Issue 34, 2024

Multi-responsive poly-catecholamine nanomembranes

Abstract

The contraction of nanomaterials triggered by stimuli can be harnessed for micro- and nanoscale energy harvesting, sensing, and artificial muscles toward manipulation and directional motion. The search for these materials is dictated by optimizing several factors, such as stimulus type, conversion efficiency, kinetics and dynamics, mechanical strength, compatibility with other materials, production cost and environmental impact. Here, we report the results of studies on bio-inspired nanomembranes made of poly-catecholamines such as polydopamine, polynorepinephrine, and polydextrodopa. Our findings reveal robust mechanical features and remarkable multi-responsive properties of these materials. In particular, their immediate contraction can be triggered globally by atmospheric moisture reduction and temperature rise and locally by laser or white light irradiation. For each scenario, the process is fully reversible, i.e., membranes spontaneously expand upon removing the stimulus. Our results unveil the universal multi-responsive nature of the considered polycatecholamine membranes, albeit with distinct differences in their mechanical features and response times to light stimulus. We attribute the light-triggered contraction to photothermal heating, leading to water desorption and subsequent contraction of the membranes. The combination of multi-responsiveness, mechanical robustness, remote control via light, low-cost and large-scale fabrication, biocompatibility, and low-environment impact makes polycatecholamine materials promising candidates for advancing technologies.

Graphical abstract: Multi-responsive poly-catecholamine nanomembranes

Supplementary files

Article information

Article type
Paper
Submitted
12 Mar 2024
Accepted
29 May 2024
First published
14 Aug 2024
This article is Open Access
Creative Commons BY license

Nanoscale, 2024,16, 16227-16237

Multi-responsive poly-catecholamine nanomembranes

A. Krysztofik, M. Warżajtis, M. Pochylski, M. Boecker, J. Yu, T. Marchesi D'Alvise, P. Puła, P. W. Majewski, C. V. Synatschke, T. Weil and B. Graczykowski, Nanoscale, 2024, 16, 16227 DOI: 10.1039/D4NR01050G

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