In-device enzyme immobilization: Wafer-level fabrication of an integrated glucose sensor

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  • University of California at Berkeley
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OriginalspracheEnglisch
Seiten (von - bis)163-173
Seitenumfang11
FachzeitschriftSensors and Actuators, B: Chemical
Jahrgang99
Ausgabenummer1
PublikationsstatusVeröffentlicht - 5 Aug. 2004
Extern publiziertJa

Abstract

Wafer-level fabrication of integrated enzyme-based BioMEMS usually requires high temperature wafer-bonding techniques such as anodic bonding. Enzymes denature at comparatively low temperatures. Thus, enzymes need to be immobilized after wafer bonding. A convenient in-device immobilization method is presented allowing wafer-level patterning of enzymes inside micro-scale flow channels after wafer bonding. Enzymes are entrapped in a poly(vinyl alcohol)- styrylpyridinium (PVA-SbQ) membrane crosslinked by UV exposure through a transparent top wafer. The reaction kinetics of immobilized glucose oxidase is investigated in more detail. A low apparent Michaelis constant of 3.0mM is determined indicating a rapid diffusion of glucose into the PVA-SbQ membrane as well as an oxygen-limited maximum catalytic rate. The entrapped glucose oxidase preserves its native properties since it is not chemically modified. Furthermore, the active PVA-SbQ membrane can be dehydrated in a vacuum and later rehydrated in buffer solution without significant loss of enzyme activity. An integrated enzyme-based glucose sensor fabricated on a wafer-level using in-device immobilization is described to demonstrate the potential of this novel technique. The sensor is part of a disposable microneedle-based continuous glucose monitor. The stability of glucose oxidase entrapped in PVA-SbQ is sufficient to continuously operate the sensor at 25°C for 24h.

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In-device enzyme immobilization: Wafer-level fabrication of an integrated glucose sensor. / Zimmermann, Stefan; Fienbork, Doerte; Flounders, Albert W. et al.
in: Sensors and Actuators, B: Chemical, Jahrgang 99, Nr. 1, 05.08.2004, S. 163-173.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Zimmermann S, Fienbork D, Flounders AW, Liepmann D. In-device enzyme immobilization: Wafer-level fabrication of an integrated glucose sensor. Sensors and Actuators, B: Chemical. 2004 Aug 5;99(1):163-173. doi: 10.1016/S0925-4005(03)00552-5
Zimmermann, Stefan ; Fienbork, Doerte ; Flounders, Albert W. et al. / In-device enzyme immobilization : Wafer-level fabrication of an integrated glucose sensor. in: Sensors and Actuators, B: Chemical. 2004 ; Jahrgang 99, Nr. 1. S. 163-173.
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abstract = "Wafer-level fabrication of integrated enzyme-based BioMEMS usually requires high temperature wafer-bonding techniques such as anodic bonding. Enzymes denature at comparatively low temperatures. Thus, enzymes need to be immobilized after wafer bonding. A convenient in-device immobilization method is presented allowing wafer-level patterning of enzymes inside micro-scale flow channels after wafer bonding. Enzymes are entrapped in a poly(vinyl alcohol)- styrylpyridinium (PVA-SbQ) membrane crosslinked by UV exposure through a transparent top wafer. The reaction kinetics of immobilized glucose oxidase is investigated in more detail. A low apparent Michaelis constant of 3.0mM is determined indicating a rapid diffusion of glucose into the PVA-SbQ membrane as well as an oxygen-limited maximum catalytic rate. The entrapped glucose oxidase preserves its native properties since it is not chemically modified. Furthermore, the active PVA-SbQ membrane can be dehydrated in a vacuum and later rehydrated in buffer solution without significant loss of enzyme activity. An integrated enzyme-based glucose sensor fabricated on a wafer-level using in-device immobilization is described to demonstrate the potential of this novel technique. The sensor is part of a disposable microneedle-based continuous glucose monitor. The stability of glucose oxidase entrapped in PVA-SbQ is sufficient to continuously operate the sensor at 25°C for 24h.",
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T2 - Wafer-level fabrication of an integrated glucose sensor

AU - Zimmermann, Stefan

AU - Fienbork, Doerte

AU - Flounders, Albert W.

AU - Liepmann, Dorian

N1 - Funding information: The Alexander von Humboldt Foundation and the DARPA BioFlips program have funded this research project.

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N2 - Wafer-level fabrication of integrated enzyme-based BioMEMS usually requires high temperature wafer-bonding techniques such as anodic bonding. Enzymes denature at comparatively low temperatures. Thus, enzymes need to be immobilized after wafer bonding. A convenient in-device immobilization method is presented allowing wafer-level patterning of enzymes inside micro-scale flow channels after wafer bonding. Enzymes are entrapped in a poly(vinyl alcohol)- styrylpyridinium (PVA-SbQ) membrane crosslinked by UV exposure through a transparent top wafer. The reaction kinetics of immobilized glucose oxidase is investigated in more detail. A low apparent Michaelis constant of 3.0mM is determined indicating a rapid diffusion of glucose into the PVA-SbQ membrane as well as an oxygen-limited maximum catalytic rate. The entrapped glucose oxidase preserves its native properties since it is not chemically modified. Furthermore, the active PVA-SbQ membrane can be dehydrated in a vacuum and later rehydrated in buffer solution without significant loss of enzyme activity. An integrated enzyme-based glucose sensor fabricated on a wafer-level using in-device immobilization is described to demonstrate the potential of this novel technique. The sensor is part of a disposable microneedle-based continuous glucose monitor. The stability of glucose oxidase entrapped in PVA-SbQ is sufficient to continuously operate the sensor at 25°C for 24h.

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