Molecular processes in an electrochemical clozapine sensor

Thomas E. Winkler; Sarah L. Lederer; Eunkyoung Kim; Hadar Ben-Yoav; Deanna L. Kelly; Gregory F. Payne; Reza Ghodssi

doi:10.1116/1.4982709

Molecular processes in an electrochemical clozapine sensor

Thomas E. Winkler
, Sarah L. Lederer
, Eunkyoung Kim
, Hadar Ben-Yoav
, Deanna L. Kelly
, Gregory F. Payne
, Reza Ghodssi

Department of Biomedical Engineering

Research output: Contribution to journal › Article › peer-review

9 Scopus citations

Abstract

Selectivity presents a crucial challenge in direct electrochemical sensing. One example is schizophrenia treatment monitoring of the redox-active antipsychotic clozapine. To accurately assess efficacy, differentiation from its metabolite norclozapine-similar in structure and redox potential-is critical. Here, the authors leverage biomaterials integration to study, and effect changes in, diffusion and electron transfer kinetics of these compounds. Specifically, the authors employ a catechol-modified chitosan film, which the authors have previously presented as the first electrochemical detection mechanism capable of quantifying clozapine directly in clinical serum. A key finding in our present work is differing dynamics between clozapine and norclozapine once the authors interface the electrodes with chitosan-based biomaterial films. These additional dimensions of redox information can thus enable selective sensing of largely analogous small molecules.

Original language	English
Article number	02B401
Journal	Biointerphases
Volume	12
Issue number	2
DOIs	https://doi.org/10.1116/1.4982709
State	Published - 1 Jun 2017

ASJC Scopus subject areas

General Chemistry
Biomaterials
General Materials Science
General Biochemistry, Genetics and Molecular Biology
General Physics and Astronomy

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title = "Molecular processes in an electrochemical clozapine sensor",

abstract = "Selectivity presents a crucial challenge in direct electrochemical sensing. One example is schizophrenia treatment monitoring of the redox-active antipsychotic clozapine. To accurately assess efficacy, differentiation from its metabolite norclozapine-similar in structure and redox potential-is critical. Here, the authors leverage biomaterials integration to study, and effect changes in, diffusion and electron transfer kinetics of these compounds. Specifically, the authors employ a catechol-modified chitosan film, which the authors have previously presented as the first electrochemical detection mechanism capable of quantifying clozapine directly in clinical serum. A key finding in our present work is differing dynamics between clozapine and norclozapine once the authors interface the electrodes with chitosan-based biomaterial films. These additional dimensions of redox information can thus enable selective sensing of largely analogous small molecules.",

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AU - Winkler, Thomas E.

AU - Lederer, Sarah L.

AU - Kim, Eunkyoung

AU - Ben-Yoav, Hadar

AU - Kelly, Deanna L.

AU - Payne, Gregory F.

AU - Ghodssi, Reza

PY - 2017/6/1

Y1 - 2017/6/1

N2 - Selectivity presents a crucial challenge in direct electrochemical sensing. One example is schizophrenia treatment monitoring of the redox-active antipsychotic clozapine. To accurately assess efficacy, differentiation from its metabolite norclozapine-similar in structure and redox potential-is critical. Here, the authors leverage biomaterials integration to study, and effect changes in, diffusion and electron transfer kinetics of these compounds. Specifically, the authors employ a catechol-modified chitosan film, which the authors have previously presented as the first electrochemical detection mechanism capable of quantifying clozapine directly in clinical serum. A key finding in our present work is differing dynamics between clozapine and norclozapine once the authors interface the electrodes with chitosan-based biomaterial films. These additional dimensions of redox information can thus enable selective sensing of largely analogous small molecules.

AB - Selectivity presents a crucial challenge in direct electrochemical sensing. One example is schizophrenia treatment monitoring of the redox-active antipsychotic clozapine. To accurately assess efficacy, differentiation from its metabolite norclozapine-similar in structure and redox potential-is critical. Here, the authors leverage biomaterials integration to study, and effect changes in, diffusion and electron transfer kinetics of these compounds. Specifically, the authors employ a catechol-modified chitosan film, which the authors have previously presented as the first electrochemical detection mechanism capable of quantifying clozapine directly in clinical serum. A key finding in our present work is differing dynamics between clozapine and norclozapine once the authors interface the electrodes with chitosan-based biomaterial films. These additional dimensions of redox information can thus enable selective sensing of largely analogous small molecules.

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Molecular processes in an electrochemical clozapine sensor

Abstract

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