Sinus Node Dysfunction After Orthotopic Cardiac Transplantation: Postoperative Incidence and Long-Term Implications

We investigated incidence, normalization rates, and clinical significance of sinus node (SN) dysfunction after cardiac transplantation. Thirty-nine of 90 patients systematically evaluated presented with impaired SN function in the postoperative period. Of these, 22 normalized their SN function during follow-up while 17 remained impaired after 3 months. The proportion normalized was higher in patients with prolonged SN recovery time (11/16, 68.8%) and those reverting from escape rhythm to sinus rhythm until discharge (5/8, 62.5%) when compared to patients in escape rhythm throughout the postoperative period (5/11, 45.5%) or pacemaker dependence (1/4, 25%). There was no reliable postoperative predictor of normalization and necessity of long-term pacing. A postoperative heart rate consistently less than 70 beats/min (irrespective of the native rhythm) was significantly related to outcome (P = 0.01), but revealed unacceptable sensitivity (61.5%) and specificity (81%). After all, both patients with severe symptoms (near syncopes and syncope), were derived from this group. These two patients, who had been discharged in sinus rhythm, had late pacemakers implanted. An additional 17 patients had early pacemaker placement, only seven of which were constantly paced during follow-up. Given the low normalization rates, patients with postoperative escape rhythm are those most likely to benefit from pacemaker therapy over the long term. Even those in, or reverting back to, sinus rhythm until discharge may experience severe symptoms, particularly in the setting of a postoperative rate consistently less than 70 beats/min since this indicates a relatively lower probability of recovery.     

Patterns of Atrioventricular Conduction During Postexercise Recovery in Patients with Atrial Fibrillation and Wolff-Parkinson-White Syndrome

The effects of the postexercise recovery phase on the functional anterograde conduction properties of the accessory pathway (AP) were evaluated. Twenty-nine patients with Wolff-Parkinson-White (WPW) syndrome were submitted to supine maximal bicycle exercise testing. In seven patients (group I), in whom sustained atrial fibrillation (AF) could be induced by transesophageal pacing (TP), mean ventricular rate (MVR), the shortest R-R interval (SRR) between preexcited beats, and the observed percentage of preexcited beats were evaluated at rest, after each step of exercise and 2 minutes after the end of exercise. In 22 patients (group II), in whom sustained AF could not be induced, decremental TP was performed to evaluate the shortest atrial cycle length (SCL) with 1:1 conduction over AP at rest, after each step of exercise, and 2 minutes after the end of exercise. In four patients in group I, the protocol was repealed with atropine injected during the last minute of exercise. In 12 patients (three from group I and nine from group II), catecholamine plasma levels were measured at rest, at peak exercise, and during recovery. MVR was 144 ± 20 beats/min at rest, 186 ± 21 beats/min at peak exercise (P < 0.001 vs rest), and 179 ± 21 beats/min during recovery (P < 0,001 vs rest; P < 0.05 vs peak exercise). SRR was 289 ± 73 msec at rest, 223 ± 25 msec at peak exercise (P < 0.05 vs rest), and 227 ± 29 msec during recovery. Preexcited beat percentage was 95.4 ± 12 at rest, 35.2 ± 24.2 at peak exercise (P < 0.001 vs rest), and 85.1 ± 22.5 during recovery fP < 0.01 vs peak exercise and n.s. vs rest). In patients in whom atropine was injected MVR was 139 ± 17 beafs/min at rest, 184 ± 19 beats/min at peak exercise (P < 0.05 vs rest), and 172 ± 16 beats/min during recovery (P < 0.05 vs peak exercise, P < 0.05 vs rest); SRR was 320 ± 71 msec at rest, 225 ± 25 msec at peak exercise, and 232 ± 3 inset; during recovery; preexcited beat percentage was 99 ± 1 at rest, 26 ± 18 at peak exercise (P < 0.01 vs rest), and 28 ± 20 during recovery (NS vs peak exercise, P < 0.01 vsrest). In group II. mean sinus rate was 84 ± 12 beats/min at rest, 151 ± 15 beats/min at peak exercise, and 117 ± 21 beats/min 2 minutes after the end of exercise; mean SCL was 328 ± 75 msec at rest, 273 ± 76 msec at peak exercise (P < 0.0001 vs rest), and 280 ± 79 msec during recovery (P < 0.0001 vs rest and NS vs peak exercise). Mean epinephrineand norepinephrine plasma levels (12 patients from groups I and II) were; 4 7.9 ± 76.6 and 355.5 ± 185.1 pg/mL at rest; 193.0 ± 88.0 and 823.9 ± 390.3 pg/mL at peak exercise (P < 0.0001 vsrest); 148.5 ± 94.5 and 672.7 ± 272.3 during recovery (P < 0.001 vs rest; P < 0.01 vs peak exercise). Thus, during early recovery versus peak exercise: SCL and SRR are still lower and confirm the persistence of increased AP conductivity; in patients with atrial fibrillation preexcited beat percentage is markedly enhanced while the duration of preexcited complexes is increased and MVR is still high. The poslexercise recovery phase in patients with WPWand atrial fibrillation determines a higher ventricular response rate with major preexcitation than does rest and peak exercise. The fact that atropine prevents increases in preexcited beats percentage demonstrates that the underlying electrophysiological basis is a discordance of autonomic effects on the conduction properties of the two afrioventricular pathways.     

