Faculty Bibliography

Bi-domain peptides with a factor XIIIa substrate in one domain and a bioactive peptide in another domain were covalently incorporated into fibrin gels during coagulation through the action of the transglutaminase factor XIIIa. The cross-linking characteristics were determined for two bi-domain peptides with factor XIIIa substrates based on fibrinogen, dYRGDTIGEGQQHHLGG-NH2, and dLRGDGAKDV-NH2, as well as one bi-domain peptide with a substrate sequence based on alpha2-plasmin inhibitor, dLNQEQVSPLRGD-NH2, and another with a nonbiological, oligolysine substrate, dLRGDKKKKG-NH2 (substrate domains in italic). Each of these peptides was able to cross-link into the fibrin gels during coagulation, with the peptide containing the factor XIIIa substrate based on alpha2-plasmin inhibitor being incorporated at levels in excess of 8 mol/mol fibrinogen. The structural characteristics of these peptide-modified gels proved to be the same as those for a native fibrin gel. The bioactivity of the incorporated active factors was tested in a neuronal culture model with day 8 chicken dorsal root ganglia using two bioactive sequences, RGD and DGEA, and one inactive control sequence, RDG. Each of these peptides influenced the extension of neurites from the ganglia as expected, indicating that the incorporated factors retained their activity. With the use of soluble competitive inhibitors, it was shown that this effect was due to the covalently incorporated peptides. Through exploiting the role of factor XIIIa in coagulation, we have developed a method by which to impart the character of nonfibrin proteins, such as extracellular matrix proteins, to fibrin, a biological material with many potential therapeutic and academic applications.

The elucidation of proteins involved in biomaterial-modulated macrophage behavior is critical for the improvement of material performance and the initial exploration of material design capable of manipulating macrophage function for tissue engineering. In this paper, several in vitro and in vivo techniques are presented to demonstrate means of delineating a part of the complex molecular mechanisms involved in the interaction between biomaterial and macrophage adhesion and phenotypic development. The following conclusions were reached: (1) using radioimmunoassay, complement component C3 was found to be critical in mediating human macrophage adhesion on polyurethanes. (2) The presence of a diphenolic antioxidant additive in polyurethanes increased the propensity for complement upregulation but did not affect adherent macrophage density. (3) The subcutaneous cage-implant system was utilized to delineate interleukin-4 participation in the fusion of adherent macrophages to form foreign body giant cells in vivo in mice. The injection of purified interleukin-4 neutralizing antibody into the implanted cages significantly decreased the giant cell density; conversely, the giant cell density was significantly increased by the injection of recombinant interleukin-4 when compared with the controls. (4) The RGD and PHSRN amino acid sequences of the central cell binding domain and the PRRARV sequence of the C-terminal heparin binding domain of human plasma fibronectin were utilized to study the structure-functional relationship of protein in mediating macrophage behavior. Polyethyleneglycol-based networks grafted with the RGD-containing peptide supported higher adherent human macrophage density than surfaces grafted with other peptides. The formation of foreign body giant cell was highly dependent on the relative orientation between PHSRN and RGD domains located in a single peptide.

The usefulness of interfacial photopolymerization of poly(ethylene glycol) (PEG) diacrylate at a variety of concentrations and molecular weights to form hydrogel membranes for encapsulating porcine islets of Langerhans was investigated. The results from this study show in vitro and in vivo function of PEG-encapsulated porcine islets and the ability of PEG membranes to prevent immune rejection in a discordant xenograft model. Encapsulated islets demonstrated an average viability of 85% during the first week after encapsulation, slightly but significantly lower than unencapsulated controls. Encapsulated porcine islets were shown to be glucose responsive using static glucose stimulation and perifusion assays. Higher rates of insulin release were observed for porcine islets encapsulated in lower concentrations of PEG diacrylate (10-13%), not significantly reduced relative to unencapsulated controls, than were observed in islets encapsulated in higher concentrations (25%) of PEG diacrylate. Perifusion results showed biphasic insulin release from encapsulated islets in response to glucose stimulation. Streptozotocin-induced diabetic athymic mice maintained normoglycemia for up to 110 days after the implantation of 5,000-8,000 encapsulated porcine islet equivalents into the peritoneal cavity. Normoglycemia was also confirmed in these animals using glucose tolerance tests. PEG diacrylate-encapsulated porcine islets were shown to be viable and contain insulin after 30 days in the peritoneal cavity of Sprague-Dawley rats, a discordant xenograft model. From these studies, we conclude that PEG diacrylate encapsulation of porcine islets by interfacial photopolymerization shows promise for use as a method of xenoprotection toward a bioartificial endocrine pancreas.

