📝 SummarXiv

Abstract

CSP is gaining clinical significance owing to its ability to restore a physiological activation sequence in the ventricles. While His bundle pacing (HBP) producing the most physiological activation is preferable, due to implant complications the selective activation of the LBB by left bundle branch area pacing (LBBAP) is considered an alternative, offering both a simpler implant and a physiological activation sequence. However, the physical mechanisms facilitating selective activation of the LBB remain poorly understood. We developed a structurally and biophysically detailed computer model of the IVS and LBB to quantitatively elucidate the role of lead position, orientation and polarity in achieving optimal s-LBBP thresholds, using a geometrically detailed model of a clinically widely used CSP lead. A deep implant within the LV sub-endocardium ensuring a direct contact between electrode and LBB is key for effective s-LBBP. For low strength s-LBBP is feasible, but capturing the LBB in its entirety could only be achieved using higher strengths that led to non-selective left bundle branch pacing (ns-LBBP). Switching the tip polarity to anodal was not beneficial, requiring higher strengths to activate the LBB. Lead orientation relative to the LBB bundles was found to influence the s-LBBP capture threshold and the number of synchronously activating bundles. The model explains the impedance trends that are clinically observed when advancing the tip through the IVS into the LBB region, as well as sudden impedance drops associated with implant complications such as septal perforation or lead dislodgement. Quantitative consistence with clinically observed trends support model credibility, and indicate that simulation may offer an effective approach for guiding the design of improved CSP leads, facilitating a selective and synchronous activation of the entire LBB.