Benefits and Limitations of Rate Adaptive Pacing Under Laboratory and Daily Life Conditions in Patients with Minute Ventilation Single Chamber Pacemakers

Rate adaptive pacing has been shown to improve hemodynamic performance and exercise tolerance during acute testing. However, there remain concerns about its benefit in daily life and possible complications incurred by unnecessary pacing. This double-blind crossover study compared the benefit of rate adaptive (SSIR) versus fixed rate (SSI) pacing under laboratory and daily life conditions in 20 rate incompetent patients with minute ventilation single chamber pacemakers (META II). The heart rate (HR) response during three different exercise tests (treadmill, bicycle ergomctry, walking test) was correlated with the Holler findings during daily life in either pacing mode. The maximal HR was significantly higher in the SSIR-mode compared to the SSI-mode, both during laboratory testing (treadmill: 123 ± 15 vs 93 ± 29 beats/min: ergometry: 118 ± 15 vs 89 ± 27 beats/min; walking test: 127 ± 9 vs 95 ± 26 beats/min, all P values < 0.01) as well as during daily life (Holter: 126 ± 13 vs 103 ± 24 beats/min, P < 0.01). On Holter, the average HR (71 ± 14 vs 71 ± 8 beats/min) and the percentage of paced rhythm (54 % vs 62%, SSI- vs SSIR-mode, P = NS) were not different in either mode. However, despite a 30% rate gain in the SSIR-mode, the exercise capacity remained unchanged, and only 38% of patients preferred the SSIR-mode. Minute ventilation pacemakers provide a physiological rate response to exercise. Irrespective of the protocol used, the findings of laboratory testing are comparable to those during daily life. However, patient selection for rate adaptive single chamber pacing should be made with caution, since the objective benefit of restoring normal chronotropy may subjectively be negligible for most patients.     

Adequacy of Pacing Rate During Exercise in Rate Responsive Ventricular Pacing

Our objective was to determint; the adequate pacing rate during exercise in ventricular pacing by measuring exercise capacity, cardiac output, and sinus node activity. Eighteen patients with complete AV block and an implanted pacemaker underwent cardiopulmonary exercise tests under three randomized pacing rates: fixed rate pacing (VVJ) at 60 beats/min and ventricular rate-responsive pacing (VVIR) programmed to attain a heart rate of about 110 beats/min ar 130 beats/min (VVIR 110 and VVIR 130, respectively) at the end of exercise. Compared with VVI and VVIR 130, VVIR 110 was associated with an increased peak oxygen uptake(VVIR 110:20.3 ± 4.5 vs VVI: 16.9 ± 3.1; P < 0.01; and VVIR 130: 19.0 ± 4.1 mL/min per kg, respectively; P < 0.05) and a higher oxygen uptake at anaerobic threshold (15.3 ± 2.7, 12.7 ± 1.9; P < 0.01, and 14.6 ± 2.6 mL/min per kg; P < 0.05). The atrial rate during exercise expressed as a percentage of the expected maximal heart rate was lower in VVIR 110 than in VVI or VVIR 130 (VVIR 110: 75.9%± 14.6% vs VVI: 90.6%± 12.8%; P < 0.01; VVIR 110 vs VVIR 130: 89.1%± 23.1%; P < 0.05). There was no significant difference in cardiac output at peak exercise between VVIR 110 and VVIR 130. We conclude that a pacing rate for submaximal exercise of 110 beats/min may be preferable to that of 130 beats/min in respect to exercise capacity and sympathetic nerve activity.     

