Randal C. Claussen

Self-assembling biomaterials: Liquid crystal phases of cholesteryl oligo(l-lactic acid) and their interactions with cells

We report here on the synthesis and characterization of a series of self-assembling biomaterials with molecular features designed to interact with cells and scaffolds for tissue regeneration. The molecules of these materials contain cholesteryl moieties, which have universal affinity for cell membranes, and short chains of lactic acid, a common component of biodegradable tissue engineering matrices. The materials were synthesized in good yields with low polydispersities in the range of 1.05–1.15, and their characterization was carried out by small-angle x-ray diffraction, transmission electron microscopy, electron diffraction, differential scanning calorimetry, and atomic force microscopy. These molecular materials form layered structures that can be described as smectic phases and can also order into single-crystal stacks with an orthorhombic unit cell. Their layer spacings range from 58 to 99 Å, corresponding to bilayers of oligomers with an average of 10 and 37 lactic acid residues, respectively. The self-organized layered structures were found to promote improved fibroblast adhesion and spreading, although the specific mechanism for this observed response remains unknown. The ability of self-assembling materials to present ordered and periodic bulk structures to cells could be a useful strategy in tissue engineering.

Encapsulation of pyrene within self-assembled peptide amphiphile nanofibers

Certain peptide amphiphiles (PAs) in aqueous media are known to form high-aspect-ratio cylindrical nanofibers with hydrophobic cores. Using cholesterol or palmitic acid as the hydrophobe and the biological adhesion epitope RGDS as the hydrophilic segment, we studied the encapsulation of pyrene, a small hydrophobic molecule, within the cores of the self-assembling PA nanofibers. Circular dichroism (CD), transmission electron microscopy (TEM) and fluorescence were used to characterize formation of the supramolecular structures. Pyrene excimer formation observed by fluorescence demonstrated the encapsulation and aggregation of pyrene within the hydrophobic cores. In addition, peptide amphiphiles covalently functionalized with pyrene linked to the hydrophobic portion of the molecule exhibited excimer formation upon self-assembly into nanofibers. Interestingly excimer formation was not observed in similar molecules that formed spherical aggregates rather than cylindrical nanofibers.