Loran D. Solorio

Affinity-based growth factor delivery using biodegradable, photocrosslinked heparin-alginate hydrogels

Photocrosslinkable biomaterials are promising for tissue engineering applications due to their capacity to be injected and form hydrogels in situ in a minimally invasive manner. Our group recently reported on the development of photocrosslinked alginate hydrogels with controlled biodegradation rates, mechanical properties, and cell adhesive properties. In this study, we present an affinity-based growth factor delivery system by incorporating heparin into photocrosslinkable alginate hydrogels (HP-ALG), which allows for controlled, prolonged release of therapeutic proteins. Heparin modification had minimal effect on the biodegradation profiles, swelling ratios, and elastic moduli of the hydrogels in media. The release profiles of growth factors from this affinity-based platform were sustained for 3weeks with no initial burst release, and the released growth factors retained their biological activity. Implantation of bone morphogenetic protein-2 (BMP-2)-loaded photocrosslinked alginate hydrogels induced moderate bone formation around the implant periphery. Importantly, BMP-2-loaded photocrosslinked HP-ALG hydrogels induced significantly more osteogenesis than BMP-2-loaded photocrosslinked unmodified alginate hydrogels, with 1.9-fold greater peripheral bone formation and 1.3-fold greater calcium content in the BMP-2-loaded photocrosslinked HP-ALG hydrogels compared to the BMP-2-loaded photocrosslinked unmodified alginate hydrogels after 8weeks implantation. This sustained and controllable growth factor delivery system, with independently controllable physical and cell adhesive properties, may provide a powerful modality for a variety of therapeutic applications.

Decellularized tissue and cell-derived extracellular matrices as scaffolds for orthopaedic tissue engineering

The reconstruction of musculoskeletal defects is a constant challenge for orthopaedic surgeons. Musculoskeletal injuries such as fractures, chondral lesions, infections and tumor debulking can often lead to large tissue voids requiring reconstruction with tissue grafts. Autografts are currently the gold standard in orthopaedic tissue reconstruction; however, there is a limit to the amount of tissue that can be harvested before compromising the donor site. Tissue engineering strategies using allogeneic or xenogeneic decellularized bone, cartilage, skeletal muscle, tendon and ligament have emerged as promising potential alternative treatment. The extracellular matrix provides a natural scaffold for cell attachment, proliferation and differentiation. Decellularization of in vitro cell-derived matrices can also enable the generation of autologous constructs from tissue specific cells or progenitor cells. Although decellularized bone tissue is widely used clinically in orthopaedic applications, the exciting potential of decellularized cartilage, skeletal muscle, tendon and ligament cell-derived matrices has only recently begun to be explored for ultimate translation to the orthopaedic clinic.

Chondrogenic differentiation of human mesenchymal stem cell aggregates via controlled release of TGF‐β1 from incorporated polymer microspheres

Aggregate culture is a useful method for inducing chondrogenic differentiation of human mesenchymal stem cells (hMSC) in a three-dimensional in vitro culture environment. Conventional aggregate culture, however, typically requires repeated growth factor supplementation during media changes, which is both expensive and time-intensive. In addition, homogenous cell differentiation is limited by the diffusion of chondrogenic growth factor from the culture medium into the aggregate and peripheral cell consumption of the growth factor. We have engineered a technology to incorporate growth factor-loaded polymer microspheres within hMSC aggregates themselves. Here, we report on the systems capacity to induce chondrogenesis via sustained delivery of transforming growth factor-beta1 (TGF-beta1). Cartilage formation after 3 weeks in the absence of externally supplied growth factor approached that of aggregates cultured by conventional methods. Chondrogenesis in the central region of the aggregates is enabled at TGF-beta1 levels much lower than those required by conventional culture using exogenously supplied TGF-beta1, which is likely a result of the systems ability to overcome limitations of growth factor diffusion from cell culture media surrounding the exterior of the aggregates. Importantly, the inclusion of growth factor-releasing polymer microspheres in hMSC aggregates could enable in vivo chondrogenesis for cartilage tissue engineering applications without extensive in vitro culture.

