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Design and Synthesis of Elastomeric Biomaterials

$715,625FY2007MPSNSF

University Of North Carolina At Chapel Hill, Chapel Hill NC

Investigators

Abstract

TECHNICAL SUMMARY: The need for completely amorphous elastomeric biomaterials with tunable thermal, mechanical and degradation properties is significant. While crystalline materials are suitable for several biological applications, in many cases, implanted tissue engineering scaffolds, drug delivery depots and in vivo sensing materials are in mechanically dynamic environments in the body and must sustain and recover from various deformations without mechanical irritations to the surrounding tissues. In addition to decreasing tissue damage, elastomeric materials would also address needs ranging from tissue engineering scaffolds with desired mechanical properties to completely amorphous drug delivery devices with faster controlled release profiles to flexible mechanical devices such as drug eluting stents. Despite the recognized importance of elastomeric biomaterials, there have been only a few examples reported in the literature. In this project, synthetic strategies will be developed that will lead to a variety of new elastomeric biomaterials. Specifically, the following will be accomplished: 1) the design of synthetic routes that yield monomers capable of being polymerized via step growth reactions, 2) the synthesis of a variety of polyester, polyester ether and polyester urethane homopolymers, copolymers, thermoset and thermoplastic elastomers, and their polar functionalized derivatives and 3) the study of the structure-property relationships for these materials, examining thermal, mechanical, solubility, processing, biocompatibility and biodegradation characteristics. While the initial thermal and mechanical property analysis will be conducted in laboratories at UNC, further bidegradation and biocompatibility analysis of these materials will be accomplished in collaboration with Professor Moo Cho in the UNC School of Pharmacy. Processing will be completed in collaboration with Professor Joseph DeSimone in the UNC department of chemistry. A detailed analysis of mechanical properties, particularly related to shape memory behavior will be a collaborative effort with Professor Ken Gall at Georgia Tech. Collaborations with colleagues at UNC and GT will combine our expertise in polymer synthesis, with characterization, processing and biomaterials knowledge to make significant contributions to this area of research. NONTECHNICAL SUMMARY: The biomaterials currently used in applications such as drug delivery stents and tissue regeneration scaffolds typically are rigid materials that often cause damage to the surrounding tissues. The new materials that will result from this project will have properties that are more compatible with soft tissue. Despite the recognized importance of designing these soft elastomeric degradable biomaterials, there have been few examples reported in the literature. In this research, synthetic strategies will be developed that lead to a variety of these types of new elastomers. The success of these materials will have a significant impact on this area of advanced biomaterials by providing methods for producing elastomers as well as for tailoring the chemical functionality, physical, mechanical and biological properties. This project will also promote teaching and training of graduate students, undergraduates and high school student researchers. Each will be presented with intriguing, relevant problems that can be answered in the laboratory using organic synthesis and analytical chemistry. The research results will be incorporated into the teaching of undergraduate organic and of graduate polymer chemistry to help students appreciate the utility of basic concepts. The major outreach efforts of this project include continuing work in a recently established UNC Chapter of the National Organization of Black Chemists and Chemical Engineers for which the PI is the faculty advisor. The PI will also continue to serve as a mentor in the Project SEED program, which encourages economically disadvantaged high school students to pursue career opportunities in the chemical sciences.

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