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Catechol‐Based Molecular Memory Film for Redox Linked Bioelectronics

Si Wu, Eunkyoung Kim, Chen‐Yu Chen, Jinyang Li, Eric VanArsdale, Christopher Grieco, Bern Kohler, William E. Bentley, Xiaowen Shi, Gregory F. Payne

2020Advanced Electronic Materials24 citationsDOIOpen Access PDF

Abstract

Abstract Redox is emerging as an alternative modality for bio‐device communication. In contrast to the more familiar ionic electrical modality: (i) redox involves the flow of electrons through oxidation–reduction reactions; (ii) the aqueous medium is an “insulator” to this electron flow since free electrons do not normally exist in water; and (iii) redox states are intrinsically digital (oxidized and reduced). By exploiting these unique features, a catechol‐based molecular memory film is reported. This memory is fabricated by electrochemically grafting catechol to a chitosan–agarose polysaccharide network to generate a redox‐active but non‐conducting matrix. The redox state of the grafted catechol moieties serves as the 2‐state memory. It is shown that these redox states: can be repeatedly switched by diffusible mediators (electron shuttles); can be easily read electrically or optically; are stable for at least 2 h in the absence of energy; are sensitive to biologically relevant oxidizing and reducing contexts; and can be switched enzymatically. This catechol‐based molecular memory film is a simple circuit element for redox linked bioelectronics.

Topics & Concepts

BioelectronicsRedoxCatecholMaterials scienceOxidizing agentIonic bondingElectrochemistryNanotechnologyPhotochemistryCombinatorial chemistryChemistryBiosensorElectrodeOrganic chemistryIonMetallurgyPhysical chemistryAdvanced Memory and Neural ComputingConducting polymers and applicationsAnalytical Chemistry and Sensors
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