Surface Passivation Method for Super-repellence of Aqueous Macromolecular Condensates

Solutions of macromolecules can undergo liquid-liquid phase separation to form droplets with ultra-low surface tension. Droplets with such low surface tension wet and spread over common surfaces such as test tubes and microscope slides, complicating \textit{in vitro} experiments. Development of an u...

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Hauptverfasser: Testa, Andrea, Spanke, Hendrik T, Jambon-Puillet, Etienne, Yasir, Mohammad, Küffner, Andreas M, Arosio, Paolo, Dufresne, Eric R, Style, Robert W, Rebane, Aleksander A
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creator Testa, Andrea
Spanke, Hendrik T
Jambon-Puillet, Etienne
Yasir, Mohammad
Küffner, Andreas M
Arosio, Paolo
Dufresne, Eric R
Style, Robert W
Rebane, Aleksander A
description Solutions of macromolecules can undergo liquid-liquid phase separation to form droplets with ultra-low surface tension. Droplets with such low surface tension wet and spread over common surfaces such as test tubes and microscope slides, complicating \textit{in vitro} experiments. Development of an universal super-repellent surface for macromolecular droplets has remained elusive because their ultra-low surface tension requires low surface energies. Furthermore, nonwetting of droplets containing proteins poses additional challenges because the surface must remain inert to a wide range of chemistries presented by the various amino-acid side-chains at the droplet surface. Here, we present a method to coat microscope slides with a thin transparent hydrogel that exhibits complete dewetting (contact angles $\theta\approx180^\circ)$ and minimal pinning of phase-separated droplets in aqueous solution. The hydrogel is based on a swollen matrix of chemically crosslinked polyethylene glycol diacrylate of molecular weight 12 kDa (PEGDA), and can be prepared with basic chemistry lab equipment. The PEGDA hydrogel is a powerful tool for \textit{in vitro} studies of weak interactions, dynamics, and internal organization of phase-separated droplets in aqueous solutions.
doi_str_mv 10.48550/arxiv.2306.02198
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Physics - Materials Science
Physics - Soft Condensed Matter
title Surface Passivation Method for Super-repellence of Aqueous Macromolecular Condensates
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