Thioether‐Functionalized Cellulose for the Fabrication of Oxidation‐Responsive Biomaterial Coatings and Films

Hydroxyethyl cellulose (HEC) is modified with thioether groups to form HEC_MTP, an oxidation-responsive polymer ideal for coatings and films. HEC_MTP scavenges reactive oxygen species, converting thioether moieties to sulfoxides, increasing wettability, decreasing stiffness, and reducing protein absorption. HEC_MTP is optically transparent and suitable for oxidation-responsive drug release. HEC_MTP films are non-resorbable in vivo and elicit minimal foreign body responses.

Abstract

Biomaterial coatings and films can prevent premature failure and enhance the performance of chronically implanted medical devices. However, current hydrophilic polymer coatings and films have significant drawbacks, including swelling and delamination. To address these issues, hydroxyethyl cellulose is modified with thioether groups to generate an oxidation-responsive polymer, HEC_MTP. HEC_MTP readily dissolves in green solvents and can be fabricated as coatings or films with tunable thicknesses. HEC_MTP coatings effectively scavenge hydrogen peroxide, resulting in the conversion of thioether groups to sulfoxide groups on the polymer chain. Oxidation-driven, hydrophobic-to-hydrophilic transitions that are isolated to the surface of HEC_MTP coatings under physiologically relevant conditions increase wettability, decrease stiffness, and reduce protein adsorption to generate a non-fouling interface with minimal coating delamination or swelling. HEC_MTP can be used in diverse optical applications and permits oxidation-responsive, controlled drug release. HEC_MTP films are non-resorbable in vivo and evoke minimal foreign body responses. These results highlight the versatility of HEC_MTP and support its incorporation into chronically implanted medical devices.