It is well-established that redox-reactions are integral to biology for energy harvesting
(oxidative phosphorylation), immune defense (oxidative burst) and drug metabolism (phase I …

Redox-cycling compounds can significantly impact biological systems and can be
responsible for activities that range from pathogen virulence and contaminant toxicities, to …

A common bioelectronics goal is to enable communication between biology and electronics,
and success is critically dependent on the communication modality. When a biorelevant …

Catechols offer diverse properties and are used in biology to perform various functions that
range from adhesion (eg, mussel proteins) to neurotransmission (eg, dopamine), and …

Electronic devices process information and transduce energy with electrons, while biology
performs such operations with ions and chemicals. To establish bio‐device connectivity, we …

Exciting opportunities in bioelectronics will be facilitated by materials that can bridge the
chemical logic of biology and the digital logic of electronics. Here we report the fabrication of …

Biology uses well-known redox mechanisms for energy harvesting (eg, respiration),
biosynthesis, and immune defense (eg, oxidative burst), and now we know biology uses …

Biology is well known for its ability to communicate through molecularly specific signaling
modalities and a globally acting electrical modality associated with ion flow across biological …

Redox bioelectronics enlists electrochemical methods to connect to biology through
biology's native redox modality. The activities of this redox modality involve the exchange of …

Electron transfer in biology occurs with individual or pairs of electrons, and is often mediated
by catechol/o‐quinone redox couples. Here, a biomimetic polysaccharide‐catecholic film is …