Evaluation of MEMS Materials of Construction for Implantable Medical Devices

Overview

Journal Biomaterials

Specialty Biomedical Engineering

Date 2002 Jun 13

PMID 12059024

Citations 65

Authors

Geoffrey Kotzar

Mark Freas

Phillip Abel

Aaron Fleischman

Shuvo Roy

Christian Zorman

James M Moran

Jeff Melzak

Affiliations

Soon will be listed here.

Abstract

Medical devices based on microelectro-mechanical systems (MEMS) platforms are currently being proposed for a wide variety of implantable applications. However, biocompatibility data for typical MEMS materials of construction and processing, obtained from standard tests currently recognized by regulatory agencies, has not been published. Likewise, the effects of common sterilization techniques on MEMS material properties have not been reported. Medical device regulatory requirements dictate that materials that are biocompatibility tested be processed and sterilized in a manner equivalent to the final production device. Material, processing, and sterilization method can impact the final result. Six candidate materials for implantable MEMS devices, and one encapsulating material, were fabricated using typical MEMS processing techniques and sterilized. All seven materials were evaluated using a baseline battery of ISO 10993 physicochemical and biocompatibility tests. In addition, samples of these materials were evaluated using a scanning electron microscope (SEM) pre- and post-sterilization. While not addressing all facets of ISO 10993 testing, the biocompatibility and SEM data indicate few concerns about use of these materials in implant applications.

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