Bone morphogenetic proteins (BMPs, e.g., BMP2 and 7) are potent mediators for bone repair, however, their clinical use has been limited by their safety and cost-effectiveness. Therefore, innovative strategies that can improve the efficacy of BMPs, and thereby, use a lower dose of exogenous BMPs are highly desired. Inspired by the natural interaction between extracellular matrix (ECM) and growth factors, we hypothesize that bone matrix-mimicking nanofibrous scaffold functionalized with BMP binding moieties can selectively capture and stabilize BMPs, and thereby, promote BMP-induced osteogenic differentiation. To test our hypothesis, a gelatin nanofibrous scaffold was fabricated using thermally induced phase separation together with a porogen leaching technique (TIPS&P) and functionalized by a BMP-binding peptide (BBP) through cross-linking. Our data indicated that BBP decoration largely improved the BMP2 binding and retention capacity of the nanofibrous scaffolds without compromising their macro/microstructure and mechanical properties. Importantly, the BBP-functionalized gelatin scaffolds were able to significantly promote BMP2-induced osteogenic differentiation. Moreover, BBP alone was able to significantly stimulate endogenous BMP2 expression and improve osteogenic differentiation. Compared to other affinity-based drug delivery strategies, e.g., heparin and antibody-mediated growth factor delivering techniques, we expect BBP-functionalized scaffolds will be a safer, more feasible and selective strategy for endogenous BMP stimulating and binding. Therefore, our data suggests a promising application of using the BBP-decorated gelatin nanofibrous scaffold to stimulate/capture BMPs and promote endogenous bone formation in situ in contrast to relying on the administration of high doses of exogenous BMPs and transplantation of cells.
Three-dimensional cellular constructs derived from pluripotent stem cells allow the ex vivo study of neurodevelopment and neurological disease within a spatially organized model. However, the robustness and utility of three-dimensional models is impacted by tissue self-organization, size limitations, nutrient supply, and heterogeneity. In this work, we have utilized the principles of nanoarchitectonics to create a multifunctional polymer/bioceramic composite microsphere system for stem cell culture and differentiation in a chemically defined microenvironment. Microspheres could be customized to produce three-dimensional structures of defined size (ranging from >100 to <350 μm) with lower mechanical properties compared with a thin film. Furthermore, the microspheres softened in solution, approaching more tissue-like mechanical properties over time. With neural stem cells (NSCs) derived from human induced pluripotent stem cells, microsphere-cultured NSCs were able to utilize multiple substrates to promote cell adhesion and proliferation. Prolonged culture of NSC-bound microspheres under differentiating conditions allowed the formation of both neural and glial cell types from control and patient-derived stem cell models. Human NSCs and differentiated neurons could also be cocultured with astrocytes and human umbilical vein endothelial cells, demonstrating application for tissue-engineered modeling of development and human disease. We further demonstrated that microspheres allow the loading and sustained release of multiple recombinant proteins to support cellular maintenance and differentiation. While previous work has principally utilized self-organizing models or protein-rich hydrogels for neural culture, the three-dimensional matrix developed here through nanoarchitectonics represents a chemically defined and robust alternative for the in vitro study of neurodevelopment and nervous system disorders.
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