Technical Pearls: Nerve-Sparing

Hung-Jen WangTaiwan Speaker Technical Pearls: Nerve-SparingPreserving the neurovascular bundles (NVB) during robotic-assisted radical prostatectomy (RARP) is crucial for maintaining postoperative continence and sexual function, while still ensuring complete cancer removal. We will share "technical pearls" for nerve-sparing in RARP, emphasizing practical innovations that enhance surgical precision without compromising oncologic control. Retrograde nerve-sparing involves a bottom-up (apex-to-base) dissection of the NVB using an athermal, gentle approach. This technique, adapted from open surgery, allows early identification and release of the nerves under direct vision. By minimizing traction and avoiding cautery near the NVB, it reduces inadvertent nerve injury and even lowers the risk of positive margins at the prostatic base. Clinically, adopting a retrograde approach (often with 30° lens “toggling”) has been linked to faster functional recovery of potency, contributing to potency rates approaching 90% at 1 year in fully nerve-sparing cases. Parallel advances in augmented reality (AR) are providing real-time surgical navigation. AR technology superimposes 3D virtual models (e.g. from MRI) onto the operative field, enhancing visualization of patient-specific anatomy. Surgeons can pinpoint tumor location relative to the NVB, enabling selective, confidence-guided nerve preservation even in locally advanced disease. This approach helps modulate nerve-sparing extent on a case-by-case basis, maintaining oncologic safety (low positive surgical margin rates) while maximizing nerve preservation. Finally, refined anatomical landmarks have emerged to guide nerve-sparing. A notable example is the identification of a consistent small arterial branch (“landmark artery”) at the NVB’s medial aspect. This vessel serves as a guide for partial nerve-sparing: dissecting just lateral to it yields an approximate 3 mm tissue margin from the prostatic capsule, sufficient to clear potential extracapsular extension while preserving the remaining nerve fibers. Such landmark-oriented dissection provides a reproducible framework for tailoring nerve-sparing to tumor risk, moving beyond the traditional “all-or-none” approach. These advanced techniques and concepts are empowering robotic surgeons to achieve optimal outcomes. By integrating retrograde nerve-sparing, AR-assisted navigation, and anatomical landmark guidance, one can improve early continence recovery and postoperative sexual function for patients without sacrificing cancer control.