Ultrathin Graphene-Protein Supercapacitors for Miniaturized Bioelectronics

Overview

Journal Adv Energy Mater

Date 2017 Nov 7

PMID 29104523

Citations 12

Authors

Islam M Mosa

Ajith Pattammattel

Karteek Kadimisetty

Paritosh Pande

Maher F El-Kady

Gregory W Bishop

Marc Novak

Richard B Kaner

Ashis K Basu

Challa V Kumar

James F Rusling

Affiliations

Soon will be listed here.

Abstract

Nearly all implantable bioelectronics are powered by bulky batteries which limit device miniaturization and lifespan. Moreover, batteries contain toxic materials and electrolytes that can be dangerous if leakage occurs. Herein, an approach to fabricate implantable protein-based bioelectrochemical capacitors (bECs) employing new nanocomposite heterostructures in which 2D reduced graphene oxide sheets are interlayered with chemically modified mammalian proteins, while utilizing biological fluids as electrolytes is described. This protein-modified reduced graphene oxide nanocomposite material shows no toxicity to mouse embryo fibroblasts and COS-7 cell cultures at a high concentration of 1600 μg mL which is 160 times higher than those used in bECs, unlike the unmodified graphene oxide which caused toxic cell damage even at low doses of 10 μg mL. The bEC devices are 1 μm thick, fully flexible, and have high energy density comparable to that of lithium thin film batteries. COS-7 cell culture is not affected by long-term exposure to encapsulated bECs over 4 d of continuous charge/discharge cycles. These bECs are unique, protein-based devices, use serum as electrolyte, and have the potential to power a new generation of long-life, miniaturized implantable devices.

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