Robotics, automation, active electrode arrays, and new devices for cochlear implantation: A contemporary review

•Postoperative inner ear structure preservation ensures better auditory outcomes.•Several new tools have been developed to improve the different steps in CI surgery.•Direct cochlear access provides a mini-invasive approach to the inner ear.•Robotic cochlear implantation potentially reduces the inser...

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Veröffentlicht in:Hearing research 2022-02, Vol.414, p.108425-108425, Article 108425
Hauptverfasser: De Seta, Daniele, Daoudi, Hannah, Torres, Renato, Ferrary, Evelyne, Sterkers, Olivier, Nguyen, Yann
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Sprache:eng
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Zusammenfassung:•Postoperative inner ear structure preservation ensures better auditory outcomes.•Several new tools have been developed to improve the different steps in CI surgery.•Direct cochlear access provides a mini-invasive approach to the inner ear.•Robotic cochlear implantation potentially reduces the insertion related intracochlear trauma.•Image guided surgery plays a central role in robotic cochlear implantation. In the last two decades, cochlear implant surgery has evolved into a minimally invasive, hearing preservation surgical technique. The devices used during surgery have benefited from technological advances that have allowed modification and possible improvement of the surgical technique. Robotics has recently gained popularity in otology as an effective tool to overcome the surgeon's limitations such as tremor, drift and accurate force control feedback in laboratory testing. Cochlear implantation benefits from robotic assistance in several steps during the surgical procedure: (i) during the approach to the middle ear by automated mastoidectomy and posterior tympanotomy or through a tunnel from the postauricular skin to the middle ear (i.e. direct cochlear access); (ii) a minimally invasive cochleostomy by a robot-assisted drilling tool; (iii) alignment of the correct insertion axis on the basal cochlear turn; (iv) insertion of the electrode array with a motorized insertion tool. In recent years, the development of bone-attached parallel robots and image-guided surgical robotic systems has allowed the first successful cochlear implantation procedures in patients via a single hole drilled tunnel. Several other robotic systems, new materials, sensing technologies applied to the electrodes, and smart devices have been developed, tested in experimental models and finally some have been used in patients with the aim of reducing trauma in cochleostomy, and permitting slow and more accurate insertion of the electrodes. Despite the promising results in laboratory tests in terms of minimal invasiveness, reduced trauma and better hearing preservation, so far, no clinical benefits on residual hearing preservation or better speech performance have been demonstrated. Before these devices can become the standard approach for cochlear implantation, several points still need to be addressed, primarily cost and duration of the procedure. One can hope that improvement in the cost/benefit ratio will expand the technology to every cochlear implantation procedure. Laboratory
ISSN:0378-5955
1878-5891
DOI:10.1016/j.heares.2021.108425