A New Motion Responsive Pacemaker: First Clinical Experience with an Acceleration Sensor Pacemaker

A new accelerometer-based adaptive rate pacemaker (OEXCELVR^TM) was evaluated to investigate its behavior at nominal settings during treadmill exercise testing and postural changes. Eight patients with sinus rhythm were selected to compare intrinsic heart rate to sensor mediated rate. Throughout exercise treadmill testing, changes in the sensor mediated rate closely paralleled actual physiological changes. The Pearson product moment correlation of pacing rate with sinus frequency, calculated for all patients, was r = 0.82 (P = 0.001). Change in the patient's physical position resulted in immediate change in sensor rate, which corresponded appropriately to the type of position change and activity level. Average (± SD) pacing rate was 62.4 ± 2.7 beats/min supine; 67 ± 3.8 beats/min sitting; 69.8 ± 6.4 beats/min standing; 81.6 ± 8.7 beats/min slow walking; and 96.8 ± 1.3 beats/min fast walking. After 4 minutes of recovery, the average pacing rate dropped to 65 ± 3 beats/min. The interaction between the accelerameter and the pulse generator at nominal settings was accurate and infrequently required the use of its many programming options. The accelerometer sensor and pulse generator algorithm in this device during postural change and exercise resulted in physiological-like changes in sensor mediated heart rate.     

Direct comparison of a contractility and activity pacemaker sensor during treadmill exercise testing

There are limited data about the chronotropic capacity of the peak endocardial acceleration (PEA) sensor. This study directly compared the chronotropic function from the PEA and the activity (ACT) sensor. The study included 18 patients (age 73 ± 7 years) with ≥ 75% pacemaker-driven heart rate (HR) and a PEA sensor and 11 healthy controls (age 67 ± 7 years) underwent a chronotropic assessment exercise protocol (CAEP) exercise test with the pacemaker patients in VVIR mode after programming the sensors in the default setting with adjustment of the upper sensor rate as an age related maximum value (220-age). The ACT sensor was externally strapped on the thorax. Achieved exercise duration for the patients and controls was, respectively, 9.2 ± 3 vs 18.4 ± 4 minutes (P < 0.001). The maximal achieved HR with the PEA sensor was 124 ± 25 beats/min, versus the ACT with 140 ± 23, versus the controls with 153 ± 26 beats/min (P < 0.001 between the groups). For the PEA, ACT, and controls, the time to peak HR was, respectively, 11 ± 3, 7 ± 3.6, and 18 ± 4 (P < 0.001 between groups) and HR after 10 minutes recovery was, respectively, 80 ± 20, 65 ± 15, and 82 ± 4 beats/min (P < 0.001 between groups). The PEA sensor functions hypochonotroop during exercise programmed as a single sensor system. It is, therefore, preferable to combine the PEA sensor with an activity-based sensor in a dual sensor system. Although both groups had normal left ventricular functions, the exercise capacity of pacemaker patients is significantly lower than in the controls.     

Importance of the Site of Ventricular Tachycardia Origin on Left Ventricular Hemodynamics in Humans

Experimental animal data have indicated that the site of ventricular tachycardia origin and, hence, the degree of asynchronous contraction, may influence the hemodynamic tolerance during sustained ventricular tachycardia. However, data in man are scarce. We studied patients with preserved left ventricular function and absence of significant coronary artery disease. Ventricular tachycardia was simulated with rapid pacing (at 120 and 150 beats/min), performed randomly, from the right ventricular apex or the right ventricular outflow tract. Following pacing from one site, it was repeated from the alternate site. Compared to outflow tract pacing, QRS duration was significantly longer during rapid pacing from the apex. Left ventricular pressure was recorded using a micromanometer-tipped catheter. During sinus rhythm, peak systolic pressure was 142 ± 14 mmHg: at 120 beats/min, it decreased to 109 ± 12 mmHg during pacing from the apex and to 127 ± 21 mmHg during pacing from the outflow tract (P = 0.008). This difference diminished at 150 beats/min (101 ± 16 mmHg vs 112 ± 16 mmHg, respectively, P = 0.21). During sinus rhythm end-diastolic pressure was 13 ± 1 mmHg, which did not change significantly during pacing at 120 beats/min. During pacing at 150 beats/min, end-diastolic pressure increased to 21 ± 3 mmHg during pacing from the apex and to 16 ± 2 mmHg during pacing from the outflow tract (P = 0.005). Changes in first derivative of pressure and in isovolumic relaxation time constant were comparable during pacing from the two sites. Thus, it seems that tachycardias originating from the right ventricular outflow tract result in more favorable left ventricular hemodynamics, compared to those from the right ventricular apex     

Rate-Responsive Ventricular Pacing: Clinical Experience With the RS4-SRT Pacing System

