Surgical approach to the facial recess influences the acceptable trajectory of cochlear implantation electrodes

Bridget Copson; Sudanthi Wijewickrema; Xingjun Ma; Yun Zhou; Jean-Marc Gerard; Stephen O'Leary

doi:10.1007/s00405-021-06633-8

Surgical approach to the facial recess influences the acceptable trajectory of cochlear implantation electrodes

Eur Arch Otorhinolaryngol. 2022 Jan;279(1):137-147. doi: 10.1007/s00405-021-06633-8. Epub 2021 Feb 5.

Authors

Bridget Copson¹, Sudanthi Wijewickrema², Xingjun Ma², Yun Zhou², Jean-Marc Gerard², Stephen O'Leary²

Affiliations

¹ Department of Surgery (Otolaryngology), University of Melbourne, Level 5, Royal Victorian Eye and Ear Hospital, 32, Gisborne Street, East Melbourne, VIC, 3002, Australia. bcopson@student.unimelb.edu.au.
² Department of Surgery (Otolaryngology), University of Melbourne, Level 5, Royal Victorian Eye and Ear Hospital, 32, Gisborne Street, East Melbourne, VIC, 3002, Australia.

PMID: 33547488
DOI: 10.1007/s00405-021-06633-8

Abstract

Purpose: To provide practical guidance to the operative surgeon by mapping the location, where acceptable straight-line virtual cochlear implant electrode trajectories intersect the facial recess. In addition, to investigate the influence of facial recess preparation, virtual electrode width and surgical approach to the cochlea on these available trajectories.

Methods: The study was performed on imaging data from eight cadaveric temporal bones within the University of Melbourne Virtual Reality (VR) Temporal Bone Surgery Simulator. The facial recess was opened to varying degrees, and acceptable trajectory vectors with varying diameters were calculated for electrode insertions via cochleostomy or round window membrane (RWM). The percentage of acceptable insertion vectors through each location of the facial recess was visually represented using heatmaps.

Results: Seven of the eight bones allowed for acceptable vector trajectories via both cochleostomy and RWM approaches. These acceptable trajectories were more likely to lie superiorly within the facial recess for insertion via the round window, and inferiorly for insertion via cochleostomy. Cochleostomy insertions required a greater degree of preparation and skeletonisation of the junction of the facial nerve and chorda tympani within the facial recess. The width of the virtual electrode had only marginal impact on the availability of acceptable trajectories. Heatmaps emphasised the intimate relationship the acceptable trajectories have with the facial nerve and chorda tympani.

Conclusion: These findings highlight the differences in the acceptable straight-line trajectories for electrodes when implanted via the round window or cochleostomy. There were notable exceptions to both surgical approaches, likely explained by the variation of hook region anatomy. The methodology used in this study holds promise for translation to patient specific surgical planning.

Keywords: Cochlear implant; Electrode insertion trajectory; Electrode insertion vector; Optimal facial recess; Optimal insertion vector; Surgical training; Temporal bone surgery.

MeSH terms

Cochlea / surgery
Cochlear Implantation*
Cochlear Implants*
Electrodes, Implanted
Humans
Round Window, Ear / surgery
Temporal Bone / diagnostic imaging
Temporal Bone / surgery