The term "linking" has been used specifically to describe the mechanism for perpetuation of functional anterograde bundle branch block: namely, repetitive transseptal retrograde concealed penetration by impulses propagating along the contralateral bundle. We present selected examples that demonstrate that linking-type phenomena actually have a wide spectrum of expression in human macroreentry circuits, particularly those incorporating either the bundle branches and His bundle or the normal pathway and Kent bundle. The examples presented are as follows: (1) Circulation 71, No. 2, 254-265, 1985.
There are few studies on the relationship between socio-economic factors and rheumatic fever (RF) in the populations where the burden of both socio-economic deprivation and RF is still very high. The aim of this study is to assess the association between some socio-economic factors and RF by examining data available from a RF hospital in Bangladesh. We have reviewed the medical records of patients presenting with manifestations suggestive of RF during a 1-year period. From the patients who showed group A beta-haemolytic streptococcal upper respiratory infection (ABHS infection), 44 RF cases defined by the Jones criteria and 86 control subjects, who did not satisfy the criteria, were identified for analysis. The median age was 12 years and 60% were female. RF was significantly associated with low income (odds ratio [OR] 2.37; P = 0.04); poor living conditions: substandard (kacha) house (OR 2.93, P = 0.02); and poor nutritional status: low height for age (OR 2.68, P = 0.02). Multiple logistic regression analysis revealed an increased OR for kacha house (OR 3.18, P = 0.02) but the same estimate for low height for age (OR 2.68; P = 0.04). Our analysis shows that, among the patients presenting to the RF hospital with proven ABHS infection, acute RF is associated with socio-economic deprivation.
SUMMARY Animal studies have suggested that spontaneous or programmed ventricular beats that occur simultaneously with atrial activation may facilitate atrioventricular (AV) nodal conduction during subsequent atrial impulses. However, this possibility has not been systematically studied in the human heart. In the present study the AV nodal conduction during a programmed atrial premature beat (S2) was analyzed.The S2 was delivered after a series of atrial drive beats (SjSj) of constant duration; this was termed stimulation method I. The results were compared with stimulation method II, which was similar to method I except that a single ventricular beat (Vs) was introduced simultaneously with the last Sl. The longest and shortest possible paced atrial cycle lengths (CLs) were scanned during both methods. Twenty-six patients were studied: 14 with a normal PR and normal intraventricular conduction (NIVC), four with first-degree AV nodal block and NIVC, three with a complete left bundle branch block (LBBB) pattern, three with a complete right bundle branch block (RBBB) pattern, and two with an incomplete RBBB pattern.At the same SlS2 intervals, the AV nodal conduction times (S2112 intervals) were consistently shorter with method II than with method I except in three patients, two with complete RBBB and one with complete LBBB. The magnitude of S2H2 shortening with method II was more pronounced at the shorter basic CLs and shorter SlS2 intervals. During method I, the effective refractory period (ERP) of the AV node was measured in 13 patients, eight with NIVC and five with preexisting bundle branch block. With method II, the ERP of the AV node shortened in all but three patients (one with complete RBBB, one with incomplete RBBB and one with complete LBBB pattern), in whom this variable did not change. The findings suggest that intranodal collison from antegrade and retrograde impulses facilitates AV nodal conduction and shortens the ERP. The magnitude of this change is greater at shorter atrial CLs and is probably related to deeper intranodal penetration of a Vs. The shortening in AV nodal conduction and refractoriness is not noted in patients with bundle branch block when retrograde conduction delay or block in the bundle branches coexists with the antegrade counterpart producing delayed or ineffective input of Vs into the AV node.ATRIOVENTRICULAR (AV) nodal conduction and refractoriness in the antegrade direction have been extensively investigated in both animals and man.'-'0 Although several studies have addressed the effects of programmed ventricular premature stimulation on subsequent AV nodal conduction in animals,9' 11 rarely has such a study been carried out systematically in the human heart. This study was designed to examine the effect of simultaneous AV stimulation on the functional properties of the AV node in man. Patients and MethodsTwenty-six patients ( ously introduced through the femoral and antecubital veins and were positioned under fluoroscopic guidance, in the region of the tricuspid valve to permit...
