Summary
The publication concerns the assessment of sleep breathing disorders as well as their interactions with the function of the autonomous nervous system after cardiac resynchronization therapy (CRT). After a 3-month observation period, the improvement in sleep breathing disorders, the quality of sleep, daytime sleepiness, clinical and echocardiographic parameters accompanied the improvement in the baroreflex sensitivity (BRS). In addition, among the analyzed breathing disorders during sleep, the presence of the central type of sleep apnea was associated with the greatest benefits of using CRT.
Introduction
Heart failure is a major and constantly increasing health problem. Currently the condition affects at least 26 million people worldwide [1]. Patients with chronic heart failure commonly suffer from breathing disorders during sleep [2–4]. It is estimated that sleep apnea occurs in 47–76% of patients with heart failure [5]. Heart failure is the principal risk factor of sleep breathing disorders, which may create a vicious circle of negative effects on the cardiovascular system [6]. The presence of breathing disorders during sleep in patients with heart failure is associated with increased risk of cardiovascular morbidity and mortality [7, 8].
The development of cardiac resynchronization therapy (CRT), which improves the exercise capacity, reduces the frequency of hospitalization associated with exacerbation of heart failure, reduces mortality, and improves the quality of life, has been a breakthrough in the treatment of heart failure [9–11]. The favorable effect of CRT on the prognosis and comfort of life may also be related to its impact on numerous disorders that accompany heart failure.
Aim
The aim of the present study was to assess the impact of CRT on sleep breathing disorders, and to determine the relationship between the changes observed in the autonomous nervous system and sleep disorders after the introduction of this therapy.
Material and methods
The study covered a group of 55 patients with chronic heart failure stable for at least the last 3 months, in New York Heart Association (NYHA) class III or IV despite optimal medical therapy, with a reduced left ventricular ejection fraction (LVEF) ≤ 35%, QRS complex duration ≥ 120 ms, and sinus rhythm. Patients who did not agree to participate in the study, had atrial fibrillation/flutter, had a sinus node disease, second or third degree atrioventricular block, implanted pacemaker, had numerous ventricular or supraventricular ectopic beats (more than 5% of all QRS complexes recorded), were hospitalized due to unstable angina, myocardial infarction or heart failure in the period of 3 months before implantation of the cardiac resynchronization system, underwent coronary artery bypass grafting or percutaneous coronary intervention within 3 months before implantation of the cardiac resynchronization system, underwent heart transplant surgery, had peripheral neuropathy, had contraindications for surgical procedures, who were treated for sleep disorders, and who participated in another research program at the time of the start of the study were excluded. In the case of coherence between RR interval and systolic blood pressure less than 0.5, patients were excluded from the research, too. In addition, pregnant women and patients whose heart failure was secondary to reversible conditions were excluded from the study.
The study was conducted according to the principles of the Helsinki Declaration, and it was approved by the Institutional Ethical Committee. All enrolled patients were informed about the course of the study, and written informed consent for participation in this study was then obtained.
Before the cardiac resynchronization system was implanted and after 3 months of observation, each patient underwent an interview and physical examination, electrocardiography at rest, echocardiography, 6-minute walk test (6MWT) and polysomnography with the Pittsburgh Sleep Quality Index (PSQI) questionnaire and the Epworth Sleepiness Scale (ESS) completed by each subject. Also baroreflex sensitivity (BRS) was evaluated. An X-ray scan of the chest was performed before and 3 days after implementation of CRT. The PSQI questionnaire evaluated the following 7 sleep quality parameters: time needed to fall asleep, duration and effectiveness of sleep, sleep disorders, the use of sleeping pills, subjective sleep quality, and difficulties with daytime functioning. The result of each sleep quality parameter ranged from 0 to 3 points. The maximum score was 21. A result above 5 points indicated poor quality of sleep [12]. Additionally, the ESS was used, which allowed the assessment of the probability of falling asleep in eight different situations occurring in everyday life. A response to each question was given according to a 4-point scale (0–3), depending on the probability of falling asleep. The total score ranged between 0 and 24. A total score higher than 10 points indicated subjective excessive daytime sleepiness [13–15]. The sleep examination was performed in a hospital setting, in a single room, at night, using the Embla S 4000 polysomnographic system. The Somnologica software was used for the analysis of obtained data. The polysomnographic examination involved: single-channel electrocardiography, 3-channel electromyography, 2-channel electrooculography, 6-channel electroencephalography, and registration of the sound of snoring and air-flow through the nose/mouth. The patient’s body position, movements of the chest and abdomen, as well as pulse oximetry were also monitored. Apnea was defined as an episode lasting for at least 10 s of a reduction in air-flow amplitude by ≥ 90% of the pre-event baseline. Apnea episodes were divided into: obstructive, central, and of mixed