Eighteen patients (11 men and 7 women) with symptomatic second or third degree atrioventricular block underwent implantation of the rate-responsive RS4-SRT pacing system. Exercise tolerance in RS4 mode was compared to that in VVI mode by randomized double-blind treadmill stress testing. Following hospital discharge, HS4 function was assessed by repeat exercise testing and 24-hour Holter monitoring. Difficulty in obtaining satisfactory P-wave amplitudes at implonfation (mean 3.1 ±1.5 mV) resulted in prolonged implantation times (mean 79.4 ± 26.4 minutes). Following implantation, 10 patients (58%) showed a significant ventricular rate response to exercise, seven did not, and one remained in sinus rhythm. For responders, peak ventricular paced rate and double product were significantly greater in RS4 than in VVI mode, being 101.8 ± 5.8 vs. 74.3 ± 0.4 beats per minute and 20.1 ± 2.9 vs. 15.5 ± 3.7 beats per minute ± mmHg ± 10⁻³, respectively (p < 0.001). However, treadmill times (10.5 ± 2.6 vs. 9.7 ± 3.3 minutes) and work done (5.51 ± 2.01 vs. 4.97 ± 2.33 joules ± 10⁻⁵) were not significantly different (p = 0.22). Following hospital discharge, repeat exercise testing and 24-hour Holter monitoring demonstrated RS4 junction in 11 of 16 and 15 of 18 patients, respectively. We conclude that, due to unreliable atrial sensing, the RS4-SRT pacing system does not provide the reliable rate-responsiveness required to improve exercise tolerance.     

Long-Term Intrinsic Pacemaker Function in Patients Paced for Sinus Node Deficiency After Cardiac Transplantation

Fifteen cardiac transplant recipients requiring permanent pacing (AAJ, n = 9; VVI, n = 6; rate responsive devices, n = 11) for postoperative sinus node (SN) insufficiency underwent evaluation of long-term SN function 240 to 1,461 days after transplantation. The intrinsic rhythm at the time of discharge was sinus in 7 patients; functional escape in 6 patients; and pacemaker dependent in 2 patients. At follow-up, 5 patients had regained regular sinus rhythm, accounting for a total of 11 patients in sinus rhythm while 4 patients were in functional bradycardia. The SN recovery time as determined by the permanent pacemaker was normal (< 1,500 msec) in only 1/8 patients in whom it was determined, although 4 of these 8 patients were temporarily overriding the pacemaker during ambulatory monitoring. Patients with pathological SN recovery times included 3 patients with late return of sinus rhythm and 4 patients who had recovered normal sinus rhythm before their discharge from the hospital. Three patients developed late symptoms despite apparent early normalization and underwent delayed pacemaker implantations on postoperative days 35, 52, and 225, respectively. We conclude that, in patients requiring pacemaker implantation after cardiac transplantation, normalization of SN function cannot be inferred from just return of sinus rhythm, regardless of whether it occurs early or late. These findings may have implications when a pacemaker exchange or explanation is being considered.     

Benign Prognosis of Early Sinus Node Dysfunction After Orthotopic Cardiac Transplantation

Previous reports raised concern about the prognosis of patients with sinus node (SN) dysfunction after cardiac transplantation and led to a low threshold for permanent pacemaker (PM) placement at most institutions. The present study addresses the survival in patients with normal and impaired post operative SN function and the effect of permanent pacing with respect to overall and cardiac mortality. There were 120 patients with normal (corrected SN recovery time < 520 ms, group I) and 47 patients with impaired SN function (corrected SN recovery time < 520 ms and/or sinus arrest ± escape rhythms). Pacing support was deemed unnecessary in 23 of 47 patients with SN dysfunction (group II; asymptomatic SN bradycardia and corrected SN recovery time 3,812 ± 5,800 ms) while a total of 24 patients had PM placement a mean of 29 ± 44 days after transplantation (symptomatic bradycardia or absence of sinus rhythm at discharge, group III). Patients were followed for a mean of 46.7 months. Thirty-five deaths occurred during the study period. Sixteen deaths were cardiac but none were causally related to the SN dysfunction (graft failure due to rejection or atheropathy n =14; myocardial infarction n = 2). Four of these cardiac deaths were sudden and all occurred in the presence of widespread structural abnormalities (rejection/vasculopathy/myocardial infarction). SN dysfunction was not related to overall (P = 0.25) or cardiac mortality (P = 0.33). Regarding either endpoint, patients who had permanent PM placement did no belter than their unpaced counterparts in group II (P = 0.53 and P = 0.33, overall and cardine mortality, respectively). Likewise, survival did not differ between groups 1 and III for either endpoint (P = 0.77, P = 0.65, respectively). These data suggest that patients with mild SN abnormality, who are in sinus rhythm at the time of discharge, can be followed by observation without specific therapy.     