Postsurgical adhesions represent a common complication following a variety of surgical procedures. We sought to develop and evaluate a water-soluble polymer that could self-assemble onto tissue surfaces, forming a barrier on the surface. A copolymer was synthesized so as to contain two components: one component adsorbed to the tissue surface, and the other created a steric barrier, thereby preventing cell interactions with the tissue surface, and perhaps altering the wound-healing response that leads to the formation of fibrous adhesions. The component selected for tissue binding was a water-soluble polycation, poly-L-lysine, which can bind to negative sites on glycoproteins, proteoglycans, and cells; and the component selected for steric stabilization was polyethylene glycol, a nonionic polymer that interacts poorly with proteins. Efficacy of lavage with an aqueous solution of the copolymer for the prevention of postsurgical abdominopelvic adhesions was assessed following a standard electrocautery injury of the uterine horns of rats. The copolymer resulted in an 88% reduction in the extent of adhesions that formed. In vitro studies designed to investigate the mechanism of this efficacy indicated that the copolymer may both hinder cell-tissue adhesive interactions and alter the process of fibrin formation.

Polyethyleneglycol-based networks were employed as substrates to graft bioactive peptides to study macrophage interactions with materials. Our overall objective was to utilize biologically active factors to stimulate certain macrophage function on materials suitable for implantation in connective tissues. In this study, we sought to explore the bioactivity of several peptides derived from extracellular matrix adhesion proteins and macrophage-active proteins that are normally soluble. The candidate peptides examined corresponded to residues 63 to 77 of complement component C3a (C3a(63-77)), residues 178 to 207 of interleukin-1 beta (IL1beta(178-207)), residues 1615 to 1624 of fibronectin (FN(1615-1624)), endothelial-macrophage activating polypeptide II, complement component C5a inhibitory sequence, macrophage inhibitory peptide, and YRGDG; materials lacking peptides were used as negative controls. An established murine cell-line IC-21 was employed as a macrophage model, and human dermal fibroblasts were used for comparison. Our results showed that the substrates without grafted peptides were free from artifactual cell adhesion associated with the adsorption of serum or cellularly secreted proteins for long duration of culture. Of all grafted samples, IL1beta(178-207)- and C3a(63-77)-grafted surfaces supported higher adherent macrophage densities. C3a(63-77)- and FN(1615-1624)-grafted surfaces supported higher adherent fibroblast densities. From competitive inhibition studies, cell adhesion was determined to occur in a receptor-peptide specific manner. The presence of grafted YRGDG in addition to IL1beta(178-207), C3a(63-77), or FN(1615-1624) synergistically increased macrophage and fibroblast adhesion. Materials grafted with IL1beta(178-207) or C3a(63-77) co-grafted with or without YRGDG did not support the formation of multinucleated giant cells from the fusion of adherent macrophages in vitro.

Hydrogel membranes formed by interfacially photopolymerizing poly(ethylene glycol) (PEG) diacrylate precursor solution were prepared from PEG diacrylate of molecular weights (MW) ranging from 2000 (2K) to 20000 (20K) with concentrations ranging from 10% to 30% w/w. The effects of PEG diacrylate MW and concentration in the membrane precursor solution upon the diffusivities of vitamin B12, myoglobin, ovalbumin, albumin, and IgG were determined. Regardless of the concentration of the PEG diacrylate in the precursor solution, hydrogels prepared with PEG 2K, 4K, and 8K diacrylate were impermeable to proteins with a size equal to or larger than myoglobin (22 kDa), while hydrogels prepared with PEG 20K diacrylate were impermeable to proteins with a size equal to or larger than ovalbumin (45 kDa). Similarities between hydrogels formed from PEG 2K, 4K, and 8K diacrylates were also seen in calculations of the molecular weight between crosslinks and the mesh size, with values in the range of 150-750 g/mol and 15-35 A, respectively, depending on PEG diacrylate concentration. In contrast, hydrogels formed from PEG 20K diacrylate had molecular weight between crosslinks ranging from 1150 to 2000 g/mol and mesh sizes ranging from 45-70 A, with larger values being observed in membranes polymerized from more dilute PEG diacrylate precursor.

The effect of fibrin matrix micromorphology on neurite growth was investigated by measuring the length of neurites growing in three-dimensional fibrin gels with well characterized micromorphologies. Dorsal root ganglia (DRGs) from 7-day chick embryos were entrapped and cultured in gels made from varying concentrations of fibrinogen (5-15 mg/mL) or calcium (2-10 mM). The length of growing neurites was measured with light videomicroscopy, and the number and diameter of fibrin fiber bundles were measured from scanning electron micrographs. An increase in fibrinogen concentration caused a decrease in the average fiber bundle thickness, an increase in the number of fiber bundles, and a marked decrease in neurite length. Gels made with different calcium concentrations had a similar range of variation in fibrin fiber bundle number or diameter, but these variations had little effect on neurite and associated nonneuronal cell outgrowth. These results provide insights into the process of neurite advance within fibrin and may be useful in the design of fibrin-based materials used for peripheral nerve regeneration. Furthermore, this study provides the first detailed experimental data on the micromorphology of fibrin matrices made from more than 5 mg/mL of fibrinogen and indicates that existing kinetic models of fibrin polymerization do not accurately predict fibrin structure at these higher concentrations.