Issue 10, 2022

Orthogonal redox and optical stimuli can induce independent responses for catechol-chitosan films

Abstract

Catechol-based materials possess diverse properties that are especially well-suitable for redox-based bioelectronics. Previous top-down, systems-level property measurements have shown that catechol-polysaccharide films (e.g., catechol-chitosan films) are redox-active and allow electrons to flow through the catechol/quinone moieties via thermodynamically-constrained redox reactions. Here, we report that catechol-chitosan films are also photothermally responsive and enable near infrared (NIR) radiation to be transduced into heat. When we simultaneously stimulated catechol-chitosan films with NIR and redox inputs, times-series measurements showed that the responses were reversible and largely independent. Fundamentally, these top-down measurements suggest that the flow of energy through catechol-based materials via the redox-based molecular modality and the electromagnetic-based optical modality can be independent. Practically, this work further illustrates the potential of catecholic materials for bridging bio-device communication because it enables communication through both short-range redox modalities and long-range electromagnetic modalities.

Graphical abstract: Orthogonal redox and optical stimuli can induce independent responses for catechol-chitosan films

Supplementary files

Article information

Article type
Research Article
Submitted
07 Feb 2022
Accepted
05 Apr 2022
First published
05 Apr 2022

Mater. Chem. Front., 2022,6, 1253-1260

Author version available

Orthogonal redox and optical stimuli can induce independent responses for catechol-chitosan films

Z. Zhao, E. Kim, C. Chen, J. R. Rzasa, Q. Zhang, J. Li, Y. Tao, W. E. Bentley, J. Lumb, B. Kohler and G. F. Payne, Mater. Chem. Front., 2022, 6, 1253 DOI: 10.1039/D2QM00106C

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