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  3. Robotic Milling of Electrode Lead Channels During Cochlear Implantation in an ex-vivo Model.
 

Robotic Milling of Electrode Lead Channels During Cochlear Implantation in an ex-vivo Model.

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BORIS DOI
10.48350/161865
Date of Publication
2021
Publication Type
Article
Division/Institute

ARTORG Center - Chair...

ARTORG Center for Bio...

Author
Hermann, Jan
ARTORG Center for Biomedical Engineering Research
ARTORG Center - Chair for Image Guided Therapy (IGT)
Müller, Fabian Matthias
ARTORG Center - Chair for Image Guided Therapy (IGT)
Schneider, Daniel
ARTORG Center - Chair for Image Guided Therapy (IGT)
O'Toole Bom Braga, Gabriela
ARTORG Center - Chair for Image Guided Therapy (IGT)
ARTORG Center for Biomedical Engineering Research
Weber, Stefan
ARTORG Center - Chair for Image Guided Therapy (IGT)
Subject(s)

500 - Science::570 - ...

600 - Technology::610...

600 - Technology::620...

Series
Frontiers in Surgery
ISSN or ISBN (if monograph)
2296-875X
Publisher
Frontiers
Language
English
Publisher DOI
10.3389/fsurg.2021.742147
PubMed ID
34859039
Uncontrolled Keywords

electrode fixation el...

Description
Objective: Robotic cochlear implantation is an emerging surgical technique for patients with sensorineural hearing loss. Access to the middle and inner ear is provided through a small-diameter hole created by a robotic drilling process without a mastoidectomy. Using the same image-guided robotic system, we propose an electrode lead management technique using robotic milling that replaces the standard process of stowing excess electrode lead in the mastoidectomy cavity. Before accessing the middle ear, an electrode channel is milled robotically based on intraoperative planning. The goal is to further standardize cochlear implantation, minimize the risk of iatrogenic intracochlear damage, and to create optimal conditions for a long implant life through protection from external trauma and immobilization in a slight press fit to prevent mechanical fatigue and electrode migrations. Methods: The proposed workflow was executed on 12 ex-vivo temporal bones and evaluated for safety and efficacy. For safety, the difference between planned and resulting channels were measured postoperatively in micro-computed tomography, and the length outside the planned safety margin of 1.0 mm was determined. For efficacy, the channel width and depth were measured to assess the press fit immobilization and the protection from external trauma, respectively. Results: All 12 cases were completed with successful electrode fixations after cochlear insertions. The milled channels stayed within the planned safety margins and the probability of their violation was lower than one in 10,000 patients. Maximal deviations in lateral and depth directions of 0.35 and 0.29 mm were measured, respectively. The channels could be milled with a width that immobilized the electrode leads. The average channel depth was 2.20 mm, while the planned channel depth was 2.30 mm. The shallowest channel depth was 1.82 mm, still deep enough to contain the full 1.30 mm diameter of the electrode used for the experiments. Conclusion: This study proposes a robotic electrode lead management and fixation technique and verified its safety and efficacy in an ex-vivo study. The method of image-guided robotic bone removal presented here with average errors of 0.2 mm and maximal errors below 0.5 mm could be used for a variety of other otologic surgical procedures.
Handle
https://boris-portal.unibe.ch/handle/20.500.12422/57994
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fsurg-08-742147.pdftextAdobe PDF4.65 MBAttribution (CC BY 4.0)publishedOpen
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