Stem cell transplants offer significant hope for brain repair following ischemic damage. Pre-clinical work suggests that therapeutic mechanisms may be multi-faceted, incorporating bone-fide circuit reconstruction by transplanted neurons, but also protection/regeneration of host circuitry. Here, we engineered hydrogel scaffolds to form "bio-bridges" within the necrotic lesion cavity, providing physical and trophic support to transplanted human embryonic stem cell-derived cortical progenitors, as well as residual host neurons. Scaffolds were fabricated by the self-assembly of peptides for a laminin-derived epitope (IKVAV), thereby mimicking the brain's major extracellular protein. Following focal ischemia in rats, scaffold-supported cell transplants induced progressive motor improvements over 9 months, compared to cell- or scaffold-only implants. These grafts were larger, exhibited greater neuronal differentiation, and showed enhanced electrophysiological properties reflective of mature, integrated neurons. Varying graft timing post-injury enabled us to attribute repair to both neuroprotection and circuit replacement. These findings highlight strategies to improve the efficiency of stem cell grafts for brain repair.
Successful control of stem cell fate in tissue engineering applications requires the use of sophisticated scaffolds that deliver biological signals to guide growth and differentiation. The complexity of such processes necessitates the presentation of multiple signals in order to effectively mimic the native extracellular matrix (ECM). Here, we establish the use of two biofunctional, minimalist self-assembling peptides (SAPs) to construct the first co-assembled SAP scaffold. Our work characterises this construct, demonstrating that the physical, chemical, and biological properties of the peptides are maintained during the co-assembly process. Importantly, the coassembled system demonstrates superior biological performance relative to the individual SAPs, highlighting the importance of complex ECM mimicry. This work has important implications for future tissue engineering studies.
Functionalized N-fluorenylmethyloxycarbonyl self-assembling peptides are biocompatible in vivo, demonstrating their utility as a cell delivery vehicle for tissue engineering.
Improved control over spatiotemporal delivery of growth factors is needed to enhance tissue repair. Current methods are limited-requiring invasive procedures, poor tissue targeting, and/or limited control over dosage and duration. Incorporation into implantable biomaterials enables stabilized delivery and avoids burst release/fluctuating doses. Here, the physical forces of fibrils formed by self-assembly of epitope-containing peptides are exploited. This biomimetic hydrogel is loaded with neurotrophic factor BDNF via a shear-induced gel-solution transition, unique to noncovalent hydrogels. This results in a biomaterial with three desirable features: a nanofibrillar scaffold, presentation of a laminin epitope, and slow release of BDNF. In a stroke-injury model, synergistic actions of this trimodal strategy on the integration of transplanted human neural progenitor cells, and protection of peri-infarct tissue are identified. These BDNF-functionalized hydrogels promote the integration of transplanted human embryonic stem cell-derived neural progenitors-resulting in larger grafts with greater cortical differentiation, appropriate for neuronal replacement. Furthermore, BDNF promotes the infiltration of host endothelial cells into the graft to augment vascularization of the graft, and adjacent penumbra tissue. These findings demonstrate the benefits of multifaceted tissue-specific hydrogels to provide biomimetics of the host tissue, while sustain protein delivery, to promote endogenous and graft-derived tissue repair.
Self-Assembling PeptidesThe ORCID identification number(s) for the author(s) of this article can be found under https://doi.
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