Highly sensitive glucose biosensor using new glucose oxidase based biocatalyst

Glucose, which is a primary energy source of living organisms, can induce diabetes or hypoglycemia if its concentration in blood is irregular. It is therefore important to develop glucose biosensor that reads the concentration of glucose in blood precisely. In the present work, we suggest new glucos...

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Published in	The Korean journal of chemical engineering Vol. 34; no. 11; pp. 2916 - 2921
Main Authors	Christwardana, Marcelinus, Ji, Jungyeon, Chung, Yongjin, Kwon, Yongchai
Format	Journal Article
Language	English
Published	New York Springer US 01.11.2017 Springer Nature B.V 한국화학공학회
Subjects	Ascorbic acid Biosensors Biotechnology Carbon nanotubes Catalysis Catalysts Catalytic activity Chemical synthesis Chemistry Chemistry and Materials Science Diabetes mellitus Electron transport Glucose Glucose oxidase Hydrophobicity Hypoglycemia Industrial Chemistry/Chemical Engineering Materials Science Nanotubes Polyethyleneimine Selectivity Sensitivity analysis Stability analysis Uric acid 화학공학 Glucose Oxidase Pyrenecarboxaldehyde Diabetes Glucose Biosensor Hypoglycemia
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Abstract	Glucose, which is a primary energy source of living organisms, can induce diabetes or hypoglycemia if its concentration in blood is irregular. It is therefore important to develop glucose biosensor that reads the concentration of glucose in blood precisely. In the present work, we suggest new glucose oxidase (GOx) based catalysts that can improve the sensitivity of the glucose biosensor and make glucose measurements over a wide concentration ranges possible. For synthesizing such catalysts, a composite including pyrenecarboxaldehyde (PCA) and GOx is attached to substrate including carbon nanotube (CNT) and polyethyleneimine (PEI) (CNT/PEI/[PCA/GOx]). Catalytic activity and stability of the catalyst are then evaluated. According to the investigation, the catalyst shows excellent glucose sensitivity of 47.83 μAcm −2 mM −1 , low Michaelis-Menten constant of 2.2 mM, and wide glucose concentration detection, while it has good glucose selectivity against inhibitors, such as uric acid and ascorbic acid. Also, its activity is maintained to 95.7% of its initial value even after four weeks, confirming the catalyst is stable enough. The excellence of the catalyst is attributed to hydrophobic interaction, C=N bonds, and π -hydrogen interaction among GOx, PCA and PEI/CNT. The bindings play a role in facilitating electron transport between GOx and electrode.
AbstractList	Glucose, which is a primary energy source of living organisms, can induce diabetes or hypoglycemia if its concentration in blood is irregular. It is therefore important to develop glucose biosensor that reads the concentration of glucose in blood precisely. In the present work, we suggest new glucose oxidase (GOx) based catalysts that can improve the sensitivity of the glucose biosensor and make glucose measurements over a wide concentration ranges possible. For synthesizing such catalysts, a composite including pyrenecarboxaldehyde (PCA) and GOx is attached to substrate including carbon nanotube (CNT) and polyethyleneimine (PEI) (CNT/PEI/[PCA/GOx]). Catalytic activity and stability of the catalyst are then evaluated. According to the investigation, the catalyst shows excellent glucose sensitivity of 47.83 μAcm−2mM−1, low Michaelis-Menten constant of 2.2 mM, and wide glucose concentration detection, while it has good glucose selectivity against inhibitors, such as uric acid and ascorbic acid. Also, its activity is maintained to 95.7% of its initial value even after four weeks, confirming the catalyst is stable enough. The excellence of the catalyst is attributed to hydrophobic interaction, C=N bonds, and π-hydrogen interaction among GOx, PCA and PEI/CNT. The bindings play a role in facilitating electron transport between GOx and electrode. Glucose, which is a primary energy source of living organisms, can induce diabetes or hypoglycemia if its concentration in blood is irregular. It is therefore important to develop glucose biosensor that reads the concentration of glucose in blood precisely. In the present work, we suggest new glucose