Abstract
Integration of materials acts as a bridge between the electronic and biological worlds, which has revolutionized the development of bioelectronic devices. This review highlights the rapidly emerging field of switchable interface and its bioelectronics applications. This review article highlights the role and importance of two-dimensional (2D) materials, especially graphene, in the field of bioelectronics. Because of the excellent electrical, optical, and mechanical properties graphene have promising application in the field of bioelectronics. The easy integration, biocompatibility, mechanical flexibility, and conformity add impact in its use for the fabrication of bioelectronic devices. In addition, the switchable behavior of this material adds an impact on the study of natural biochemical processes. In general, the behavior of the interfacial materials can be tuned with modest changes in the bioelectronics interface systems. It is also believed that switchable behavior of materials responds to a major change at the nanoscale level by regulating the behavior of the stimuli-responsive interface architecture.
Highlights
Bioelectronics is an emerging and exciting field, which involves biological materials and biological architecture for information processing
The key concept of the bioelectronics is the transduction of the signals is the interface between biological materials and electronics [1,2,3]
We look at graphene-based interface materials with their respective of bioelectronic interfaces
Summary
Bioelectronics is an emerging and exciting field, which involves biological materials and biological architecture for information processing. The main aspect ofinformation bioelectronics is thebionics interface biological materials and processing, biofuel cells, and electronic components and actuators. The key concept of the bioelectronics is the transduction of the signals is the interface between biological materials and electronics [1,2,3]. Carbon-based materials have the potential to crack past technical problems by by communicating the biological entities to to thethe electronic itsinterface interface[4,5]. Interface works a shuttlebetween betweenbiological biological and and enhances the the interface To overcome these challenges,carbon-based carbon-based materials emerges as aasbest-fitted electron transfer rate.rate. We highlight the future prospects of graphene-based bioelectronic interfaces by focusing on recent reports on electrochemical biosensing performance. Chemosensors prospects 2020, of 8,graphene-based bioelectronic interfaces by focusing on recent reports ofon electrochemical biosensing performance
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