Comparison of Continuously Recorded Sensor and Sinus Rates During Daily Life Activities and Standardized Exercise Testing: Efficacy of Automatically Optimized Rate Adaptive Dual Sensor Pacing to Simulate Sinus Rhythm

The normal sinus rhythm remains the gold standard to compare the rate response of a rate adaptive pacemaker. The aim of this study was to assess an automatically optimized dual sensor system by continuous comparison of the normal sinus (SR) and sensor indicated rates (SIR). Twelve patients with complete heart block (mean age 60 ± 9 years) with normal sinus rhythm received a dual sensor pacemaker driven by combined, automatically adaptive activity and QT sensors. After I month of automatic adaptation, patients performed a treadmill exercise in the VDD mode with simultaneous collection of SR and combined SIR. Thereafter the difference between SR and SIR was recorded over a 1-month period using a software downloaded into the pacemakers, with the patients ambulatory during this period. During exercise testing, the SR and SIR were significantly correlated (r =0.96 ± 0.02, P < 0.001), and the mean difference between SR and SIR was 4.01 ± 4.47 beats/mm. The percentages of paced beats, over the 1 month ambulatory period, that exhibited a difference between SR and SIR of 8 beats/mm were 98%± 2%, 90%± 4% and 67%± 8% for low, medium, and high workloads, respectively (P < 0.05, ANOVA). whereas > 95% of SIR were within 15 beats/min of SR independent of the level of activities. Thus, an automatically programmed dual sensor gives an accurate reflection of SR during exercise. SIR was less accurate for more vigorous daily life activities, but most of the SIR were within the normal SR variation of 15 beats/min.     

Relationship Between Atrioventricular Delay and Oxygen Consumption in Patients with Sick Sinus Syndrome: Relevance to Rate Responsive Pacing

To develop a dromotropic-controlled rate adaptive algorithm for patients with sick sinus syndrome (SSS) and intact AV conduction, 14 pace-maker patients with SSS underwent cardiopulmonary exercise testing (CPX). During exercise, the pace-maker was programmed in an AAT mode without rate adaptation, whereby 3 patients developed supraventricular arrhythmia and 11 patients kept sinus rhythm. Chronotropic incompetence (CI) at heart rate (HR) < 95 beats/min at the anaerobic threshold (AT) was found in five patients. In patients with chronotropic competence (CC), the HR increase was significantly greater than in CI patients (rest: 73.2 +/- 12.6 vs. 64.2 +/- 4.0 beats/min;AT:101.2 +/- 6.2 vs. 82.0 +/- 5.1 beats/min;peak: 135.2 +/- 10.7 vs. 103.2 +/- 10.9 beats/min). There was no significant difference in the AVD between CC and CI patients (rest: 167.7 +/- 38.6 vs. 170.8 +/- 22.5 ms, AT: 156.2 +/- 30.7 vs. 163.6 +/- 21.6 ms, peak: 144.7 +/- 29.0 vs. 152.4 +/- 15.0 ms). The correlation coefficient between HR increase and VO2 was +1.0 and between AVD decrease and VO2 - 1.0 in both groups. An increase in pacing rate from 75 beats/min to 120 beats/min without exercise (overpacing) led to a prolongation of the AV interval of about 30.6 +/- 14.2 ms. Based on this closed loop control with negative feedback, a dromotropic rate adaptive algorithm for patients with SSS and intact AV conduction could be developed.     

Doppler Echocardiographic Assessment of the Hemodynamic Benefits of Rate Adaptive AV Delay During Exercise in Paced Patients with Complete Heart Block

To determine if rate adaptation of the atrioventricular (AV) delay (i.e., linearly decreasing the AV interval for increasing sinus rate) improves exercise left ventricular systolic hemodynamics, we performed paired maximal semi-upright bicycle exercise tests (EXTs) on 14 chronotropically competent patients with dual chamber pacemakers. Nine patients with complete AV block (CAVB) and total ventricular pacing dependence during exercise comprised the experimental group. Pacemakers in these patients were programmed randomly to rate adaptive AV delay (AVDR) for one EXT and fixed AV delay (AVDF) for the other EXT. AVDF was 156 msec; AVDR decreased linearly from 156–63 msec from rates of 78–142 beats/min. The other five patients had intact AV conduction and comprised the control group who were exercised in identical fashion while their pacemakers were inhibited throughout exercise io assure reproducibility of hemodynamic measurements between EXTs. Cardiac hemodynamics were calculated using measured Doppler echocardiographic systolic aortic valve flows recorded suprasternally with an independent 2-MHz Doppler transducer during a graded ramp exercise protocol. For analysis, exercise was divided into four phases to compare Doppler measurements at submaximal and maximal levels of exercise, rest, early exercise (1st stage), late exercise (stage preceding peak), and peak. Patients achieved statistically similar heart rates between EXTs at each phase of exercise. Although at lower levels of exercise cardiac hemodynamics did not differ, experimental patients (with CAVB) showed a statistically significant benefit to cardiac output at peak exercise with heart rates of 129 ± 13 beats/min (AVDR: 9.4 ± 2.8 L/min; AVDE: 8.2 ± 2.6 L/min, P = 0.002), stroke volume (AVDR: 74.1 ± 25.6 mL; AVDF: 64.3 ± 24.4 mL, P = 0.0003), and aortic ejection time (AVDR: 253.3 ± 35.7 msec; AVDF: 226.7 ± 35.0 msec, P = 0.002). Duration of exercise, peak rate pressure product, peak aortic flow velocities, and acceleration times did not differ. In contrast, control group patients (intact AV conduction throughout exercise) showed no statistical differences between any hemodynamic parameters measured at any phase of exercise from the first to second exercise test. These data demonstrate that systolic cardiac hemodynamics measured echocardia-graphically at the high heart rates achieved with peak exercise are improved with AVDR compared to AVDF in chronofropically competent patients with complete AV block. This is due primarily to improved stroke volume and a longer systolic ejection time with AV delay rate adaptation.     

