A novel approach to energy harvesting and biosensing devices would exploit optoelectronic
processes found in proteins that occur in nature. However, in order to design such systems …

Single-molecule sensing is becoming a major driver in biomarker assays as it is foreseen to
enable precision medicine to enter into everyday clinical practice. However, among the …

A long-term goal of nanobiotechnology is to build tiny devices that respond to the
environment, perform computations and carry out tasks. Considerable progress has been …

Biomolecular Electronics–the electrical control of biological phenomena–is a scientific
challenge that, once fully realized, will find a wide range of applications from electronics and …

We review charge transport across molecular monolayers, which is central to molecular
electronics (MolEl), using large-area junctions (NmJ). We strive to provide a wide conceptual …

The rate of electron transfer by tunnelling decreases exponentially with distance, but is
generally not rate limiting for distances up to 14Å, enabling the robust design of redox …

Bioelectrochemical technologies have an important and growing role in healthcare, with
applications in sensing and diagnostics, as well as the potential to be used as implantable …

Protein hinges for bioelectronics | Nature Biotechnology Skip to main content Thank you for
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Polymer‐based electrodes for interfacing biological tissues are becoming increasingly
sophisticated. Their many functions place them at the cross‐roads of electromaterials …

Biologically inspired peptide‐based materials, as novel charge transport materials, have
gained increasing interest in bioelectronics due to their remarkable electrical properties and …