Engineered cartilage via self-assembled hMSC sheets with incorporated biodegradable gelatin microspheres releasing transforming growth factor-β1

Self-assembling cell sheets have shown great potential for use in cartilage tissue engineering applications, as they provide an advantageous environment for the chondrogenic induction of human mesenchymal stem cells (hMSCs). We have engineered a system of self-assembled, microsphere-incorporated hMSC sheets capable of forming cartilage in the presence of exogenous transforming growth factor β1 (TGF-β1) or with TGF-β1 released from incorporated microspheres. Gelatin microspheres with two different degrees of crosslinking were used to enable different cell-mediated microsphere degradation rates. Biochemical assays, histological and immunohistochemical analyses, and biomechanical testing were performed to determine biochemical composition, structure, and equilibrium modulus in unconfined compression after 3 weeks of culture. The inclusion of microspheres with or without loaded TGF-β1 significantly increased sheet thickness and compressive equilibrium modulus, and enabled more uniform matrix deposition by comparison to control sheets without microspheres. Sheets incorporated with fast-degrading microspheres containing TGF-β1 produced significantly more GAG and GAG per DNA than all other groups tested and stained more intensely for type II collagen. These findings demonstrate improved cartilage formation in microsphere-incorporated cell sheets, and describe a tailorable system for the chondrogenic induction of hMSCs without necessitating culture in growth factor-containing medium.

Spatiotemporal Regulation of Chondrogenic Differentiation with Controlled Delivery of Transforming Growth Factor-β1 from Gelatin Microspheres in Mesenchymal Stem Cell Aggregates

The precise spatial and temporal presentation of growth factors is critical for cartilage development, during which tightly controlled patterns of signals direct cell behavior and differentiation. Recently, chondrogenic culture of human mesenchymal stem cells (hMSCs) has been improved through the addition of polymer microspheres capable of releasing growth factors directly to cells within cellular aggregates, eliminating the need for culture in transforming growth factor‐β1 (TGF‐β1)‐containing medium. However, the influence of specific patterns of spatiotemporal growth factor presentation on chondrogenesis within microsphere‐incorporated cell systems is unclear. In this study, we examined the effects of altering the chondrogenic microenvironment within hMSC aggregates through varying microsphere amount, growth factor concentration per microsphere, and polymer degradation time. Cartilage formation was evaluated in terms of DNA, glycosaminoglycan, and type II collagen in hMSCs from three donors. Chondrogenesis equivalent to or greater than that of aggregates cultured in medium containing TGF‐β1 was achieved in some conditions, with varied differentiation based on the specific conditions of microsphere incorporation. A more spatially distributed delivery of TGF‐β1 from a larger mass of fast‐degrading microspheres improved differentiation by comparison with delivery from a smaller mass of microspheres with a higher TGF‐β1 concentration per microsphere, although the total amount of growth factor per aggregate was the same. Results also indicated that the rate and degree of chondrogenesis varied on a donor‐to‐donor basis. Overall, this study elucidates the effects of varied conditions of TGF‐β1‐loaded microsphere incorporation on hMSC chondrogenesis, demonstrating that both spatiotemporal growth factor presentation and donor variability influence chondrogenic differentiation within microsphere‐incorporated cellular constructs.

Controlled Dual Growth Factor Delivery From Microparticles Incorporated Within Human Bone Marrow-Derived Mesenchymal Stem Cell Aggregates for Enhanced Bone Tissue Engineering via Endochondral Ossification