Sinus Node Dysfunction After Orthotopic Heart Transplantation: The Vienna Experience 1987–1993

In the present study, the annual incidence of postoperative sinus node dysfunction and the type of sinus node abnormality after cardiac transplantation were followed over a 6½-year period in 185 patients. Each year the sinus node function was systematically characterized by rhythm and corrected sinus node recovery time in a significant number of patients. Over the entire study period, there were 131 patients with normal sinus node function (corrected sinus node recovery time 318 ± 55 msec) while 54 patients had latent (n = 24, sinus rhythm, corrected sinus node recovery time 8,053 ± 2,198 msec) or manifest (n = 30, absence of sinus rhythm or pacemaker dependence) sinus node dysfunction. Twenty-nine patients had pacemaker placement. The incidence of sinus node dysfunction declined in absolute terms and when indexed by the actual number of patients transplanted per year (index 1987: 38.5; 1998: 17.6; 1989: 23.2; 1990: 29.1; 1991: 10.4; 1992: 7.5; 1993: 2.2). Among those with sinus node dysfunction, the annual percentage of patients presenting with prolonged recovery time, escape rhythm, and those reverting back to sinus rhythm until discharge did not change significantly over the study period (P = 0.22). On multivariate analysis, only the date of transplantation was significantly associated with the occurrence of postoperative sinus node deficiency (P = 0.0007) while age of recipient (P = 0.85) or donor (P = 0.96), the type of cardioplegia used (P = 0.09) and ischemic time (P = 0.09) were insignificant. This decline in the annual incidence of sinus node dysfunction most probably may be interpreted in terms of improvements in management (learning curve). It is unclear which changes in particular are responsible for this development. In view of the lack of other significant associations, this might be an indication that operative trauma plays a role in the etiology of sinus node dysfunction after cardiac transplantation.     

Diurnal Fluctuations in Human Ventricular and Atrial Refractoriness

The relative significance of the direct and indirect effects ofautonomic tone on diurnal fluctuations in human ventricular and atrial refractoriness are not well known. In this study, the circadian rhythms of ventricular and atrial effective refractory periods (ERPs) were measured by noninvasive programmed stimulation in ten patients (mean age 62 ± 10 years) who had a permanent dual chamber pacemaker for complete atrioventricular (AV) block. The ERP was measured at 4-hour intervals during spontaneous sinus rhythm with ventricular pacing (day 1)and during constant-rate dual chamber pacing (day 2). Cosinor analysis showed the ventricular ERP to have a significant diurnal rhythm in sinus rhythm (amplitude, 12 msec; 95% confidence intervals 1–24 msec) but not during constant-rate pacing (amplitude, 4 msec; 95% confidence intervals -3–12 msec). The atrial ERP had a significant rhythm at times of both spontaneous sinus rate (amplitude, 19 msec; confidence intervals 13–24 msec) and constant heart rate (amplitude, 11 msec; confidence intervals 1–21 msec) with acrophase during the sleeping hours. The increase in heart rate during dual chamber pacing resulted in a more marked decrease in the average 24-hour ERP in the ventricle than in the atrium (46 ± 9 msec vs 12 ± 6 msec, P < 0.01). Thus, refractoriness is more rate dependent in the ventricle than in the atrium, and autonomic influences on ventricular refractoriness are mainly indirect, via fluctuations in the sinus rate, but atrial refractoriness is also affected by direct neural influences and/or other rate independent factors.     