Previous work has suggested that at higher absolute ventricular fibrillation voltages (AVFV), the heart is more amenable to defibrillation. This study investigated in a canine model whether voltage integration of the AVFV is associated with the defibrillation success rate. The moving-average filter was used to process the ventricular fibrillation (VF) waveform recorded from Lead II of the electrocardiogram (ECG). In seven animals, defibrillation trials were analyzed using a dc shock (DCS) successful approximately 50% of the time when delivered randomly. For each of a total of 84 DCS (40% successes, 60% failures), the fibrillation waveform just prior to DCS was analyzed. The integration of the AVFV waveform was performed over various sample sizes including 1, 4, 8, 16, 64, and 128 ms, as well as the time equal to the mean VF cycle length. The results suggest that dc shocks delivered at instants of higher values of integrated AVFV over the various window sizes are associated with successful defibrillation. Window sizes less than 16 ms appeared to offer the best discrimination. The integration of AVFV over the entire VF cycle length was significantly higher for successful rather than unsuccessful DCS. This interesting observation is consistent with the clinical observation that "coarse" VF (high AVFV) is easier to defibrillate than "fine" VF (low AVFV). The use of voltage integration of AVFV may have potential implications in the improvement of defibrillation success in implantable devices.
The concept that refractoriness of the His-Purkinje system (HPS) and ventricular muscle both vary directly with cycle length is based on observations during the use of constant cycle length. During abrupt changes in ventricular cycle length, refractoriness of the ventricular muscle is known to reflect the cumulative durations of preceding cycle lengths.
Patients with DDD pacemakers who have intact retrograde conduction are known to be at risk of developing ventricular and "endless loop" tachycardia. To address this problem, a pacing protocol was designed in which V2A2 conduction was assessed in 16 patients during ventricular pacing alone (standard method) and during paced atrioventricular (AV) sequential drive (AV sequential method); the results were then compared. In eight of 16 patients who had intact retrograde conduction with both methods (group 1), the V2A2 intervals were significantly shorter (by 60 to 340 msec) with the AV sequential method. In the remaining eight patients, who demonstrated V2A2 block with the standard method, no V2A2 block occurred with the AV sequential method. In this study, two sets of AV intervals were programmed to produce collision of the two impulses (atrial and ventricular), either in the AV node or the His-Purkinje system (HPS). The site of V2A2 facilitation was related to the site of impulse collision. These results can be explained by earlier excitation by the atrial impulse (of AV node and/or HPS) during AV sequential pacing. However, in some cases it was evident that antegrade propagation of the atrial impulse was responsible for subsequent facilitation. The data suggest that assessment of retrograde conduction in candidates for DDD pacemakers can be made most accurately by the AV sequential method. Circulation 68, No. 1, 23-32, 1983. RESTORATION of normal atrioventricular (AV) synchrony in patients who need permanent pacing is not a new idea. ' However, the development of stable transvenous atrial electrodes2' has rekindled interest in AV sequential pacing. Programmable pacemakers capable of pacing and seinsing both the atrium and ventricle are now available,4 and one highly desirable feature of such pacemakers is the ability to sense the physiologic variations of atrial rate and to pace the ventricle accordingly, i.e., to accomplish atrial tracking (as in DDD, VDD, and VAT modes). The major clinical problem with these devices has been the development of pacemaker tachycardias. These are usually initiated by a premature ventricular beat (PVB), which produces a retrograde P wave. This is sensed and commits the pacemaker to stimulate the ventricle, which in turn produces another retrograde P wave, closing the "loop" and thereby initiating an "endless loop" tachycardia.5-7 A more serious arrhythmia develops when the paced ventricular beat (after a sensed retrograde P wave) falls in the vulnerable period of the initiating PVB, resulting in ventricular tachycardia.8 These complications have led some authors to suggest that intact retrograde (ventriculoatrial, VA) conduction should be considered a relative contraindication for the use of these pacemakers.9 Since intact VA conduction is found in more than 75% of patients receiving constant cycle length ventricular pacing or programmed premature ventricular stimulation,'0 many patients could be denied the use of these versatile pacemakers. Furthermore, the physiologic...
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