Therapeutic proteins are challenging to transport and store, and thus the majority must be refrigerated or frozen. Proteins exposed to these conditions and others such as mechanical agitation often lose activity. This can be harmful or even fatal for patients that take the medications and can also increase costs because of the requirement of the cold chain. Thus, polymeric materials that are capable of stabilizing biomolecules at room temperature and to agitation are of significant interest. This talk will focus on new polymeric materials to address this important problem. Well-defined polymers were synthesized by controlled radical polymerization and ring opening polymerizations. These were tested in their ability to stabilize proteins to room temperature, elevated temperatures, mechanical agitation, and pH changes when added as excipients. Side chains derived from Nature and others from known excipient classes were compared and contrasted, and the mechanisms of stabilization were investigated. Grafting to and grafting from synthetic strategies were utilized to prepare protein conjugates of these polymers, and in vivo testing showed that the polymers significantly increased blood circulation times (i.e. pharmacokinetics) in addition to retaining protein activity after exposure to high temperatures. Furthermore, by altering the synthesis, the polymers could be made responsive in order to release protein drugs on demand. Synthesis, stabilization properties, and application of the polymers in medicine will be presented.
Host: MG Finn (firstname.lastname@example.org)