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Microsystem Technologies
Erschienen in: Microsystem Technologies 2/2017

17.11.2016 | Technical Paper

Fabrication of a MEMS retinal tack and long-term in vivo biocompatibility evaluation for retinal prostheses

verfasst von: Sangmin Lee, Hyoungho Ko

Erschienen in: Microsystem Technologies | Ausgabe 2/2017

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Abstract

A silicon and PMMA (poly-(methyl methacrylate)) retinal tack with barbs is developed for retinal prostheses. The MEMS retinal tack presented in this paper has barbs, which are intended for the fixation of the epiretinal-type retina-stimulating microelectrode array. Although conventional retinal tacks made of titanium are available, they are expensive, invasive, and restricted in shape. The silicon retinal tack is fabricated using silicon micromachining, and the PMMA retinal tack is fabricated by X-ray lithography for accurate micro-patterning, which is very scalable and is suitable for inexpensive and repeatable mass production. In this paper, long-term in vivo biocompatibility evaluation of silicon and PMMA retinal tacks is presented. The MEMS retina tack is implanted with epiretinal microelectrodes onto the retinal surface of the rabbit eye and harvested after 1 year for the silicon retinal tack and 6 months for the PMMA retinal tack. Through histological examination, no inflammatory infiltrates in retina, choroid, nor sclera are revealed. Scanning electron microscope (SEM) images show no chemical reaction trace nor mechanical fracture of the implanted device. The results indicate that both silicon and PMMA retinal tacks are suitable for mechanical fixation of microelectrode arrays. Also, the long-term evaluation of the durability in vivo shows acceptable biocompatibility for further use in retinal prostheses.
Vorheriger Artikel Electrical characterization of 2D and 3D microelectrodes for achieving high-resolution sensing in retinal prostheses with in vitro animal experimental results
Nächster Artikel Top-down fabrication of silicon-nanowire arrays for large-scale integration on a flexible substrate for achieving high-resolution neural microelectrodes

