Implantable enzyme amperometric biosensors

▸ Development techniques of implantable amperometric enzyme biosensors are reviewed. ▸ The known failure modes of biosensors are a starting point for research. ▸ Design of device-to-tissue interfaces is key to long duration implantation. ▸ Biosmart materials are essential for maintaining desired bio...

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Veröffentlicht in:Biosensors & bioelectronics 2012-05, Vol.35 (1), p.14-26
Hauptverfasser: Kotanen, Christian N., Moussy, Francis Gabriel, Carrara, Sandro, Guiseppi-Elie, Anthony
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Sprache:eng
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Zusammenfassung:▸ Development techniques of implantable amperometric enzyme biosensors are reviewed. ▸ The known failure modes of biosensors are a starting point for research. ▸ Design of device-to-tissue interfaces is key to long duration implantation. ▸ Biosmart materials are essential for maintaining desired bioanalytical performance. ▸ Systems integration to minimize device footprint is paramount for implantable. The implantable enzyme amperometric biosensor continues as the dominant in vivo format for the detection, monitoring and reporting of biochemical analytes related to a wide range of pathologies. Widely used in animal studies, there is increasing emphasis on their use in diabetes care and management, the management of trauma-associated hemorrhage and in critical care monitoring by intensivists in the ICU. These frontier opportunities demand continuous indwelling performance for up to several years, well in excess of the currently approved seven days. This review outlines the many challenges to successful deployment of chronically implantable amperometric enzyme biosensors and emphasizes the emerging technological approaches in their continued development. The foreign body response plays a prominent role in implantable biotransducer failure. Topics considering the approaches to mitigate the inflammatory response, use of biomimetic chemistries, nanostructured topographies, drug eluting constructs, and tissue-to-device interface modulus matching are reviewed. Similarly, factors that influence biotransducer performance such as enzyme stability, substrate interference, mediator selection and calibration are reviewed. For the biosensor system, the opportunities and challenges of integration, guided by footprint requirements, the limitations of mixed signal electronics, and power requirements, has produced three systems approaches. The potential is great. However, integration along the multiple length scales needed to address fundamental issues and integration across the diverse disciplines needed to achieve success of these highly integrated systems, continues to be a challenge in the development and deployment of implantable amperometric enzyme biosensor systems.
ISSN:0956-5663
1873-4235
DOI:10.1016/j.bios.2012.03.016