background. The classification was based on the recorded activity of respiratory muscles. Obstructive sleep apnea was diagnosed when an episode of a reduction in air-flow amplitude by ≥ 90% of pre-event baseline lasting for at least 10 s was accompanied by respiratory movements of the chest and abdomen. Central sleep apnea was diagnosed in the case of an episode of a reduction in air-flow amplitude by ≥ 90% of the pre-event baseline lasting for at least 10 s with no respiratory movements of the chest and abdomen. Mixed sleep apnea was defined as a combination of central sleep apnea at the initial phase and obstructive sleep apnea in the final phase. Hypopnea was defined as a reduction of the amplitude of air-flow by at least 30% of the pre-event baseline lasting for at least 10 s, accompanied by oxygen desaturation by ≥ 3% from the pre-event baseline or arousal [16]. The following polysomnographic parameters were analyzed: apnea-hypopnea index (AHI) indicating the number of apnea and hypopnea episodes per hour of sleep, apnea index (AI) corresponding to the number of apnea episodes per hour of sleep, obstructive apnea index (OAI) indicating the number of obstructive apnea episodes per hour of sleep, central apnea index (CAI) indicating the number of central apnea episodes per hour of sleep, mixed apnea index (MAI) indicating the number of mixed apnea episodes per hour of sleep, hypopnea index (HI) indicating the number of hypopnea episodes per hour of sleep. The examination of BRS was carried out in a quiet room, after a 15-minute rest in a lying position, for stabilization of the cardiovascular system. All subjects refrained from eating, drinking coffee and smoking for 3 h before the start of the examination. The protocol involved registration of signals in a lying position with spontaneous respiration for 10 min. Arterial blood pressure was monitored using the beat-to-beat method (Finometer Pro device – Finapres Medical Systems B.V.). An electrocardiogram was recorded, too. Baroreflex sensitivity was evaluated with non-invasive methods: spectral analysis and the sequence method (BRSseq). The α coefficient for the LF component (spectral power at low frequencies ranging between 0.04 and 0.14 Hz) and for the HF component (spectral power at high frequencies ranging between 0.15 and 0.4 Hz) was calculated as the square root of the quotient of the spectral power variability of the RR interval and systolic blood pressure. The transfer function modulus (TF) was calculated between RR interval oscillations and oscillations of systolic blood pressure for the LF and HF components. Assessment of baroreflex sensitivity using the sequential technique was based on the automatic capture of sequences of four or more consecutive heart evolutions, where the increase or decrease in systolic blood pressure was accompanied by a corresponding gradual increase or decrease of the length of the heart cycle. The slope of the regression curve plotted for the correlation between changes in systolic blood pressure and changes in the RR interval was assumed as the value of BRSseq [17].
Statistical analysis
The statistical analysis was performed using the Statistica 10 software and was presented as mean value ± standard deviation (SD), median with interquartile range (Q1–Q3) or percentages. Parameters were tested for normal distribution with the Shapiro-Wilk test. Data were analyzed using the Wilcoxon signed-rank test, the Mann-Whitney U test and Spearman’s rank correlation coefficient. A p-value of < 0.05 was considered statistically significant.
Results
Fifty-five patients were enrolled in the study, including 45 males (81.8% of subjects) and 10 females (18.2% of subjects). The clinical characteristic and pharmacotherapy of the study population are presented in Table I.
Table I
After a 3-month observation period, the QRS complexes narrowed (170 (160–200) vs. 140 (120–160) ms, p < 0.001) and also the echocardiography showed a significant improvement in LVEF (26% (21–32%) vs. 32% (27–37%), p < 0.001). In addition, the severity of heart failure assessed according to the NYHA classification significantly decreased (3.11 ±0.31 vs. 2.2 ±0.58, p < 0.001) and the distance covered by the patients during the 6-minute walk test increased (300 (250–320) vs. 360 (300–400) m, p < 0.001).
In the study group, at baseline, 43.6% of patients had apnea that was predominantly central, 38.2% of patients had apnea that was predominantly obstructive and 18.2% of patients had apnea that was predominantly mixed. Polysomnography indicated a significant reduction in AHI after 3 months from CRT implementation. There was also a significant reduction in AI, CAI, and MAI. There were no significant changes in OAI or in HI. The evaluated polysomnographic parameters are presented in Table II. An improvement defined as 50% or more reduction in the number of obstructive sleep apnea episodes was reported in 23.8% of patients with this type of sleep breathing disorders. There were no statistically significant differences in baseline LVEF (p = 0.364), NYHA class (p = 0.283), 6MWT (p = 0.409), or body mass index (BMI) (p = 0.433) between groups of patients with obstructive sleep apnea responding and not responding to cardiac resynchronization therapy according to the accepted improvement criterion. In the examined group of patients, before the use of CRT, the subjects with AHI exceeding 30 events per hour of sleep prevailed. After the cardiac resynchronization system was implanted, the dominant group consisted of patients with AHI of 15–30 events per hour of sleep. Moreover, introduction of CRT resulted in significant improvement of the quality of sleep assessed with the PSQI questionnaire, and also in significant reduction of daytime sleepiness as measured with the ESS (Table III).
