Surface Passivation Method for Super-repellence of Aqueous Macromolecular Condensates

Abstract

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 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 θ≈180) 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 in vitro studies of weak interactions, dynamics, and internal organization of phase-separated droplets in aqueous solutions.