Transforming Siliconization into Slippery Liquid-like Coatings

Abstract: Siliconization is widely used as a coating technique to engineer surface properties, such as in the pharmaceutical and medical device industries to lubricate motion, ensure complete dispensation of product, and to inhibit protein adsorption and biofilm growth. In the hitherto unconnected literature, there has recently been significant progress in understanding the concept of surfaces slippery to liquids. Whereas in the siliconization industry the wettability of surfaces focuses on the hydrophobicity, as measured by contact angle and surface energy, for surfaces slippery to liquids the focus is on the contact angle hysteresis (droplet-on-solid static friction). Moreover, it has been discovered that surfaces with similar static wetting properties can have dramatically different droplet kinetic friction. Here, we report a simple-to-apply coating method to create ultra-low contact angle hysteresis liquid-like coatings for glass (G), polydimethylsiloxane (PDMS), polyurethane (PU), and stainless steel (SS); materials that are used for pharmaceutical/parenteral packaging and medical equipment. Moreover, we demonstrate that the coating's slow sliding dynamics surface properties for water droplets, which indicate high droplet kinetic friction, can be converted into fast sliding dynamics, which indicate low droplet kinetic friction, by a simple molecular capping (methylation) process. Our results provide new insight into key aspects of siliconization coatings in the context of industrial/commercial processes.