Considerations for design of future cochlear implant electrode arrays: Electrode array stiffness, size,

Rebscher, Stephen J.; Hetherington, Alexander; Bonham, Ben H.; Wardrop, Peter; Whinney, David; Leake, Patricia A.

doi:10.1682/jrrd.2007.08.0119

Cited by 153 publications

(126 citation statements)

References 43 publications

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“…There are a number of variables related to hearing preservation that need to be clarified and investigated. These variables include electrode design, the use of hair cell protection, electrode insertion depth and the method of electrode insertion, which should be as atraumatic as possible [Ishii et al, 1995;Roland et al, 2005;Rebscher et al, 2008;Verbist et al, 2009]. Until recently, the electrode insertion speed and its impact on insertion characteristics has not been examined in detail, especially in the clinical setting [Majdani et al, 2010].…”

Section: Discussionmentioning

confidence: 99%

The Effects of Insertion Speed on Inner Ear Function during Cochlear Implantation: A Comparison Study

2012

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Objective: To investigate the insertion speed and its impact on electrode insertion characteristics, hearing preservation and clinical vestibular function in a prospective cohort study with a retrospective control group at a tertiary otology/neurotology centre. Interventions: Hearing-preserving cochlear implantation using systemic and topical steroids in conjunction with a round-window approach, a complete cochlear coverage electrode and two different electrode insertion speeds [60 mm/min (n = 18) vs. 15 mm/min (n = 22)] was performed. Results: The insertion speed had a significant impact on various insertion characteristics as well as hearing preservation and vestibular function. In conclusion, a slow electrode insertion speed appears to facilitate full electrode insertion, reduce the occurrence of insertion resistance as well as promote preservation of residual hearing and vestibular function after cochlear implantation.

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Section: Discussionmentioning

confidence: 99%

The Effects of Insertion Speed on Inner Ear Function during Cochlear Implantation: A Comparison Study

2012

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“…In many cases this damage results in decreased coupling efficiency and inconsistent channel-to-channel performance. Analysis of the forces that affect the occurrence of trauma and the angle at which an electrode contacts tissue have identified two primary mechanisms of injury [121][122][123][124][125][126]. First, damage most frequently occurs as a straight electrode, or curved electrode held on a stylet, contacts the outer wall of the scala tympani as it spirals away from the round window or cochleostomy through which the electrode was inserted.…”

Section: A Design Goals For Intracochlear Electrodesmentioning

confidence: 99%

“…In our trials at UCSF surgeons have observed little resistance to insertion and were confident that the electrodes were implanted with little or no trauma. Particularly in cases with the Advanced Bionics HiFocus™ electrode with positioner, subsequent dimensional analysis [127,149 ] and temporal bone evaluations indicate that many, or most, of these insertions exceeded the depth at which the electrode and positioner could be located without trauma. This disparity indicates that it is very difficult to sense the level of resistance that signals the initiation of injury with a large tapered electrode carrier.…”

Section: Insertion Trauma Depth and Electrode Designmentioning

confidence: 99%

Cochlear Implants: System Design, Integration, and Evaluation

Zeng

Rebscher

Harrison³

et al. 2008

IEEE Rev. Biomed. Eng.

652

198

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As the most successful neural prosthesis, cochlear implants have provided partial hearing to more than 120,000 persons worldwide; half of which being pediatric users who are able to develop nearly normal language. Biomedical engineers have played a central role in the design, integration and evaluation of the cochlear implant system, but the overall success is a result of collaborative work with physiologists, psychologists, physicians, educators, and entrepreneurs. This review presents broad yet in-depth academic and industrial perspectives on the underlying research and ongoing development of cochlear implants. The introduction accounts for major events and advances in cochlear implants, including dynamic interplays among engineers, scientists, physicians, and policy makers. The review takes a system approach to address critical issues from design and specifications to integration and evaluation. First, the cochlear implant system design and specifications are laid out. Second, the design goals, principles, and methods of the subsystem components are identified from the external speech processor and radio frequency transmission link to the internal receiver, stimulator and electrode arrays. Third, system integration and functional evaluation are presented with respect to safety, reliability, and challenges facing the present and future cochlear implant designers and users. Finally, issues beyond cochlear implants are discussed to address treatment options for the entire spectrum of hearing impairment as well as to use the cochlear implant as a model to design and evaluate other similar neural prostheses such as vestibular and retinal implants.

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“…Rebscher et al, 15 who tested the insertion damage in correlation to the stiffness of 8 different models of electrode arrays, showed that electrode arrays with proportionately greater stiffness in the vertical plane were less likely to produce severe trauma during insertion. Severe damage, defined as an electrode array dislocation from the scala tympani into the scala media or scala vestibuli, varied in straight electrodes from 0% to 37.5% and in spiral types from 0% to 38.9%.…”

Section: Discussionmentioning

confidence: 99%

“…Electrode arrays designed to position stimulating contacts near the modiolus appear to operate with lower current thresholds than previous devices that were located closer to the lateral wall of the scala tympani. [15][16][17] The charge units of maximum comfortable loudness level of the 2 groups were compared to determine whether an electrode dislocation was associated with higher stimulus charges.…”

Section: Discussionmentioning

confidence: 99%

Radiologic and Functional Evaluation of Electrode Dislocation from the Scala Tympani to the Scala Vestibuli in Patients with Cochlear Implants

Fischer¹,

Pinggera²,

Weichbold

et al. 2014

AJNR Am J Neuroradiol

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BACKGROUND AND PURPOSE:Localization of the electrode after cochlear implantation seems to have an impact on auditory outcome, and conebeam CT has emerged as a reliable method for visualizing the electrode array position within the cochlea. The aim of this retrospective study was to evaluate the frequency and clinical impact of scalar dislocation of various electrodes and surgical approaches and to evaluate its influence on auditory outcome.

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Considerations for design of future cochlear implant electrode arrays: Electrode array stiffness, size,

Cited by 153 publications

References 43 publications

The Effects of Insertion Speed on Inner Ear Function during Cochlear Implantation: A Comparison Study

The Effects of Insertion Speed on Inner Ear Function during Cochlear Implantation: A Comparison Study

Cochlear Implants: System Design, Integration, and Evaluation

Radiologic and Functional Evaluation of Electrode Dislocation from the Scala Tympani to the Scala Vestibuli in Patients with Cochlear Implants

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