Intravenous Adenosine: A Noninvasive Diagnostic Test for Sick Sinus Syndrome

Adenosine has a well established negative chronotropic effect on the smoatrial node. The most wideJy utilized test of sinus node/unction remains the sinus node recovery time (SNRT), which generally requires catheterization. We compared the effect of adenosine (150 meg/kg IV) on the lengthening of sinus cycle length (ADO:SCL) in 12 control patients (group I) and in 11 patients with clinical sick sinus syndrome (SSS) (group III, eight of whom had undergone prior permanent pacemaker implantation. Using 675 msec as an abnormal result indicating sinus node dysfunction (two standard deviations above the mean value established in controls), ADO:SCL had a sensitivity and specificity of 64% and 100%, which were equal to that observed for the corrected sinus node recovery time (CSNRT) (abnormal value 550 msec). There was a significant difference in the CSNRT between group I (304 ± 149 msec) and group II (1,199 ±936 msec, P = 0.003). There was no significant difference in ADO:SCL between groups I (256 ± 210 msec) and group II (1,213 ± 1,719 msec, P = 0.069); however, there was substantial overlap between patients exhibiting an abnormal ADO:SCL and CSNRT. As such, a significant difference in ADO.-SCL was evident between group II patients (1,784 ± 1,950 msec, n = 7) exhibiting an abnormal CSNRT and group I patients, P = 0.014. In conclusion, ADO:SCL has the same sensitivity and specificity for sinus node dysfunction as compared to the CSNRT. Intravenous adenosine may prove to be a useful noninvasive test to assess the need for permanent pacemaker implantation.     

The Hemodynamic Importance of Atrial Systole: A Function of the Kinetic Energy of Blood Flow?

The relative importance of atrial systole on left ventricular filling was investigated at rest and during exercise in 25 patients with dual chamber pacemakers. The mean blood flow velocity over the atrial valve, the velocities of the rapid filling phase (E), the active filling phase (A), and the E/ A ratio were determined for pulsed Doppler-echocardiography. The patients were first examined at rest during AV sequential pacing (DVI) at 70 and 104 beats/mm. The investigation was subsequently repeated during atrial synchronous pacing (VDD) at rest and during supine submaximal exercise at workloads adjusted to achieve heart rates corresponding to those during DVI pacing. The mean blood flow velocity at rest did not differ between DVI and VDD pacing at 70 beats/mm (0.46 vs 0.49 m/sec). When (he resting heart rate was increased to 104 beats/min (DVI) the mean blood flow velocity increased to 0.56 msec (P < 0.001). At a corresponding heart rate during exercise (VDD) the velocity increased to 0.70 msec (P < 0.001). At a resting heart rate of 70 beats/min the E/A ratio (n = 14) did not differ significantly between DVI and VDD pacing. With an increased resting heart rate (DVI) the E/A ratio decreased from 0,94 ± 0.45 to 0.78 ± 0.18; NS. When the heart rate increased during exercise (VDD) the E/A ratio increased from 0.75 ± 0.14 to 0.97 ± 0.16; P < 0.001. There was a positive correlation between the increase of the mean blood flow velocity and the increase of the E/A ratio during exercise (r = 0.69, P < 0,01). No such correlation was found when the heart rate was changed at rest. Thus, the importance of atrial systole on ventricular filling diminishes during exercise in accordance with increasing blood flow velocity, which by physical principles is related to the kinetic energy. The relative importance of atrial systole is hence inversely correlated to the kinetic energy of the blood flow.     

连续气道正压通气和高流量湿化氧疗方式下患者行纤维支气管镜诊疗的临床观察

目的探讨连续气道正压通气（CPAP）和高流量湿化氧疗（HFHCO）方式下患者行纤维支气管镜操作的临床效果。 方法选择2018年12月至2019年7月使用纤维支气管镜诊疗的26例留置人工气道患者,根据患者行纤维支气管镜的操作次数,将其分为CPAP组（32例次）和HFHCO组（32例次）。比较两组患者在纤维支气管镜诊疗操作前及诊疗操作过程中心率、呼吸频率、平均动脉压、外周动脉血氧饱和度（SaO₂）以及操作前后患者血液pH值、动脉血氧分压（PaO₂）、动脉血二氧化碳分压（PaCO₂）、脉搏血氧饱和度（SpO₂）。记录两组患者在行纤维支气管镜诊疗中的不良反应发生情况。 结果操作中,HFHCO组患者心率[（121 ± 3）次/ min vs.（130 ±3）次/ min]、呼吸频率[（21.3 ± 2.7）次/ min vs.（26.1 ± 2.3）次/ min]及平均动脉压[（99 ± 7）mmHg vs.（109 ± 8）mmHg]均较CPAP组患者显著降低（t = 5.232、5.164、6.424,P均< 0.001）。操作后,CPAP组和HFHCO组患者pH值[（7.45 ± 0.05）vs.（7.45 ± 0.07）]、PaO₂ [（86.5 ± 7.3）mmHg vs.（88.3 ±6.7）mmHg]、PaCO₂ [（40.1 ± 7.5）mmHg vs.（39.4 ± 6.8）mmHg]及SpO₂ [（93.9 ± 2.4）% vs.（94.1 ± 2.0）%]水平比较,差异均无统计学意义（t = 0.222、0.468、0.420、0.348,P = 0.731、0.670、0.684、0.697）。与同组操作前比较,CPAP组和HFHCO组患者操作中心率[（86 ± 4）次/ min vs.（130 ± 3）次/ min,（87 ± 4）次/ min vs.（121 ± 3）次/ min,t = 9.826、9.612,P均< 0.001]、呼吸频率[（17.8 ± 2.5）次/ min vs.（26.1 ± 2.3）次/ min,（16.7 ± 2.9）次/ min vs.（21.3 ± 2.7）次/ min,t = 8.488、5.837,P均< 0.001]及平均动脉压[（78 ± 7）mmHg vs.（109 ± 8）mmHg,（77 ± 7）mmHg vs.（99 ± 7）mmHg,t = 9.104、8.224,P均< 0.001]及操作后PaO₂ [（67.8 ± 2.6）mmHg vs.（86.5 ± 7.3）mmHg,（68.9 ± 4.0）mmHg vs.（88.3 ± 6.7）mmHg,t = 7.126、6.395,P均< 0.001]水平均显著升高。两组患者在进行纤维支气管镜诊疗操作过程中均未发生严重出血、恶性心律失常、气胸等事件。 结论对于留置气管插管或气管切开留置套管的患者,在应用CPAP或HFHCO给氧方式下行纤维支气管镜操作时均可改善患者气道通气,提高患者PaO₂,但是HFHCO给氧方式下患者的舒适度更好,减轻了患者呼吸、血流动力学体征的明显波动。     

