Catechol‐Based Molecular Memory Film for Redox Linked Bioelectronics

Wu, Si; Kim, Eunkyoung; Chen, Chen-Yu; Li, Jinyang; VanArsdale, Eric; Grieco, Christopher; Kohler, Bern; Bentley, William E.; Shi, Xiaowen; Payne, G. L.

doi:10.1002/aelm.202000452

Cited by 19 publications

(54 citation statements)

References 52 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Previous studies have assigned this peak to the oxidized quinone (Q) moieties. [ 26 ] The rightmost plot in Figure 3a shows the change in absorbance measured at 480 nm (Δ| A 480 |) decreased with time, and this change was larger for films written with a larger number of electrode writing strokes. These results indicate that: i) ascorbate can donate electrons to the film to convert the oxidized quinone moieties (Q‐state) into reduced catechol moieties (QH 2 ‐state); ii) the film's capacity to accept electrons can be adjusted by the extent of catechol modification; and iii) electron transfer to the film can be “passively” observed (i.e., without changing the state) by measuring optical absorbance.…”

Section: Resultsmentioning

confidence: 99%

“…In addition to detecting the pattern of the catechol that was irreversibly written into the film (Figure 2), it is also possible to detect the reversible switching of this catechol's redox state. To demonstrate optical detection of the redox‐state of the patterned catechol regions, [ 26 ] we started with a Chit 0 /agarose hydrogel that was patterned with two circular dots with the same extent of modification ( Q fab = 5 mC), and locally set the redox state of these dots to an oxidized (Q) state or a reduced (QH 2 ) state through mediated electrochemistry as illustrated in Figure a. Experimentally, the catechol‐patterned Chit 0 /agarose hydrogel film was immersed in Fc/Ru 3+ mediator solutions (0.1 m m each), a standard gold electrode was placed above each dot, and the imposed voltage was controlled to set the redox state.…”

Section: Resultsmentioning

confidence: 99%

“…[ 23–25 ] Third, the catechol and quinone redox states are distinguishable due to differences in their optical absorbance. [ 26–28 ] Finally, kinetic barriers for electron exchange with catechol‐quinone redox couples are often low which allows the oxidized quinone to accept electrons from a wide range of reductants, and allows the reduced catechol to donate electrons to a range of oxidants. [ 29 ]…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Hydrogel Patterning with Catechol Enables Networked Electron Flow

Zhao

Rzasa

et al. 2021

Adv Funct Materials

Self Cite

View full text Add to dashboard Cite

Reduction–oxidation (redox) reactions provide a distinct modality for biological communication that is fundamentally different from the more‐familiar ion‐based electrical modality. Biology uses these two modalities for communication through different systems (immune versus nervous), and uses different mechanisms to control the flow of the charge carriers: the flow of soluble ions is controlled using structural barriers (i.e., membranes) and gates (e.g., membrane‐spanning protein channels), while the flow of insoluble electrons is controlled using redox‐reaction networks. Here, a simple electrochemical approach to pattern catechols onto a flexible polysaccharide hydrogel is reported and it is demonstrated that the patterned catechol regions serve as nodes for the mediated flow of electrons through redox reactions. Electron flow through this node involves the switching of binary redox states (oxidized and reduced) and this node's redox state can be detected (i.e., “read”) by passively observing its optical absorbance, or actively switching its redox‐state electrochemically. Further, this catechol node can be switched through biological mechanisms, and this enables the fabricated catechol node to be embedded within biochemical redox reaction networks to facilitate the spanning of bio‐electronic communication. Thus, it is envisioned that catechols can emerge as a molecular equivalent to a transistor for miniaturize‐able, deployable and sustainable redox‐linked bioelectronics.

show abstract

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Hydrogel Patterning with Catechol Enables Networked Electron Flow

Zhao

Rzasa

et al. 2021

Adv Funct Materials

Self Cite

View full text Add to dashboard Cite

show abstract

“…Cellular redox in particular has proven to be a valuable source of cellular information that is easily accessible to human and device readable outputs. For example, detection and memory of redox state was achieved using a chatecol-chitosan-agarose matrix with optical or electrical output 59 . The ubiquitous nature of biological redox has made it possible to electronically interact with skin pigments such as melanin, control biological patterning and gene expression, and integrate two-way communication via redox stress signals 60 .…”

Section: Introductionmentioning

confidence: 99%

Sensing the future of bio-informational engineering

2021

View full text Add to dashboard Cite

The practices of synthetic biology are being integrated into ‘multiscale’ designs enabling two-way communication across organic and inorganic information substrates in biological, digital and cyber-physical system integrations. Novel applications of ‘bio-informational’ engineering will arise in environmental monitoring, precision agriculture, precision medicine and next-generation biomanufacturing. Potential developments include sentinel plants for environmental monitoring and autonomous bioreactors that respond to biosensor signaling. As bio-informational understanding progresses, both natural and engineered biological systems will need to be reimagined as cyber-physical architectures. We propose that a multiple length scale taxonomy will assist in rationalizing and enabling this transformative development in engineering biology.

show abstract

“…Interestingly, redox-inactive materials can be conjugated with redox mediators such as catechols and quinones, and these are easily fabricated at discrete locations ( Liu et al., 2010 ). We have suggested that these materials can serve as a form of bioelectronic memory to locally address where specific communication events happen within a spatial domain, such as within the spatial resolution of an electrode array or gel ( Wu et al., 2020 ). That is, in these storage devices, a non-conducting material, such as catechol-modified chitosan, serves as a redox sink to sequester electrons away from the electrode.…”

Section: Introductionmentioning

confidence: 99%

Redox Electrochemistry to Interrogate and Control Biomolecular Communication

et al. 2020

Self Cite

View full text Add to dashboard Cite

Summary Cells often communicate by the secretion, transport, and perception of molecules. Information conveyed by molecules is encoded, transmitted, and decoded by cells within the context of the prevailing microenvironments. Conversely, in electronics, transmission reliability and message validation are predictable, robust, and less context dependent. In turn, many transformative advances have resulted by the formal consideration of information transfer. One way to explore this potential for biological systems is to create bio-device interfaces that facilitate bidirectional information transfer between biology and electronics. Redox reactions enable this linkage because reduction and oxidation mediate communication within biology and can be coupled with electronics. By manipulating redox reactions, one is able to combine the programmable features of electronics with the ability to interrogate and modulate biological function. In this review, we examine methods to electrochemically interrogate the various components of molecular communication using redox chemistry and to electronically control cell communication using redox electrogenetics.

show abstract

Catechol‐Based Molecular Memory Film for Redox Linked Bioelectronics

Cited by 19 publications

References 52 publications

Hydrogel Patterning with Catechol Enables Networked Electron Flow

Hydrogel Patterning with Catechol Enables Networked Electron Flow

Sensing the future of bio-informational engineering

Redox Electrochemistry to Interrogate and Control Biomolecular Communication

Contact Info

Product

Resources

About