oxidase (GOx) based catalysts that can improve the sensitivity of the glucose biosensor and make glucose measurements over a wide concentration ranges possible. For synthesizing such catalysts, a composite including pyrenecarboxaldehyde (PCA) and GOx is attached to substrate including carbon nanotube (CNT) and polyethyleneimine (PEI) (CNT/PEI/[PCA/GOx]). Catalytic activity and stability of the catalyst are then evaluated. According to the investigation, the catalyst shows excellent glucose sensitivity of 47.83 μAcm −2 mM −1 , low Michaelis-Menten constant of 2.2 mM, and wide glucose concentration detection, while it has good glucose selectivity against inhibitors, such as uric acid and ascorbic acid. Also, its activity is maintained to 95.7% of its initial value even after four weeks, confirming the catalyst is stable enough. The excellence of the catalyst is attributed to hydrophobic interaction, C=N bonds, and π -hydrogen interaction among GOx, PCA and PEI/CNT. The bindings play a role in facilitating electron transport between GOx and electrode. Glucose, which is a primary energy source of living organisms, can induce diabetes or hypoglycemia if its concentration in blood is irregular. It is therefore important to develop glucose biosensor that reads the concentration of glucose in blood precisely. In the present work, we suggest new glucose oxidase (GOx) based catalysts that can improve the sensitivity of the glucose biosensor and make glucose measurements over a wide concentration ranges possible. For synthesizing such catalysts, a composite including pyrenecarboxaldehyde (PCA) and GOx is attached to substrate including carbon nanotube (CNT) and polyethyleneimine (PEI) (CNT/PEI/[PCA/GOx]). Catalytic activity and stability of the catalyst are then evaluated. According to the investigation, the catalyst shows excellent glucose sensitivity of 47.83 μAcm−2mM−1, low Michaelis-Menten constant of 2.2mM, and wide glucose concentration detection, while it has good glucose selectivity against inhibitors, such as uric acid and ascorbic acid. Also, its activity is maintained to 95.7% of its initial value even after four weeks, confirming the catalyst is stable enough. The excellence of the catalyst is attributed to hydrophobic interaction, C=N bonds, and π-hydrogen interaction among GOx, PCA and PEI/ CNT. The bindings play a role in facilitating electron transport between GOx and electrode. KCI Citation Count: 48
Author	Christwardana, Marcelinus Kwon, Yongchai Chung, Yongjin Ji, Jungyeon
Author_xml	– sequence: 1 givenname: Marcelinus surname: Christwardana fullname: Christwardana, Marcelinus organization: Graduate School of Energy and Environment, Seoul National University of Science and Technology – sequence: 2 givenname: Jungyeon surname: Ji fullname: Ji, Jungyeon organization: Graduate School of Energy and Environment, Seoul National University of Science and Technology – sequence: 3 givenname: Yongjin surname: Chung fullname: Chung, Yongjin email: yjchung@seoultech.ac.kr organization: Graduate School of Energy and Environment, Seoul National University of Science and Technology – sequence: 4 givenname: Yongchai surname: Kwon fullname: Kwon, Yongchai email: kwony@seoultech.ac.kr organization: Graduate School of Energy and Environment, Seoul National University of Science and Technology
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Keywords	Glucose Oxidase Pyrenecarboxaldehyde Diabetes Glucose Biosensor Hypoglycemia
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Snippet	Glucose, which is a primary energy source of living organisms, can induce diabetes or hypoglycemia if its concentration in blood is irregular. It is therefore...
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SubjectTerms	Ascorbic acid Biosensors Biotechnology Carbon nanotubes Catalysis Catalysts Catalytic activity Chemical synthesis Chemistry Chemistry and Materials Science Diabetes mellitus Electron transport Glucose Glucose oxidase Hydrophobicity Hypoglycemia Industrial Chemistry/Chemical Engineering Materials Science Nanotubes Polyethyleneimine Selectivity Sensitivity analysis Stability analysis Uric acid 화학공학
Title	Highly sensitive glucose biosensor using new glucose oxidase based biocatalyst
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