Living and Regenerative Material Encapsulating Self-Assembled -CdS Hybrids for Photocatalytic Biodegradation of Organic Dyes

Overview

Journal Microorganisms

Specialty Microbiology

Date 2022 Dec 23

PMID 36557754

Authors

Mingyue Tao

Chenyang Jin

Hongfei Lu

Kai Jin

Lin Yu

Jinliang Liu

Jing Zhang

Xiaohui Zhu

Yihan Wu

Affiliations

Soon will be listed here.

Abstract

Reductive biodegradation by microorganisms has been widely explored for detoxifying recalcitrant contaminants; however, the biodegradation capacity of microbes is limited by the energy level of the released electrons. Here, we developed a method to self-assemble -CdS nanoparticle hybrids with significantly improved reductive biodegradation capacity and constructed a living material by encapsulating the hybrids in hydrogels. The material confines the nano-bacteria hybrids and protects them from environmental stress, thus improving their recyclability and long-term stability (degradation capacity unhindered after 4 weeks). The developed living materials exhibited efficient photocatalytic biodegradation of various organic dyes including azo and nitroso dyes. This study highlights the feasibility and benefits of constructing self-assembled nano-bacteria hybrids for bioremediation and sets the stage for the development of novel living materials from nano-bacteria hybrids.

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