Bone tissue engineering via endochondral ossification has been explored by chondrogenically priming cells using soluble mediators for at least 3 weeks to produce a hypertrophic cartilage template. Although recapitulation of endochondral ossification has been achieved, long‐term in vitro culture is required for priming cells through repeated supplementation of inductive factors in the media. To address this challenge, a microparticle‐based growth factor delivery system was engineered to drive endochondral ossification within human bone marrow‐derived mesenchymal stem cell (hMSC) aggregates. Sequential exogenous presentation of soluble transforming growth factor‐β1 (TGF‐β1) and bone morphogenetic protein‐2 (BMP‐2) at various defined time courses resulted in varying degrees of chondrogenesis and osteogenesis as demonstrated by glycosaminoglycan and calcium content. The time course that best induced endochondral ossification was used to guide the development of the microparticle‐based controlled delivery system for TGF‐β1 and BMP‐2. Gelatin microparticles capable of relatively rapid release of TGF‐β1 and mineral‐coated hydroxyapatite microparticles permitting more sustained release of BMP‐2 were then incorporated within hMSC aggregates and cultured for 5 weeks following the predetermined time course for sequential presentation of bioactive signals. Compared with cell‐only aggregates treated with exogenous growth factors, aggregates with incorporated TGF‐β1‐ and BMP‐2‐loaded microparticles exhibited enhanced chondrogenesis and alkaline phosphatase activity at week 2 and a greater degree of mineralization by week 5. Staining for types I and II collagen, osteopontin, and osteocalcin revealed the presence of cartilage and bone. This microparticle‐incorporated system has potential as a readily implantable therapy for healing bone defects without the need for long‐term in vitro chondrogenic priming.

Spatially organized differentiation of mesenchymal stem cells within biphasic microparticle-incorporated high cell density osteochondral tissues.

Giving rise to both bone and cartilage during development, bone marrow-derived mesenchymal stem cells (hMSC) have the unique capacity to generate the complex tissues of the osteochondral interface. Utilizing a scaffold-free hMSC system, biphasic osteochondral constructs are incorporated with two types of growth factor-releasing microparticles to enable spatially organized differentiation. Gelatin microspheres (GM) releasing transforming growth factor-β1 (TGF-β1) combined with hMSC form the chondrogenic phase. The osteogenic phase contains hMSC only, mineral-coated hydroxyapatite microparticles (MCM), or MCM loaded with bone morphogenetic protein-2 (BMP-2), cultured in medium with or without BMP-2. After 4 weeks, TGF-β1 release from GM within the cartilage phase promotes formation of a glycosaminoglycan- and type II collagen-rich matrix, and has a local inhibitory effect on osteogenesis. In the osteogenic phase, type X collagen and osteopontin are produced in all conditions. However, calcification occurs on the outer edges of the chondrogenic phase in some constructs cultured in media containing BMP-2, and alkaline phosphatase levels are elevated, indicating that BMP-2 releasing MCM provides better control over region-specific differentiation. The production of complex, stem cell-derived osteochondral tissues via incorporated microparticles could enable earlier implantation, potentially improving outcomes in the treatment of osteochondral defects.

Mathematical modelling of glycosaminoglycan production by stem cell aggregates incorporated with growth factor‐releasing polymer microspheres

Systems composed of high density cells incorporated with growth factor‐releasing polymer microspheres have recently been shown to promote chondrogenic differentiation and cartilage formation. Within these systems, the effects of spatial and temporal patterning of growth factor release on hyaline cartilage‐specific extracellular matrix production have been examined. However, at present, it is unclear which microsphere densities and growth factor delivery profiles are optimal for inducing human mesenchymal stem cell differentiation and glycosaminoglycan production. A mathematical model to describe glycosaminoglycan production as a function of initial microsphere loading and microsphere degradation rate over a period of 3 weeks is presented. Based on predictions generated by this model, it may be feasible to design a bioactive microsphere system with specific spatiotemporal growth factor presentation characteristics to promote glycosaminoglycan production at controllable rates. Copyright

FTIR imaging analysis of bioactive microsphere incorporated stem cell sheets for osteochondral defect repair

Several tissue engineering approaches have been proposed for articular cartilage repair, but to date there is no consensus on the optimal method. Self-assembling microsphere-incorporated cell sheets have been developed recently for cartilage tissue engineering applications, as they provide an environment for the chondrogenic induction of human mesenchymal stem cells (hMSCs). In the current study, early articular cartilage repair was assessed in a rabbit osteochondral defect model treated with self-assembling hMSC sheets incorporated with bioactive polymer microspheres. Histological sections were evaluated by FTIR imaging for molecular composition. We found that the incorporation of transforming growth factor β1 to the microspheres improved the quality of repair tissue based on increased repair tissue, and increased collagen maturity, at one and three months post-repair. Evaluation of repair tissue at longer timepoints will assess whether these preliminary results will extend to the quality of more mature repair tissue.