Tracy A. Tebb

The development of photochemically crosslinked native fibrinogen as a rapidly formed and mechanically strong surgical tissue sealant.

We recently reported the generation of a highly elastic, crosslinked protein biomaterial via a rapid photochemical process using visible light illumination. In light of these findings, we predicted that other unmodified, tyrosine-rich, self-associating proteins might also be susceptible to this covalent crosslinking method. Here we show that unmodified native fibrinogen can also be photochemically crosslinked into an elastic hydrogel biomaterial through the rapid formation of intermolecular dityrosine. Photochemically crosslinked fibrinogen forms tissue sealant bonds at least 5-fold stronger than commercial fibrin glue and is capable of producing maximum bond strength within 20s. In vitro studies showed that components of the photochemical crosslinking reaction are non-toxic to cells. This material will find useful application in various surgical procedures where rapid curing for high strength tissue sealing is required.

Biodegradable and injectable cure-on-demand polyurethane scaffolds for regeneration of articular cartilage.

This paper describes the synthesis and characterization of an injectable methacrylate functionalized urethane-based photopolymerizable prepolymer to form biodegradable hydrogels. The tetramethacrylate prepolymer was based on the reaction between two synthesized compounds, diisocyanato poly(ethylene glycol) and monohydroxy dimethacrylate poly(epsilon-caprolactone) triol. The final prepolymer was hydrated with phosphate-buffered saline (pH 7.4) to yield a biocompatible hydrogel containing up to 86% water. The methacrylate functionalized prepolymer was polymerized using blue light (450 nm) with an initiator, camphorquinone and a photosensitizer, N,N-dimethylaminoethyl methacrylate. The polymer was stable in vitro in culture media over the 28 days tested (1.9% mass loss); in the presence of lipase, around 56% mass loss occurred over the 28 days in vitro. Very little degradation occurred in vivo in rats over the same time period. The polymer was well tolerated with very little capsule formation and a moderate host tissue response. Human chondrocytes, seeded onto Cultispher-S beads, were viable in the tetramethacrylate prepolymer and remained viable during and after polymerization. Chondrocyte-bead-polymer constructs were maintained in static and spinner culture for 8 weeks. During this time, cells remained viable, proliferated and migrated from the beads through the polymer towards the edge of the polymer. New extracellular matrix (ECM) was visualized with Massons trichrome (collagen) and Alcian blue (glycosaminoglycan) staining. Further, the composition of the ECM was typical for articular cartilage with prominent collagen type II and type VI and moderate keratin sulphate, particularly for tissue constructs cultured under dynamic conditions.

Development of porous collagen beads for chondrocyte culture

A method for the preparation of bioresorbable collagen beads with an open porous structure is presented. These beads were prepared from collagen-alginate composite beads by removal of the alginate component. These collagen beads were suitable for rapid proliferation of chondrocytes in a dynamic, spinner culture system. Histology and immuno-histology showed that biochemical markers of chondrocytes are present during this cell proliferation, indicating that there was control of phenotype and that cell de-differentiation had not occurred. Unlike other 3-D scaffolds that have been used, the cells were amplified from very low cell densities and were able to proliferate freely without loss of phenotype.

Preparation of resorbable collagen-based beads for direct use in tissue engineering and cell therapy applications

For tissue engineering and cell therapy applications, expansion of cells such as chondrocytes on beads in spinner culture can provide advantages compared with monolayer culture. The use of resorbable beads that can be included as an integral part of the construct provides the advantage of minimizing the extent of cell handling and eliminating a final trypsin treatment to detach cells from the bead. In this study, we have made various types of beads based on native collagen and denatured collagen (gelatin). The beads have been stabilized by different extents of glutaraldehyde cross-linking, and characterized by a combination of chemical analysis, thermal stability, and microscopy. In vitro examination in the presence and absence of chondrocytes showed that stability increased with the extent of crosslinking and could also be influenced by the manner of fabrication. On the basis of the in vitro stability studies, gelatin beads of a defined stability were shown to resorb over time in subcutaneous implants in nude mice compared with more stable demineralized bone particle (DMB) carriers. These data indicate that for direct use in tissue engineering or cell therapy applications, where resorbable beads can be used for cell expansion and then direct delivery of cells, it is possible to design suitable carrier beads with a range of stabilities that match the implant requirements.

The use of peptide-mediated electrofusion to select monoclonal antibodies directed against specific and homologous regions of the potyvirus coat protein

Whilst monoclonal antibodies (Mab) to potyviruses have been generated, it has not been possible to produce molecules with high specificity or broad reactivity to defined conserved amino acid sequences. In the current study, peptide-mediated electrofusion was used to select for high efficiency antibody-secreting hybridomas after mice were immunized with highly immunogenic viral coat protein. Mice were immunized with coat protein from either one potyvirus (potato virus Y, PVY-D) or a mixture of five distinct potyviruses. Two well-defined peptides were used for selective electrofusions. Peptide-1 was selected from the highly specific N terminal region of PVY-D and peptide-2 from the highly conserved N terminal/core junction region of Johnson grass mosaic virus (JGMV). Conventional PEG-mediated fusions using mice immunized with these peptides did not result in hybridoma formation. On the other hand, electrofusions using biotin-streptavidin to bridge peptide-specific B cells to myeloma cells produced hybridomas secreting antibodies either highly specific to PVY-D or cross-reactive with all potyviruses, depending on the peptide used.

Collagenous tissue formation in association with medical implants

Abstract The host response to a biomaterial includes assembly of an effective collagenous matrix that is critical for the long-term performance of a medical implant. Despite the development of methods that allow detailed examination of the non-cellular matrix components, particularly collagens, relatively little information is available on the extent of molecular variability in the collagen matrix that is associated with various alternative implant materials.

Conformational epitopes on interstitial collagens

The antigenic response to the helical domain of collagens is normally very low, with the nature of the epitopes recognized by antibodies being dependent on the species of origin. Thus, in certain species, for example rabbit, sequential determinants on single alpha-chains are found, whereas in other species such as mouse, conformational epitopes are predominant. A variety of techniques for identification of epitopes, including rotary shadowing, examination of specific fragments and chemical modification reactions are discussed. The application of these techniques is illustrated using a range of monoclonal antibodies to interstitial collagens. These antibodies show that epitopes are distributed over the length of the collagen molecule.

The use of quenching agents to enable immunofluorescent examination of collagen-based biomaterials showing glutaraldehyde-derived autofluorescence

Abstract Examination of glutaraldehyde-treated collagen-based vascular prostheses by immunofluorescence methods indicated that a high degree of autofluorescence was present. This background autofluorescence, which resulted from the glutaraldehyde used in the manufacture of the prostheses, made it very difficult to visualise specific antibody-associated fluorescence. The use of different fluorochromes with a variety of filter blocks did not lead to acceptable conditions, since the autofluorescence showed a broad emission spectrum at various excitation wavelengths. An alternative which proved satisfactory was the use of quenching agents. In particular, 1% Evans Blue led to a shift in the autofluorescent spectrum to longer wavelengths. Specific monoclonal antibody detection of collagen was then possible, with the use of additional filters to mask out the longer autofluorescence wavelengths.