We review the status of protein-based molecular electronics. First, we define and discuss fundamental concepts of electron transfer and transport in and across proteins and proposed mechanisms for these processes. We then describe the immobilization of proteins to solid-state surfaces in both nanoscale and macroscopic approaches, and highlight how different methodologies can alter protein electronic properties. Because immobilizing proteins while retaining biological activity is crucial to the successful development of bioelectronic devices, we discuss this process at length. We briefly discuss computational predictions and their connection to experimental results. We then summarize how the biological activity of immobilized proteins is ben...
Different scientific disciplines, from biochemistry to electronics, are converging toward the inves...
Methods to immobilize proteins are of particular relevance for biosensing. In biosensors, proteins ...
Molecular bioelectronics is a rapidly growing field at the junction of biochemistry, physics and sur...
Protein-mediated charge transport is of relevant importance in the design of protein-based electroni...
Bioelectronic materials interface biomolecules, cells, organs, or organisms with electronic devices,...
Recent work by a number of groups has highlighted the emerging potential associated with the marriag...
Introduction: A survey of proteins in nanobioelectronics The idea of using proteins to assemble hybr...
Successful integration of proteins in solid-state electronics requires contacting them in a non-inva...
Protein-mediated charge transport is of relevant importance in the design of protein based electroni...
Biological macromolecules have evolved over many millions of years into structures primed, in some c...
A key challenge of the current research in nanoelectronics is the realization of biomolecular device...
Nucleic acids and proteins are not only biologically important polymers. They have recently been rec...
Control over molecular scale electrical properties within nano junctions is demonstrated, utilizing ...
Proteins and peptides may be a promising route to develop conductive materials capable of interfacin...
Recently, the appreciation of the high energy yield and quantum efficiencies of a number of natural ...
Different scientific disciplines, from biochemistry to electronics, are converging toward the inves...
Methods to immobilize proteins are of particular relevance for biosensing. In biosensors, proteins ...
Molecular bioelectronics is a rapidly growing field at the junction of biochemistry, physics and sur...
Protein-mediated charge transport is of relevant importance in the design of protein-based electroni...
Bioelectronic materials interface biomolecules, cells, organs, or organisms with electronic devices,...
Recent work by a number of groups has highlighted the emerging potential associated with the marriag...
Introduction: A survey of proteins in nanobioelectronics The idea of using proteins to assemble hybr...
Successful integration of proteins in solid-state electronics requires contacting them in a non-inva...
Protein-mediated charge transport is of relevant importance in the design of protein based electroni...
Biological macromolecules have evolved over many millions of years into structures primed, in some c...
A key challenge of the current research in nanoelectronics is the realization of biomolecular device...
Nucleic acids and proteins are not only biologically important polymers. They have recently been rec...
Control over molecular scale electrical properties within nano junctions is demonstrated, utilizing ...
Proteins and peptides may be a promising route to develop conductive materials capable of interfacin...
Recently, the appreciation of the high energy yield and quantum efficiencies of a number of natural ...
Different scientific disciplines, from biochemistry to electronics, are converging toward the inves...
Methods to immobilize proteins are of particular relevance for biosensing. In biosensors, proteins ...
Molecular bioelectronics is a rapidly growing field at the junction of biochemistry, physics and sur...