A Parylene-Silicon Cochlear Electrode Array with Integrated Position Sensors

Wang, Jianbai; Gulari, Mayurachat Ning; Wise, K.D.

doi:10.1109/iembs.2006.260604

Cited by 12 publications

(9 citation statements)

References 9 publications

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“…The field dielectrics around the intended array substrate are next removed. A 3 lm-thick layer of parylene is now deposited using physical vapor deposition (PVD) at room temperature and is patterned using an oxygen plasma to remove it from the sites and the field portions of the wafer (Wang et al, 2006). The field etch is used to form undercut anchor holes for the parylene in the substrate, mechanically locking it in place and providing additional protection against delamination.…”

Section: Array Fabrication and Circuit Integrationmentioning

confidence: 99%

High-density cochlear implants with position sensing and control

et al. 2008

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Section: Array Fabrication and Circuit Integrationmentioning

confidence: 99%

High-density cochlear implants with position sensing and control

et al. 2008

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“…After patterning the field dielectrics, a deep reactive-ion etch is used to undercut the silicon along the probe edge and create holes (anchors) along important features such as gold pads. The 3-μm-thick conformal parylene coating then wraps the probe and fills the anchor holes, mechanically locking parylene in place [18], [19].…”

Section: Electrode Fabrication Processmentioning

confidence: 99%

“…These performance limitations are imposed by the difficulties in achieving deep insertion in the scala tympani of the cochlea (Fig. 1), by the small number (16)(17)(18)(19)(20)(21)(22) of wires that can be accommodated in the scala tympani, and by the current spreading that occurs due to the physical separation between the sites and the receptors in the modiolus. Ultimately, frequency resolution will likely be determined by this separation and by the effectiveness of multiple sites in shaping the stimulus currents.…”

Section: Introductionmentioning

confidence: 99%

A Thin-Film Cochlear Electrode Array With Integrated Position Sensing

Wang

Wise

2009

J. Microelectromech. Syst.

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A thin-film electrode array with integrated position sensors has been developed for a cochlear prosthesis. The array is designed to minimize tissue damage during array insertion and achieve deep implants that hug the modiolus inside the cochlea. The array is fabricated using bulk micromachining technology and contains embedded polysilicon piezoresistive sensors for wallcontact detection and array-shape recognition. Nine strain gauges are distributed at the tip and along the array, covering the 8-mmlong shank. Each sensor is arranged in a half Wheatstone bridge whose output signal is time multiplexed, amplified (10 or 30 times), and band limited. The equivalent gauge factors are typically about 15, permitting array-tip position to be determined within a 50-μm resolution while providing wall-contact output signals of more than 50 mV at the tip. The arrays use a parylene-silicondielectric-electrode structure, improving flexibility while maintaining enough robustness to facilitate a modiolus-hugging shape defined by a polymeric backing device. Integrated with an articulated position-control device, such arrays are the first step toward providing closed-loop control of array insertion and improved perception of speech and music.[2007-0222]

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“…We subsequently designed and constructed models of steerable electrode arrays that bend by pulling on a strand embedded in them [15], [16]. Wang [11] designed MEMS electrode arrays with embedded sensors for sensing the bending angle during insertion. More recently, [6], [9] designed a two DoF tool for perimodiolar electrode array insertion and with integrated force sensing.…”

Section: Introductionmentioning

confidence: 99%

Algorithms and design considerations for robot assisted insertion of Perimodiolar Electrode Arrays

Pile

Cheung

Zhang

et al. 2011

2011 IEEE International Conference on Robotics and Automation

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This paper evaluates the potential for using robotic assistance for the insertion of commercial Perimodiolar Electrode Arrays (PEA's) that use a stylet and a pre-curved electrode body. We propose an algorithm for coordinated robotic insertion of the pre-curved electrode body and pulling of the stylet in order to provide partial control over the PEA shape. However, for robotic insertion to be a viable option for PEA's, an understanding of the statistical variability of their characteristics is essential. This paper investigates the kinematics of PEA's, their shape variability, and their expected performance during robotic insertion. An investigation of the required number of Degrees of Freedom (DoF) and the workspace is presented. A study of shape variability is carried out for characterizing shape repeatability across different insertion trials using the same electrode array. Also a study of shape variability is carried out between different electrode arrays. We simulate and evaluate the expected performance of three and four DoF robotic instruments for PEA insertion. The results support our proposed algorithm for coordinated insertion of the electrode array body and pulling of the stylet. They show that existing commerical perimodiolar arrays provide good shape repeatability. These results also point to the need for designing robotic insertion tools with at least four DoF. We believe that these results provide guidelines for future robotic instrument design for cochlear implant PEA's.

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A Parylene-Silicon Cochlear Electrode Array with Integrated Position Sensors

Cited by 12 publications

References 9 publications

High-density cochlear implants with position sensing and control

High-density cochlear implants with position sensing and control

A Thin-Film Cochlear Electrode Array With Integrated Position Sensing

Algorithms and design considerations for robot assisted insertion of Perimodiolar Electrode Arrays

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