Effects of Sterilization on Cellobiose Dehydrogenase and Glucose Oxidase Based Glucose Biosensors

Richard Bennett; Arvind Rathore; Sébastien Gounel; Anna Lielpetere; Thomas M.B. Reichhart; Kavita Jayakumar; Roland Ludwig; Alfons K.G. Felice; Dónal Leech; Wolfgang Schuhmann; Andrew Mount; Nicolas Mano; Claudine Boiziau

doi:10.1002/adsr.202400056

Effects of Sterilization on Cellobiose Dehydrogenase and Glucose Oxidase Based Glucose Biosensors

Richard Bennett
, Arvind Rathore
, Sébastien Gounel
, Anna Lielpetere
, Thomas M.B. Reichhart
, Kavita Jayakumar
, Roland Ludwig
, Alfons K.G. Felice
, Dónal Leech
, Wolfgang Schuhmann
, Andrew Mount
, Nicolas Mano
, Claudine Boiziau

School of Biological and Chemical Sciences

Research output: Contribution to a Journal (Peer & Non Peer) › Article › peer-review

2 Citations (Scopus)

Abstract

Research on implantable glucose biosensors is driven by the need for innovative medical devices for continuous glucose monitoring in patients with diabetes mellitus. However, biosensor sterilization is a step that is widely omitted during the process of innovation. To compare the effects of gamma irradiation and chemical treatment with ethylene oxide (carbon microarray electrodes are fabricated, functionalized with glucose oxidizing enzymes (cellobiose dehydrogenase CDH or glucose oxidase GOx), and coated with a specifically designed zwitterionic polymer prior to the sterilization step. Cyclic voltammetry in the presence of 100 mm glucose of the biosensors before and after sterilization shows that gamma irradiation with a low radiation rate (25 kGy, 260 Gy h⁻¹) does not induce a sensor performance loss, unlike the EtO treatment. In addition, no cytotoxic by-products are released after gamma sterilization. Based on these results obtained with both glucose oxidizing enzymes (CDH and GOx), gamma irradiation of the glucose biosensors with a low dose rate is preferable to exposure to EtO for biosensor terminal sterilization.

Original language	English
Article number	2400056
Journal	Advanced Sensor Research
Volume	3
Issue number	11
DOIs	https://doi.org/10.1002/adsr.202400056
Publication status	Published - Nov 2024

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 3 Good Health and Well-being

Keywords

ethylene oxide
gamma irradiation
glucose biosensors
protein conformation
terminal sterilization

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10.1002/adsr.202400056

Cite this

Bennett, R., Rathore, A., Gounel, S., Lielpetere, A., Reichhart, T. M. B., Jayakumar, K., Ludwig, R., Felice, A. K. G., Leech, D., Schuhmann, W., Mount, A., Mano, N., & Boiziau, C. (2024). Effects of Sterilization on Cellobiose Dehydrogenase and Glucose Oxidase Based Glucose Biosensors. Advanced Sensor Research, 3(11), Article 2400056. https://doi.org/10.1002/adsr.202400056

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title = "Effects of Sterilization on Cellobiose Dehydrogenase and Glucose Oxidase Based Glucose Biosensors",

abstract = "Research on implantable glucose biosensors is driven by the need for innovative medical devices for continuous glucose monitoring in patients with diabetes mellitus. However, biosensor sterilization is a step that is widely omitted during the process of innovation. To compare the effects of gamma irradiation and chemical treatment with ethylene oxide (carbon microarray electrodes are fabricated, functionalized with glucose oxidizing enzymes (cellobiose dehydrogenase CDH or glucose oxidase GOx), and coated with a specifically designed zwitterionic polymer prior to the sterilization step. Cyclic voltammetry in the presence of 100 mm glucose of the biosensors before and after sterilization shows that gamma irradiation with a low radiation rate (25 kGy, 260 Gy h−1) does not induce a sensor performance loss, unlike the EtO treatment. In addition, no cytotoxic by-products are released after gamma sterilization. Based on these results obtained with both glucose oxidizing enzymes (CDH and GOx), gamma irradiation of the glucose biosensors with a low dose rate is preferable to exposure to EtO for biosensor terminal sterilization.",

keywords = "ethylene oxide, gamma irradiation, glucose biosensors, protein conformation, terminal sterilization",

author = "Richard Bennett and Arvind Rathore and S{\'e}bastien Gounel and Anna Lielpetere and Reichhart, \{Thomas M.B.\} and Kavita Jayakumar and Roland Ludwig and Felice, \{Alfons K.G.\} and D{\'o}nal Leech and Wolfgang Schuhmann and Andrew Mount and Nicolas Mano and Claudine Boiziau",

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doi = "10.1002/adsr.202400056",

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AU - Bennett, Richard

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AU - Gounel, Sébastien

AU - Lielpetere, Anna

AU - Reichhart, Thomas M.B.

AU - Jayakumar, Kavita

AU - Ludwig, Roland

AU - Felice, Alfons K.G.

AU - Leech, Dónal

AU - Schuhmann, Wolfgang

AU - Mount, Andrew

AU - Mano, Nicolas

AU - Boiziau, Claudine

PY - 2024/11

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N2 - Research on implantable glucose biosensors is driven by the need for innovative medical devices for continuous glucose monitoring in patients with diabetes mellitus. However, biosensor sterilization is a step that is widely omitted during the process of innovation. To compare the effects of gamma irradiation and chemical treatment with ethylene oxide (carbon microarray electrodes are fabricated, functionalized with glucose oxidizing enzymes (cellobiose dehydrogenase CDH or glucose oxidase GOx), and coated with a specifically designed zwitterionic polymer prior to the sterilization step. Cyclic voltammetry in the presence of 100 mm glucose of the biosensors before and after sterilization shows that gamma irradiation with a low radiation rate (25 kGy, 260 Gy h−1) does not induce a sensor performance loss, unlike the EtO treatment. In addition, no cytotoxic by-products are released after gamma sterilization. Based on these results obtained with both glucose oxidizing enzymes (CDH and GOx), gamma irradiation of the glucose biosensors with a low dose rate is preferable to exposure to EtO for biosensor terminal sterilization.

AB - Research on implantable glucose biosensors is driven by the need for innovative medical devices for continuous glucose monitoring in patients with diabetes mellitus. However, biosensor sterilization is a step that is widely omitted during the process of innovation. To compare the effects of gamma irradiation and chemical treatment with ethylene oxide (carbon microarray electrodes are fabricated, functionalized with glucose oxidizing enzymes (cellobiose dehydrogenase CDH or glucose oxidase GOx), and coated with a specifically designed zwitterionic polymer prior to the sterilization step. Cyclic voltammetry in the presence of 100 mm glucose of the biosensors before and after sterilization shows that gamma irradiation with a low radiation rate (25 kGy, 260 Gy h−1) does not induce a sensor performance loss, unlike the EtO treatment. In addition, no cytotoxic by-products are released after gamma sterilization. Based on these results obtained with both glucose oxidizing enzymes (CDH and GOx), gamma irradiation of the glucose biosensors with a low dose rate is preferable to exposure to EtO for biosensor terminal sterilization.

KW - ethylene oxide

KW - gamma irradiation

KW - glucose biosensors

KW - protein conformation

KW - terminal sterilization

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DO - 10.1002/adsr.202400056

M3 - Article

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JF - Advanced Sensor Research

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ER -

Effects of Sterilization on Cellobiose Dehydrogenase and Glucose Oxidase Based Glucose Biosensors

Abstract

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Keywords

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