A Prospective, Patient Blinded, Cross-over Study of the Effect on Clinical Outcomes of AV Optimization in All Comer Ambulatory Patients With a Dual Chamber Pacemaker - The Role of Atrial Function and Interatrial Conduction Delay

Brief Summary

Detailed Description

Given the high prevalence of interatrial block (WHO definition: PWD on surface ECG \> 110 ms) in a general hospitalized population and especially in patient groups with tachyarrhythmias (18% and 52 % respectively), this phenomenon will be important to recognize in a BIC pacemaker patient population. Actually, the prevalence of advanced interatrial block (PWD \> 120 ms with biphasic P wave morphology) is 10% in candidates for definitive pacing and 32 % in patients with a bradycardia-tachycardia syndrome. The main underlying mechanism is thought to lie in abnormalities of the Bachmann bundle resulting in partial or advanced interatrial conduction delay (IACD). A normal IACD varies between 60 and 85 ms. Two potential mechanisms are spatial dispersion of refractory periods or anisotropy resulting from scarce side-to-side electrical coupling and fibrosis disrupting the arrangement of atrial muscle fibers. Patients with an interatrial conduction delay may have a suboptimal left atrioventricular timing due to delayed contraction of the left atrium with foreshortening of ventricular filling. This may be an issue in pacemaker patients, with our without a substrate for heart failure. Beside the loss of reduction of left atrial contraction, it might even induce neurohormonal changes due to atrial stretch and pressure thus lowering blood pressure. Coronary sinus or multisite atrial pacing, both with the aim of synchronizing right and left atrial electrical activation, have shown to (i) improve hemodynamics in patients with an important IACD, both invasively and noninvasively, and to (ii) decrease recurrences of atrial fibrillation. In patients with a conventional BIC pacemaker, prevention of left atrioventricular asynchrony can be achieved by AV optimization (lengthening of the AV delay in case of too short nominal settings) as an alternative. Though all these interventions have proven to have positive hemodynamic results until now evidence about positive effects on clinical patient outcomes are lacking. On the other hand, some of the patients implanted with a bicameral pacemaker have a too long AV delay. As a consequence diastolic filling time is impaired. Without compromising left atrioventricular synchrony AV delay, optimal AVD (AVO) can be achieved by lengthening of the AVD with conventional methods. In contrast to the setting of CRT, AV optimization in patients with a bicameral (BIC) pacemaker is not fully implemented in daily clinical practice. Given the proven effect on mitral inflow on echocardiography, we wanted to evaluate the effect of this non invasive intervention on patient functionality and quality of life, based on a comprehensive assessment of atrial pathophysiology.

Primary Outcomes

Secondary Outcomes

• Change in exercise capacity, expressed by VO2max (maximal oxygen consumption)(baseline, 4 weeks, 8 weeks)
• Change in quality of life(baseline, 4 weeks, 8 weeks)
• Change in left atrial function, measured by left atrial late diastolic peak strain (εm)(baseline, 4 weeks, 8 weeks)
• Change in systolic pulmonary artery pressure (PAPs)(baseline, 4 weeks, 8 weeks)
• Change in NYHA class: New York Heart Association Class(baseline, 4 weeks, 8 weeks)
• Change in left atrial function, measured by left mitral annular late diastolic peak velocity (A'm(c))(baseline, 4 weeks, 8 weeks)
• Change in 6-Minute Walk test Distance (6MWD)(baseline, 4 weeks, 8 weeks)
• Change in serum brain natriuretic peptide (BNP)(4 weeks, 8 weeks)
• Change in left atrial function, measured by left atrial late diastolic peak strain rate (SRm)(baseline, 4 weeks, 8 weeks)