Optical method to preserve residual hearing in patients receiving a cochlear implant

Joaquin Cury, Arnaldo Rivera, Rebecca Schneider, Ray Tan, Xiaodong Tan, Claus-Peter Richter
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Abstract

Worldwide, thousands of patients with severe to profound hearing loss restore their hearing with cochlear implant (CI) devices. Newer developments in electrode design and manufacturing and a better understanding of cochlear mechanics allow for conserving critical structures, often translating into serviceable residual hearing and improving device performance. Monitoring insertion speed and intraluminal pressure helps mitigate some of these challenges. However, the information becomes available after irreparable damage has occurred.We developed and tested a high-resolution optical system to navigate the intricate anatomy of the cochlea during electrode insertion. The miniaturized optical system was integrated in conventional cochlear implants electrode arrays and custom-made cochlear probes. Electrode insertion were conducted in eight cadaveric human temporal bones and video recordings were acquired. Micro-computed tomography (μCT) scans were performed to evaluate the position of the modified electrode arrays.Full insertions of the modified CI electrode were successfully conducted and verified by μCT scans. Video recordings of the cochlear structures visible in scala tympani were acquired, and no scala migration was detected.Surgeons can now follow the CI electrode's path during its insertion and reduce cochlear damage through early interventions and steering of the CI electrode. Our device will be compatible with robotic platforms that are already available to insert these electrodes.
保护人工耳蜗植入患者残余听力的光学方法
在全球范围内,成千上万的重度到极重度听力损失患者通过人工耳蜗(CI)设备恢复了听力。电极设计和制造方面的最新发展以及对人工耳蜗力学的更好理解,使得保留关键结构成为可能,这通常可以转化为可用的残余听力并提高设备性能。监测插入速度和腔内压力有助于减轻其中的一些挑战。我们开发并测试了一种高分辨率光学系统,用于在电极插入过程中导航耳蜗复杂的解剖结构。微型光学系统集成在传统人工耳蜗电极阵列和定制的人工耳蜗探头中。在八具尸体颞骨上进行了电极插入,并采集了视频记录。通过微计算机断层扫描(μCT),对改良电极阵列的位置进行了评估。外科医生现在可以在 CI 电极插入过程中跟踪其路径,并通过早期干预和 CI 电极转向来减少耳蜗损伤。我们的设备将与现有的插入这些电极的机器人平台兼容。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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