Scaffold-mediated lentiviral transduction for functional tissue engineering of cartilage.

The ability to develop tissue constructs with matrix composition and biomechanical properties that promote rapid tissue repair or regeneration remains an enduring challenge in musculoskeletal engineering. Current approaches require extensive cell manipulation ex vivo, using exogenous growth factors to drive tissue-specific differentiation, matrix accumulation, and mechanical properties, thus limiting their potential clinical utility. The ability to induce and maintain differentiation of stem cells in situ could bypass these steps and enhance the success of engineering approaches for tissue regeneration. The goal of this study was to generate a self-contained bioactive scaffold capable of mediating stem cell differentiation and formation of a cartilaginous extracellular matrix (ECM) using a lentivirus-based method. We first showed that poly-L-lysine could immobilize lentivirus to poly(ε-caprolactone) films and facilitate human mesenchymal stem cell (hMSC) transduction. We then demonstrated that scaffold-mediated gene delivery of transforming growth factor ß3 (TGF-ß3), using a 3D woven poly(ε-caprolactone) scaffold, induced robust cartilaginous ECM formation by hMSCs. Chondrogenesis induced by scaffold-mediated gene delivery was as effective as traditional differentiation protocols involving medium supplementation with TGF-ß3, as assessed by gene expression, biochemical, and biomechanical analyses. Using lentiviral vectors immobilized on a biomechanically functional scaffold, we have developed a system to achieve sustained transgene expression and ECM formation by hMSCs. This method opens new avenues in the development of bioactive implants that circumvent the need for ex vivo tissue generation by enabling the long-term goal of in situ tissue engineering.

A novel process for optimizing musculoskeletal allograft tissue to improve safety, ultrastructural properties, and cell infiltration.

BACKGROUND: This study evaluated the properties of scaffold derived from freeze-dried human Achilles tendon allograft for use in anterior cruciate ligament (ACL) reconstruction. Our hypothesis was that such an allograft could be processed using a method to remove cellular and infectious material, producing a cytocompatible, architecturally modified scaffold possessing tensile properties suitable for ACL reconstruction. METHODS: Fifty-two allografts were provided by a tissue bank. Twenty-one were used as controls to assess cellularity, DNA content, microarchitecture, porosity, cytocompatibility, and tensile properties in vitro (n = 13) and in vivo (n = 8). Thirty-one were processed to produce scaffolds that were similarly assessed for these properties in vitro (n = 23) and in vivo (n = 8). The elimination of added enveloped and nonenveloped viruses was also determined in vitro after each processing step. RESULTS: A subjective decrease in cellularity and a significant decrease in DNA content were observed in the scaffolds compared with the allografts from which they had been derived. The porosity was increased significantly, and the scaffolds were cytocompatible in vitro. Processing resulted in significantly increased elongation of the scaffolds (138% of the elongation of the unprocessed allograft) during tensile testing. No other significant differences in tensile properties were observed in vitro or in vivo. The number of infiltrating host cells and the depth to which those cells infiltrated were significantly greater in the scaffolds. No enveloped viruses and only two of 10(8) nonenveloped viruses were detected in the scaffolds after processing, corresponding to a sterility assurance level of 0.2 × 10(-7). CONCLUSIONS: Allografts were processed using a method that removed cellular and infectious material to produce a decellularized, cytocompatible, architecturally modified scaffold with tensile properties that differed minimally from those of human allograft tissue both in vitro and in vivo. The scaffold production process also resulted in an increase in porosity that led to increased cell infiltration in vivo.