Table II
In the analysis of interrelations between the assessed parameters, statistically significant negative correlations between changes in AHI, AI, CAI and changes in BRS evaluated with all three methods in the supine position during spontaneous breathing were demonstrated. Also the relationships between changes in MAI and changes in BRSseq, α HF and TF HF were statistically significant. Among the analyzed types of sleep breathing disorders, the strongest negative correlations were observed between changes in CAI and changes in BRS evaluated with all three methods. Significant negative correlations were observed between changes in intensity of daytime sleepiness and changes in BRS. In addition, significant negative correlations between changes in sleep quality and changes in the values of BRSseq, α HF, and TF HF were noted in the study group. However, no significant correlations were found between changes in sleep quality and changes in α LF and TF LF values. Statistically significant positive correlations were observed between changes in LVEF, 6MWT and changes in BRSseq, α HF, TF HF. There were significant negative correlations between changes in NYHA class and changes in BRSseq, α HF, TF HF. Non-significant correlations were noted between changes in LVEF, NYHA class, 6MWT and changes in α LF, TF LF. The results mentioned above are presented in Table IV.
Table IV
[i] AHI – apnea-hypopnea index, AI – apnea index, α HF – α coefficient in the high frequency band, α LF – α coefficient in the low frequency band, BRSseq – baroreflex sensitivity measured by the sequence method, CAI – central apnea index, ESS – Epworth Sleepiness Scale, HI – hypopnea index, LVEF – left ventricular ejection fraction, MAI – mixed apnea index, NYHA – New York Heart Association, OAI – obstructive apnea index, PSQI – Pittsburgh Sleep Quality Index, 6MWT – 6-minute walk test, TF HF – transfer function modulus in the high frequency band, TF LF – transfer function modulus in the low frequency band.
The mutual associations between changes in polysomnographic parameters and changes in the quality of sleep, daytime sleepiness, LVEF, NYHA class, 6MWT occurring after 3 months of CRT are presented in Table V. It was observed that changes in AHI, AI and CAI were significantly correlated with changes in the quality of sleep, daytime sleepiness and changes in LVEF, NYHA class, and 6MWT. Moreover, there was a statistically significant positive correlation between changes in MAI and changes in the subjective assessment of sleep quality. However, there were no significant correlations between changes in OAI, MAI, HI and changes in LVEF, NYHA class, 6MWT, as well as between changes in OAI, HI and changes in the quality of sleep, and also between changes in OAI, MAI, HI and changes in daytime sleepiness.
Table V
[i] AHI – apnea-hypopnea index, AI – apnea index, CAI – central apnea index, ESS – Epworth Sleepiness Scale, HI – hypopnea index, LVEF – left ventricular ejection fraction, MAI – mixed apnea index, NYHA – New York Heart Association, OAI – obstructive apnea index, PSQI – Pittsburgh Sleep Quality Index, 6MWT – 6-minute walk test.
There were statistically significant negative correlations between changes in the quality of sleep and changes in LVEF and 6MWT, as well as a statistically significant positive correlation between changes in the quality of sleep and changes in NYHA class. Also, changes in the severity of daytime sleepiness correlated negatively, significantly with changes in LVEF. The results are shown in Table VI.
Discussion
In the present study, the values of AHI, AI, CAI, and MAI were significantly reduced after 3 months of CRT. Moreover, no significant changes in OAI and HI were noted. In the literature there are controversial data about the influence of CRT on sleep breathing disorders. Lüthje et al. demonstrated that CRT significantly reduces the central apnea-hypopnea index remaining without a significant impact on the obstructive apnea-hypopnea index [18]. By contrast, Stanchina et al. assessing the effect of CRT on obstructive respiratory events observed a decrease in AHI [19]. In addition, in the present study a statistically significant reduction in the number of episodes of central sleep apnea accompanied the improvement of LVEF. Significant negative correlations between changes in LVEF and changes in CAI, as well as between changes in LVEF and changes in AHI and AI, were noted. However, there were no statistically significant relationships between changes in LVEF and changes in OAI, MAI, or HI. This suggests the existence of a relationship between the number of central sleep apnea episodes and the severity of heart failure.