Relationship Between QT Interval Duration and Electrical Induction of Ventricular Tachycardia

The relation of inducible ventricular tachycardia (VT) to QT interval duration of ventricular paced rhythm has not been evaluated. To clarify this relation we measured corrected QT interval duration (QT_C) during sinus rhythm and QT interval duration during ventricular paced rhythm (QT-V) in patients with coronary artery disease without (non-VT group = group B) and with inducible VT (VT group = group A). Duration of QT-V was greater in the VT group (n = 20) compared with non-VT group (n = 20) during ventricular pacing at cycle lengths of 600 ms (424 ± 26 vs 396 ± 19 ms, P < 0.01), of 500 ms (407 ± 20 vs 383 ± 21 ms, P < 0.01), and of 400 ms (390 ± 21 vs 362 ± 17 ms, P < 0.001). During sinus rhythm the mean values of QT_C were similar in both groups (408 ± 25 vs 413 ± 20 ms, NSJ. During ventricular stimulation the percentage of patients with values of QT-V exceeding 380 ms was 35% in non-VT group and 95% in VT group (P <0.01) at cycle length of 500 ms and 5% versus 60%, respectively, (P < 0.01), at cycle length of 400 ms. Thus, a trend toward longer QT values of ventricular paced rhythm exists in patients with inducible VT.     

Clinical Study of a New Activity Sensor for Rate Adaptive Pacing Controlled by Electrical Signals Generated by the Kinetic Energy of a Moving Magnetic Ball

A new rate adaptive pacemaker (Sensorithm) controlled by an activity sensor providing electrical signals induced by a magnetic ball moving freely in an elliptical cavity surrounded by two copper coils, was implanted in ten patients; mean age of 75 years (range 64–89). Six patients had atrioventricular block and four had sinus node disease. In auto-set testing procedure during a 1-minute walk in the corridor, a slope resulting in a maximum rate of 95 beats/min was selected in every patient, and a medium reaction time was programmed. During graded treadmill exercise tests the heart rate increased 63 ± 7 beats/min to 135 ± 6 beats/min in rate adaptive pacing mode (VVIR), and 15 ± 6 beats/min (P < 0.0001) in ventricular pacing mode (VVI). The symptom-limited exercise time was 9.1 ± 1.1 minutes and 8.2 ±1.2 minutes (P = NS), and the exercise distance was 501 ± 95 meters and 428 ± 92 meters (P < 0.05) in VVIR and VVI pacing mode, respectively. The maximum oxygen uptake was 20.6 ± 2.6 mL/kg per minute in VVIR pacing and 18.1 ± 2.1 mL/kg per minute (P < 0.05) in VVI pacing. The delay time until the pacing rate increased 10% of the total rate increase at onset of treadmill exercise was 4.4 ± 0.7 seconds. Assuming a linear relation between metabolic workload and heart rate response from rest to the age predicted maximum heart rate, a deviation of heart rate ranging from 13.5 ± 11.2% to –1.6 ± 5.2% from the expected heart rate at mid-point and endpoint of each quartile of workload was observed during treadmill testing. Conclusions : By using a 1 -minute walk test for selecting an appropriate slope setting, Sensorithm provided a significant and proportional heart rate increase during exercise resulting in an improvement of exercise capacity during VVIR pacing compared to VVI pacing.