Antifouling Surfaces Enabled by Surface Grafting of Highly Hydrophilic Sulfoxide Polymer Brushes.

Antifouling surfaces are important in a broad range of applications. An effective approach to antifouling surfaces is to covalently attach antifouling polymer brushes. This work reports the synthesis of a new class of antifouling polymer brushes based on highly hydrophilic sulfoxide polymers by surface-initiated photoinduced electron/energy transfer-reversible addition-fragmentation chain transfer (PET-RAFT) polymerization. The sulfoxide polymer brushes are able to effectively reduce nonspecific adsorption of proteins and cells, demonstrating remarkable antifouling properties. Given the outstanding antifouling behavior of the sulfoxide polymers and versatility of surface-initiated PET-RAFT technology, this work presents a useful and general approach to engineering various material surfaces with antifouling properties, for potential biomedical applications in areas such as tissue engineering, medical implants, and regenerative medicine.

Synthesis of polymers and nanoparticles bearing polystyrene sulfonate brushes for chemokine binding.

The movement of leukocytes to the site of inflammation in response to injury or infection is orchestrated by chemokines binding and signaling through cognate receptors. The interaction between sulfated tyrosine residues on the flexible N-terminal tail of the receptor with positively charged regions of the chemokine is one of the key recognition features that facilitates binding. In this manuscript we describe the synthesis of polymers and silica nanoparticles bearing polystyrene sulfonate brushes to mimic the sulfated tyrosine residues. We show that both the polymers and nanoparticles possess high binding affinity for the chemokine monocyte chemoattractant protein-1 (MCP-1) in monomeric and dimeric form. We also demonstrate key differences in the relative affinity for the chemokine for the free polymer versus the polymer-derived nanoparticle system.

Single addition of an allylamine monomer enables access to end-functionalized RAFT polymers for native chemical ligation.

A novel method for the introduction of a single protected amine-functional monomer at the chain end of RAFT polymers has been developed. This monomer addition, in concert with native chemical ligation, facilitated the development of a simple and versatile method for the end-functionalization of polymers with peptides.