorly toleratedin this group; thus we decided to limit our study to less symptomaticpatients. Nevertheless, the strong inverse relationship betweencontribution of nonneural mechanisms to the HF power and HRV providesproof of a basic principle that can be applied to virtually allpathophysiological conditions associated with a reduction in vagalactivity or responsiveness (7). Predictably, maneuvers thatare known to increase the vagally mediated respiratory sinus arrhythmia,such as slow deep breathing (13), significantly decreased therelative importance of nonneural mechanisms (Fig. 4). Since controllingthe breathing rhythm also reduces the incidence of periodic orCheyne-Stokes respiration in patients with CHF (19), this procedure,as well as the use of absolute units for expressing HF power,appears to be strongly advisable when one attempts to assess cardiacautonomic control or prognosis by using spectral analysis of HRVin patients withCHF.

Mechanisms responsible for the nonneural HF oscillations. HR fluctuations in the HF range result from periodic stretching of the sinoatrial node secondary to changes in atrial transmuralpressure with breathing (6, 21). Pacemaking activity is knownto be enhanced by mechanical stretch (15), and stimulation ofmechanosensitive Cl channels has been shown to be at least in part responsible forthis phenomenon (1, 12). The degree of atrial stretch isdependent on the breathing pattern, and large increases in $V$ Iand VT have been shown to enhance nonneural respiratory sinusarrhythmia in heart transplant patients (2, 3, 25). Similarly,Perlini et al. (21) found that the HF power of the HRV in anesthetizedrabbits after vagotomy and $beta$ -adrenergic blockade was positivelycorrelated with VT and, to a smaller extent, breathing frequency.The main determinant of nonneural HR oscillations, however, wasrespiratory flow, and combinations of VT and breathing frequenciesthat gave the same $V$ I also resulted in similar nonneural HF power(21). Consistent with these findings, controlled breathing at0.16 Hz did not affect the amplitude of the HF component afterGB (Table 1), since the increase in VT was counteracted by thereduction in breathing frequency and $V$ I did not change comparedwith spontaneous breathing (Table 2).

Summary. This study shows that the relative contribution of nonneural mechanisms to the respiratory sinus arrhythmia is significantlyincreased in patients with mild CHF, accounting on average for15% (range 1-77%) of the HF component of the HRV (vs. 3% in controls).These findings suggest that spectral analysis of HRV should beinterpreted with caution in all patients with CHF (not just inthose with terminal disease) or, indeed, whenever the HRV is significantlyreduced [e.g., during exercise (7)]. Since RR oscillationsin the LF range appear to be entirely neurally mediated whereasthose in the HF range are clearly not, the use of normalized unitsor of the LF-to-HF ratio in CHF patients would lead to a significantoverestimation of the level of cardiac vagal responsiveness. However,the accuracy of respiratory sinus arrhythmia as a vagal indexcan be improved by controlled breathing, since this maneuver appearsto increase the vagal contribution to respiratory sinus arrhythmiawithout affecting its nonneuralcomponent.

	ACKNOWLEDGEMENTS

We gratefully acknowledge the support of the Garfield Weston Trust and the Norman CollissonFoundation.

	FOOTNOTES

Address for reprint requests and other correspondence: B. Casadei, University Dept. of Cardiovascular Medicine, John RadcliffeHospital, Oxford OX3 9DU, UK (E-mail: barbara.casadei{at}cardiov.ox.ac.uk).

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.Section 1734 solely to indicate thisfact.

Received 8 June 2000; accepted in final form 10 August 2000.

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