The dysfunction of the autonomous nervous system may be manifested by a decrease in baroreflex sensitivity [20]. In the present study, negative correlations between changes in baroreflex sensitivity and changes in the polysomnographic parameters were demonstrated. Statistically significant negative correlations were found between changes in AHI, AI and changes in baroreflex sensitivity evaluated using the sequence method, the α coefficient and the transfer function modulus. Among the analyzed types of sleep breathing disorders, the strongest correlations were demonstrated between changes in BRS and changes in CAI. The present results suggest that the improvement of sleep breathing disorders occurring 3 months after the implementation of CRT is parallel to the improvement of baroreflex sensitivity. Assessment of baroreflex sensitivity may therefore play an important role in predicting the severity of sleep breathing disorders. The significant reduction in the central apnea index with the strongest, among the analyzed types of sleep breathing disorders, statistically significant negative correlations between the changes in this index and changes in baroreflex sensitivity may indicate that the patients with heart failure and the central type of sleep apnea will benefit most from implantation of the cardiac resynchronization system.
An important problem in patients with heart failure is the poor quality of sleep, which is a barrier to self-care and compliance with treatment in this group of patients [21]. In the present study, the improvement of the polysomnographic parameters was accompanied by an improvement in the subjective quality of sleep assessed using the PSQI questionnaire. Statistically significant correlations between changes in sleep quality and changes in AHI, AI, and CAI were noted. A statistically significant, though weaker, correlation was observed between changes in the quality of sleep and changes in MAI. In addition to assessing the quality of sleep, the subjective assessment of daytime sleepiness is also an important element in the diagnosis of sleep disorders. Daytime sleepiness measured with the ESS was significantly decreased following CRT. An association between daytime sleepiness and baroreflex sensitivity was demonstrated in the present study. It was found that the reduction of daytime sleepiness after the use of CRT was simultaneously associated with increased baroreflex sensitivity. Statistically significant negative correlations were observed between changes in daytime sleepiness and changes in baroreflex sensitivity measured using the sequence method, the α coefficient and the transfer function modulus. Occurrence of excessive daytime sleepiness may indicate changes in autonomous regulation of the heart work in patients with sleep breathing disorders. The reduction of AHI and daytime sleepiness coexisting with the increase in BRS observed after the use of CRT indicates an increase in the activity of the parasympathetic part of the autonomous nervous system. Moreover, the obtained results suggest that an assessment of baroreflex sensitivity and the apnea-hypopnea index may be useful in predicting the occurrence of daytime sleepiness and its severity. It is worth noting that after the implementation of cardiac resynchronization therapy, the improvement of clinical and echocardiographic parameters was accompanied by an improvement in subjective sleep assessment, which intensified the benefits of this therapy.
The obtained results indicate that the use of cardiac resynchronization therapy may bring the greatest benefits in patients with heart failure and the coexisting central type of sleep apnea. Already after a 3-month observation period, the implementation of cardiac resynchronization therapy resulted in a significant reduction in the number of central sleep apnea episodes with simultaneous improvement in both clinical and echocardiographic parameters, subjective sleep parameters, as well as in the autonomous nervous system function. This suggests that the coexistence of central sleep apnea in patients with heart failure is a predictor of response to cardiac resynchronization therapy. Therefore, screening for sleep breathing disorders prior to implantation of a cardiac resynchronization system may help identify patients with heart failure who will respond to cardiac resynchronization therapy and will receive the greatest multidirectional benefits of this therapy. In addition, baroreflex sensitivity is a reflection of the clinical and echocardiographic response to CRT, as well as the severity of breathing disorders during sleep, sleep quality and daytime sleepiness, so it can be used to assess the effectiveness of cardiac resynchronization therapy.
Conclusions
The present study showed that the use of CRT reduced the number of apnea-hypopnea episodes, and in particular the number of central and mixed type sleep apnea episodes. Moreover, a beneficial effect of CRT not only on objective but also subjective sleep features, such as sleep quality and daytime sleepiness, was observed already after 3 months of this therapy. The improvement in sleep breathing disorders, the quality of sleep, daytime sleepiness, clinical and echocardiographic parameters occurring after the implementation of CRT was associated with the improvement of the autonomous nervous system function. Due to a significant reduction of CAI after the use of CRT, and the occurrence of the strongest among the analyzed types of sleep breathing disorders, statistically significant negative correlations between changes in CAI and changes in BRS, and also because of the strongest relationship between improvement in CAI and improvement in sleep quality, daytime sleepiness, clinical and echocardiographic parameters, it may be assumed that patients with heart failure and the central type of sleep apnea will benefit most from CRT.