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Literatur
Asakawa K, Ishikawa H, Uga S, Mashimo K, Kondo M, Terasaki H (2016) Histopathological changes of inner retina, optic disc, and optic nerve in rabbit with advanced retinitis pigmentosa. Neuro Ophthalmol 1:1–6
Chou N, Byun B, Kim S (2014) MEMS-based microelectrode technologies capable of penetrating neural tissues. Biomed Eng Lett 4(2):109–119CrossRef
Chung H, Seo J-M, Paik S-J, Cho D, Kim E, Kim S, Kim K, Heo J, Yu HG, Yu YS (2004) Epiretinal fixation of the polyimide electrode array using silicon retinal tack. Invest Ophthalmol Vis Sci ARVO Annu Meet Abstr 45(13):4182
Chung H, Paik S, Lee A, Seo J-M, Kim E, Lim J, Cho D, Kim S, Yu H, Yu YS (2005) Revised Silicon Retinal Tack for Epiretinal Fixation of the Electrode. Invest Ophthalmol Vis Sci ARVO Annu Meet Abstr 46(13):1514
Chung H, Koo K-I, Lee S, Bae SH, Ban J, Jeong H, Park H, Hong S, Seo J-M, Cho D (2010) Interpretation of the optical coherent tomographic findings in the rabbit eye with implanted PMMA retinal tack for retinal prosthesis. Investigative Ophthalmology & Visual Science (ARVO Annual Meeting Abstract) 51(13):3050
Cogan SF (2008) Neural stimulation and recording electrodes. Annu Rev Biomed Eng 10:275–309CrossRef
Congdon N, O’Colmain B, Klaver CC, Klein R, Munoz B, Friedman DS, Kempen J, Taylor HR, Mitchell P (2004) Causes and prevalence of visual impairment among adults in the United States. Arch Ophthalmol 122:477–485CrossRef
Hartong DT, Berson EL, Dryja TP (2006) Retinitis pigmentosa. Lancet 368(9549):1795–1809CrossRef
Humayun MS, de Juan Jr E, Dagnelie G (2016) The Bionic Eye: A Quarter Century of Retinal Prosthesis Research and Development. Ophthalmology 123(10):S89–S97CrossRef
Jones BW, Pfeiffer RL, Ferrell WD, Watt CB, Marmor M, Marc RE (2016) Retinal remodeling in human retinitis pigmentosa. Exp Eye Res 150:149–165CrossRef
Kim MT, Son J, Cho CH, Park CM, Kim KG (2012) Quantitative analysis of applied force on biopsy needle insertions. Biomed Eng Lett 2(4):249–254CrossRef
Kim R, Joo S, Jung H, Hong N, Nam Y (2014a) Recent trends in microelectrode array technology for in vitro neural interface platform. Biomed Eng Lett 4(2):129–141CrossRef
Kim J, Lee M, Rhim JS, Wang P, Lu N, Kim D (2014b) Next-generation flexible neural and cardiac electrode arrays. Biomed Eng Lett 4(2):95–108CrossRef
Lee S, Koo KI, Ha S, Ban J, Jeong H, Park H, Seo JM, Chung H, Cho D (2009) PMMA retinal tack with barb-shaped scale bars for retinal prosthesis. Invest Ophthalmol Vis Sci ARVO Annu Meet Abstr 50(13):4232
Lee S, Koo K-I, Ban J, Jeong H, Park H, Hong S, Bae SH, Seo J-M, Chung H, Cho D (2010) A long-term in vivo biocompatibility evaluation of PMMA retinal tack for retinal prosthesis. Invest Ophthalmol Vis Sci ARVO Annu Meet Abstr 51(13):3044
Meyer JU (2002) Retina implant—a bioMEMS challenge. Sens Actuators A 97:1–9CrossRef
Paik S, Cho D, Seo SM, Lim J, Park Y, Byun S, Kim S (2003) Development of silicon-micromachined retinal tacks for artificial retina implantation. Proceedings of 1st International IEEE EMBS Conference on Neural Engineering. pp 185–188
Paik S, Byun S, Lim J, Park Y, Lee A, Chung S, Chang J, Chun K, Cho D (2004) In-plane single-crystal-silicon microneedles for minimally invasive microfluid systems. Sens Actuators A 114(2):276–284CrossRef
Rizzo JF (2011) Update on retinal prosthetic research: the Boston Retinal Implant Project. J Neuro Ophthalomol 31(2):160–168CrossRef
Seo JM, Paik SJ, Kim ET, Byun SW, Lee AR, Cho D, Kim SJ, Yu HG, Yu YS, Chung H (2006) Silicon retinal tack for the epiretinal fixation of the polyimide electrode array. Curr Appl Phys 6:649–653CrossRef
Song J, Lee S, Jung S, Cha G, Mun M (2009) Improved biocompatibility of parylene-C films prepared by chemical vapor deposition and the subsequent plasma treatment. J Appl Polym Sci 112(6):3677–3685CrossRef
Stone JL, Barlow WE, Humayun MS, de Juan Jr E, Milam AH (1992) Morphometric analysis of macular photoreceptors and ganglion cells in retinas with retinitis pigmentosa. Arch Ophthalmol 110(11):1634CrossRef
Zarbin MA (2004) Current concepts in the pathogenesis of age-related macular degeneration. Arch Ophthalmol 122(4):598–614CrossRef
Metadaten
Titel
Fabrication of a MEMS retinal tack and long-term in vivo biocompatibility evaluation for retinal prostheses
verfasst von
Sangmin Lee
Hyoungho Ko
Publikationsdatum
17.11.2016
Verlag
Springer Berlin Heidelberg
Erschienen in
Microsystem Technologies / Ausgabe 2/2017
Print ISSN: 0946-7076
Elektronische ISSN: 1432-1858
DOI
https://doi.org/10.1007/s00542-016-3201-z

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