A Cascade Enzyme System Integrating Peroxidase Mimic with Catalase for Linear Range Expansion of H2O2 Assay: A Mechanism and Application Study

A Cascade Enzyme System Integrating Peroxidase Mimic with Catalase for Linear Range Expansion of H2O2 Assay: A Mechanism and Application Study

Peroxidase (POD) Nanozyme‐based hydrogen peroxide (H2O2) detection is popular, but hardly adapt to high concentration of H2O2 owing to narrow linear range (LR) and low LR maximum. Here, a solution of combining POD and catalase (CAT) is raised to expand the LR of H2O2 assay via decomposing part of H2...

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Veröffentlicht in:Small (Weinheim an der Bergstrasse, Germany) Germany), 2023-06, Vol.19 (25), p.n/a
Hauptverfasser: Hou, Haiwei, Liu, Lan, Li, Qiuyue, Wang, Jianming, Du, Baoji
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Sprache:eng
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Assaying
cascade enzymes
Catalase
Contact lenses
Enzyme activity
Enzymes
Graphene
H 2O 2 detection
Hydrogen peroxide
linear range expansion
Nanoparticles
Nanotechnology
Peroxidase
peroxidase mimic
Ruthenium
Substrates
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Liu, Lan
Li, Qiuyue
Wang, Jianming
Du, Baoji
description Peroxidase (POD) Nanozyme‐based hydrogen peroxide (H2O2) detection is popular, but hardly adapt to high concentration of H2O2 owing to narrow linear range (LR) and low LR maximum. Here, a solution of combining POD and catalase (CAT) is raised to expand the LR of H2O2 assay via decomposing part of H2O2. As a proof of concept, a cascade enzyme system (rGRC) is constructed by integrating ruthenium nanoparticles (RuNPs), CAT and graphene together. The rGRC‐based sensor does perform an expanded LR and higher LR maximum for H2O2 detection. Meanwhile, it is confirmed that LR expansion is closely associated with apparent Km of rGRC, which is determined by the relative enzyme activity between CAT and POD both in theory and in experiment. At last, rGRC is successfully used to detect high concentration of H2O2 (up to 10 mm) in contact lens care solution, which performs higher assay accuracy (close to 100% recovery at 10 mm of H2O2) than traditional POD nanozymes. This study brings up a kind of POD/CAT cascade enzyme system and provides a new concept for accurate and facile H2O2 detection. Additionally, it replenishes a new enzyme‐substrate model of achieving the same pattern with competitive inhibition in enzyme reactions. A cascade enzyme system (rGRC) integrating peroxidase with catalase is constructed. Then, it is theoretically expected and experimentally confirmed that increasing relative activity between CAT and POD can result in Km increase of POD and LR expansion for H2O2 assay. At last, rGRC is demonstrated to detect high concentration of H2O2 in contact lens cleaner more accurately than conventional peroxidase.
doi_str_mv 10.1002/smll.202300444
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Here, a solution of combining POD and catalase (CAT) is raised to expand the LR of H2O2 assay via decomposing part of H2O2. As a proof of concept, a cascade enzyme system (rGRC) is constructed by integrating ruthenium nanoparticles (RuNPs), CAT and graphene together. The rGRC‐based sensor does perform an expanded LR and higher LR maximum for H2O2 detection. Meanwhile, it is confirmed that LR expansion is closely associated with apparent Km of rGRC, which is determined by the relative enzyme activity between CAT and POD both in theory and in experiment. At last, rGRC is successfully used to detect high concentration of H2O2 (up to 10 mm) in contact lens care solution, which performs higher assay accuracy (close to 100% recovery at 10 mm of H2O2) than traditional POD nanozymes. This study brings up a kind of POD/CAT cascade enzyme system and provides a new concept for accurate and facile H2O2 detection. Additionally, it replenishes a new enzyme‐substrate model of achieving the same pattern with competitive inhibition in enzyme reactions. A cascade enzyme system (rGRC) integrating peroxidase with catalase is constructed. Then, it is theoretically expected and experimentally confirmed that increasing relative activity between CAT and POD can result in Km increase of POD and LR expansion for H2O2 assay. 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Here, a solution of combining POD and catalase (CAT) is raised to expand the LR of H2O2 assay via decomposing part of H2O2. As a proof of concept, a cascade enzyme system (rGRC) is constructed by integrating ruthenium nanoparticles (RuNPs), CAT and graphene together. The rGRC‐based sensor does perform an expanded LR and higher LR maximum for H2O2 detection. Meanwhile, it is confirmed that LR expansion is closely associated with apparent Km of rGRC, which is determined by the relative enzyme activity between CAT and POD both in theory and in experiment. At last, rGRC is successfully used to detect high concentration of H2O2 (up to 10 mm) in contact lens care solution, which performs higher assay accuracy (close to 100% recovery at 10 mm of H2O2) than traditional POD nanozymes. This study brings up a kind of POD/CAT cascade enzyme system and provides a new concept for accurate and facile H2O2 detection. Additionally, it replenishes a new enzyme‐substrate model of achieving the same pattern with competitive inhibition in enzyme reactions. A cascade enzyme system (rGRC) integrating peroxidase with catalase is constructed. Then, it is theoretically expected and experimentally confirmed that increasing relative activity between CAT and POD can result in Km increase of POD and LR expansion for H2O2 assay. 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Here, a solution of combining POD and catalase (CAT) is raised to expand the LR of H2O2 assay via decomposing part of H2O2. As a proof of concept, a cascade enzyme system (rGRC) is constructed by integrating ruthenium nanoparticles (RuNPs), CAT and graphene together. The rGRC‐based sensor does perform an expanded LR and higher LR maximum for H2O2 detection. Meanwhile, it is confirmed that LR expansion is closely associated with apparent Km of rGRC, which is determined by the relative enzyme activity between CAT and POD both in theory and in experiment. At last, rGRC is successfully used to detect high concentration of H2O2 (up to 10 mm) in contact lens care solution, which performs higher assay accuracy (close to 100% recovery at 10 mm of H2O2) than traditional POD nanozymes. This study brings up a kind of POD/CAT cascade enzyme system and provides a new concept for accurate and facile H2O2 detection. Additionally, it replenishes a new enzyme‐substrate model of achieving the same pattern with competitive inhibition in enzyme reactions. A cascade enzyme system (rGRC) integrating peroxidase with catalase is constructed. Then, it is theoretically expected and experimentally confirmed that increasing relative activity between CAT and POD can result in Km increase of POD and LR expansion for H2O2 assay. At last, rGRC is demonstrated to detect high concentration of H2O2 in contact lens cleaner more accurately than conventional peroxidase.</abstract><cop>Weinheim</cop><pub>Wiley Subscription Services, Inc</pub><doi>10.1002/smll.202300444</doi><tpages>9</tpages><orcidid>https://orcid.org/0000-0002-8423-7640</orcidid></addata></record>
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subjects Assaying
cascade enzymes
Catalase
Contact lenses
Enzyme activity
Enzymes
Graphene
H 2O 2 detection
Hydrogen peroxide
linear range expansion
Nanoparticles
Nanotechnology
Peroxidase
peroxidase mimic
Ruthenium
Substrates
title A Cascade Enzyme System Integrating Peroxidase Mimic with Catalase for Linear Range Expansion of H2O2 Assay: A Mechanism and Application Study
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