Toward bioelectronic device based on bionanohybrid composed of nanomaterials and biomaterials: From nucleic acid and protein to living cell

Bioelectronics is a convergence research field composed of biology and electronics for realizing the electronic functions of a biochip. However, the intrinsic properties of biomaterials impede the development of delicate bioelectronic devices due to low conductivity and durability. Nanomaterials can circumvent the limitations of biomaterials by virtue of their unique properties, including conductivity and biocompatibility. To this end, the development of bionanohybrids through the integration of nanomaterials with biomaterials is a common approach. In recent years, several new nanomaterials, such as graphene, transition metal dichalcogenides, and MXenes, have been developed. Accordingly, numerous studies have reported on novel bionanohybrid-based bioelectronics developed by introducing nanomaterials to bioelectronic devices for improved durability and electrical functions, such as conductivity and functional expansion. This review summarizes the recent studies on such delicate bioelectronic devices based on bionanohybrids and thereby helps the understanding of the development of bioelectronic devices by integrating biomaterials with nanomaterials.

Automated summary

Bioelectronics is a field that combines biology and electronics to achieve electronic functions in biochips. However, the properties of biomaterials hinder the development of delicate bioelectronic devices due to their low conductivity and durability. Nanomaterials with unique properties such as conductivity and biocompatibility can overcome these limitations. The integration of nanomaterials with biomaterials has led to the development of bionanohybrids, and new nanomaterials like graphene, transition metal dichalcogenides, and MXenes have been developed. This review summarizes recent studies on bionanohybrid-based bioelectronic devices, which improve durability and electrical functions such as conductivity and functional expansion by introducing nanomaterials. It helps to understand the development of bioelectronic devices by integrating biomaterials with nanomaterials.