Biofluid‐Activated Biofuel Cells, Batteries, and Supercapacitors: A Comprehensive Review

Abstract: Recent developments in wearable and implanted devices have resulted in numerous, unprecedented capabilities that generate increasingly detailed information about a user's health or provide targeted therapy. However, options for powering such systems remain limited to conventional batteries which are large and have toxic components and as such are not suitable for close integration with the human body. This review provides an in‐depth overview of biofluid‐activated electrochemical energy devices, an emerging cl… Show more

“…BOD-based biocathodes in fuel cells offer diverse applications across different fields since they drive the catalytic reduction process of oxygen. The versatile applications of BOD enzyme-based cathodes in fuel cells span a range of fields, from biobattery, medical devices, and H 2 /O 2 fuel cells, to environmental monitoring, showcasing the enzyme’s potential impact in various technological developments. − Herein, we discussed an overview of BODs-based biocathodes in EFCs utilizing biomolecules for biosensors and powering bioelectronics. A redox polymer/BOD-based gas diffusion electrode has been reported as a noncurrent and nonstability-limiting biocathode in a glucose/O 2 biofuel cell .…”

Emerging Trends of Bilirubin Oxidases at the Bioelectrochemical Interface: Paving the Way for Self-Powered Electrochemical Devices and Biosensors

“…BOD-based biocathodes in fuel cells offer diverse applications across different fields since they drive the catalytic reduction process of oxygen. The versatile applications of BOD enzyme-based cathodes in fuel cells span a range of fields, from biobattery, medical devices, and H 2 /O 2 fuel cells, to environmental monitoring, showcasing the enzyme’s potential impact in various technological developments. − Herein, we discussed an overview of BODs-based biocathodes in EFCs utilizing biomolecules for biosensors and powering bioelectronics. A redox polymer/BOD-based gas diffusion electrode has been reported as a noncurrent and nonstability-limiting biocathode in a glucose/O 2 biofuel cell .…”

Emerging Trends of Bilirubin Oxidases at the Bioelectrochemical Interface: Paving the Way for Self-Powered Electrochemical Devices and Biosensors

“…With a novel concentrated element combination, the template-assisted electrochemical technique offers several benefits in this regard, including ease of use, affordability, accessibility, dependability, and scalability [ 516 ]. One significant category of biomedical equipment that helps to maximize the human body's performance is tissue-integrated devices [ 517 ]. These materials were initially employed in tissue engineering to raise patients' quality of life.…”

“…Numerous industries have seen a transformation thanks to the numerous uses of nanoparticles (NPs). Due to their use in specialized fields like biosensing, agriculture, medicine, cancer theranostics, biosensing, catalysis, and the environment, magnetic nanoparticles (MNPs) in particular have attracted a lot of attention in the last ten years [ 581 ]. Current advancements in implanted and wearable technology have led to a host of previously unheard-of features that can deliver tailored therapy or produce even more detailed health information for the user [ 582 ].…”

A comprehensive review on the biomedical frontiers of nanowire applications

“…10–13 The output of a fuel cell is a process involving electrochemistry, gas reactions, and proton transfer and electron transfer in series, in which the transfer rates of the gas and proton are much lower than those of electron transfer under high power loading. 14–17 However, a sudden increase in load when the catalyst is used directly to power a fuel cell in an electric vehicle (EV) can result in a rapid drop in output voltage. More seriously, the output voltage can drop significantly or even become negative, which can cause structural damage to the catalyst and even detachment, resulting in the degradation of the performance of the fuel cell and shortening of its life, ultimately seriously affecting the acceleration performance of the EV.…”

Al-MOF-derived porous carbon-modified Pt/C catalyst for constructing a high-performance super fuel cell via an ORR + EDLC parallel-discharge mechanism