Litcius/Paper detail

<i>De Novo</i> Design of Entropy-Driven Polymers Resistant to Bacterial Attachment via Multicomponent Reactions

Guoqiang Liu, Ziyang Xu, Xiaobin Dai, Yuan Zeng, Yen Wei, Xianzhe He, Li‐Tang Yan, Lei Tao

2021Journal of the American Chemical Society38 citationsDOI

Abstract

Nonbactericidal polymers that prevent bacterial attachment are important for public health, environmental protection, and avoiding the generation of superbugs. Here, inspired by the physical bactericidal process of carbon nanotubes and graphene derivatives, we develop nonbactericidal polymers resistant to bacterial attachment by using multicomponent reactions (MCRs) to introduce molecular “needles” (rigid aliphatic chains) and molecular “razors” (multicomponent structures) into polymer side chains. Computer simulation reveals the occurrence of spontaneous entropy-driven interactions between the bacterial bilayers and the “needles” and “razors” in polymer structures and provides guidance for the optimization of this type of polymers for enhanced resistibility to bacterial attachment. The blending of the optimized polymer with commercially available polyurethane produces a film with remarkably superior stability of the resistance to bacterial adhesion after wear compared with that of commercial mobile phone shells made by the Sharklet technology. This proof-of-concept study explores entropy-driven polymers resistant to bacterial attachment via a combination of MCRs, computer simulation, and polymer chemistry, paving the way for the de novo design of nonbactericidal polymers to prevent bacterial contamination.

Topics & Concepts

PolymerChemistryPolyurethaneNanotechnologyEntropy (arrow of time)Chemical engineeringOrganic chemistryMaterials scienceEngineeringQuantum mechanicsPhysicsAntimicrobial agents and applicationsGraphene and Nanomaterials ApplicationsPolymer Surface Interaction Studies