Synthetic biodegradable microparticles for articular cartilage tissue engineering.

Articular cartilage tissue engineering procedures require the transplantation of chondrocytes that have been expanded in vitro. The expansion is carried out for a considerable time and can lead to a modulation of cell phenotype. However, microcarrier cultures have been shown to allow cell expansion while maintaining the phenotype. Here, we have used the biodegradable polyester poly(lactide-co-glycolide) (PLGA) in the form of microspheres and irregular shaped microparticles with a diameter between 47 and 210 microm. Surface modification of particles was carried out by ammonia plasma treatment and subsequent adsorption of collagen. Alternatively, particles were modified by partial hydrolysis and subsequent immobilization of an amine-terminated dendrimer. Each surface modification step was characterized by X-ray photoelectron spectroscopy. The effectiveness of the surface modification procedures was demonstrated by in vitro cell culture experiments using sheep articular cartilage chondrocytes. A significant influence of both the particle shape and the surface chemistry on the proliferation rate was observed while the phenotype was maintained independent of the surface chemistry or particle shape. Chondrocytes cultured on PLGA microspheres were further assessed for cartilage tissue formation in collagen type I gels in nude mice. The tissue that were formed showed the appearance of a hyaline-like cartilage and the presence of the microspheres substantially reduced the degree of collagen gel contraction over 1-2 months.

Monoclonal antibodies to type VI collagen demonstrate new tissue augmentation of a collagen-based biomaterial implant.

We developed a panel of highly specific monoclonal antibodies (MAb) to either human or dog collagen Type VI. Various degrees of species crossreactivities were found with ELISA and immunohistology. Because of these differentiating species specificities, which allowed distinction between the original donor collagen and newly formed host collagen, the MAb proved to be valuable tools in examination of explanted samples of an ovine composite vascular prosthesis retrieved from a canine model. With an MAb that reacts with dog but not sheep collagen Type VI, newly synthesized pockets of collagen Type VI could readily be detected within the prosthesis as early as 3 months after implantation. These areas were associated with regions of cell infiltration, presumably derived from the host. This association was also apparent in the newly formed intimal region of the prosthesis where only host cells were found. Another of the MAb, which was positive against human but not sheep collagen, was also used to demonstrate marked deposition of host collagen Type VI in a retrieved human sample of the prosthesis. In this case the antibody was able to detect collagen on a formalin-fixed tissue, which would broaden the scope of its use in clinical and pathological situations. Use of these novel antibody probes provides a rapid marker for new tissue augmentation of implanted biological devices which would be an indicator of the long-term performance of a prosthesis.

Structural stability of long-term implants of a collagen-based vascular prosthesis.

Samples of an ovine collagen-polyester composite device suitable for peripheral revascularization, the Omniflow Vascular Prosthesis, have been retrieved for morphological and immunohistological analyses during and up to 4 years of implantation in a dog aortoiliac by-pass model. At the various sample times, the prosthesis explants were shown to retain their structural integrity, with no aneurysm formation and with little thrombus accumulation. Immunohistological studies on samples of the prosthesis showed that the original ovine collagen was still present after 4 years, and that there had been augmentation by the deposition of new, host-derived connective tissue.

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 Masson's 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.