Hierachical assembly of collagen mimetic peptides into biofunctional materials

Jeremy W Gleaton, Purdue University

Abstract

Collagen is a remarkably strong and prevalent protein distributed throughout nature and as such, collagen is an ideal material for a variety of medical applications. Research efforts for the development of synthetic collagen biomaterials is an area of rapid growth. Here we present two methods for the assembly of collagen mimetic peptides (CMPs). The initial approach prompts assembly of CMPs which contain modifications for metal ion-triggered assembly. Hierarchical assembly into triple helices, followed by formation of disks via hydrophobic interactions has been demonstrated. Metal-ion mediated assembly of these disks, using iron (II)-bipyrdine interactions, has been shown to form micron-sized cages. The nature of the final structures that form depends on the number of bipyridine moieties incorporated into the CMP. These hollow spheres encapsulate a range of molecular weight fluorescently labeled dextrans. Furthermore, they demonstrate a time dependent release of contents under a variety of thermal conditions. The second approach assembles CMPs via the copper-catalyzed alkyne-azide cycloaddition (CuAAC) and the strain-promoted alkyne-azide cycloaddition (SPAAC) reactions. CMPs that incorporate the unnatural amino acids L-propargylglycine and L-azidolysine form triple helices and demonstrate higher order assembly when reacted via CuAAC. Reaction of the alkyne/azide modified CMPs under CuAAC conditions was found to produce an crosslinked 3-dimensional network. Moreover, we demonstrate that polymers, such as, PEG, can be reacted with alkyne and azide CMP triple helices via CuAAC and SPAAC. This designed covalent CMP chemistry allows for high flexibility in integrating various chemical cues, such as cell growth and differentiation within the higher order structures.

Degree

Ph.D.

Advisors

Chmielewski, Purdue University.

Subject Area

Chemistry|Materials science

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