Modular domain structure: a biomimetic strategy for advanced polymeric materials.

A long lasting challenge in polymer science is to design polymers that combine desired mechanical properties such as tensile strength, fracture toughness, and elasticity into one structure. A novel biomimetic modular polymer design is reported here to address this challenge. Following the molecular mechanism used in nature, modular polymers containing multiple loops were constructed by using precise and strong hydrogen bonding units. Single-molecule force-extension experiments revealed the sequential unfolding of loops as a chain is stretched. The excellent correlation between the single-molecule and the bulk properties successfully demonstrates our biomimetic concept of using modular domain structure to achieve advanced polymer properties.

A novel carbohydrate-derived side-chain polyether with excellent protein resistance.

A novel carbohydrate-derived side-chain polyether was synthesized as a new biomaterial by condensation polymerization of monomers derived from natural occurring carbohydrates. Surface plasmon resonance spectroscopy studies demonstrated that this side-chain polyether has excellent resistance to nonspecific protein adsorption. The protein resistant capability of the side-chain polyether is comparable to that of oligoethylene glycol, a main-chain polyether that is, to date, the best protein resistant material. In addition to the excellent biocompatibility, the new polymer also combines biodegradability and functionalizability. With these combined good properties, this side-chain polyether is envisioned as a new biomaterial for many potential biomedical applications.