IL-10 lentivirus-laden hydrogel tubes increase spinal progenitor survival and neuronal differentiation after spinal cord injury.

A complex cellular cascade characterizes the pathophysiological response following spinal cord injury (SCI) limiting regeneration. Biomaterial and stem cell combination therapies together have shown synergistic effects, compared to the independent benefits of each intervention, and represent a promising approach towards regaining function after injury. In this study, we combine our polyethylene glycol (PEG) cell delivery platform with lentiviral-mediated overexpression of the anti-inflammatory cytokine interleukin (IL)-10 to improve mouse embryonic Day 14 (E14) spinal progenitor transplant survival. Immediately following injury in a mouse SCI hemisection model, five PEG tubes were implanted followed by direct injection into the tubes of lentivirus encoding for IL-10. Two weeks after tube implantation, mouse E14 spinal progenitors were injected directly into the integrated tubes, which served as a soft substrate for cell transplantation. Together, the tubes with the IL-10 encoding lentivirus improved E14 spinal progenitor survival, assessed at 2 weeks posttransplantation (4 weeks postinjury). On average, 8.1% of E14 spinal progenitors survived in mice receiving IL-10 lentivirus-laden tubes compared with 0.7% in mice receiving transplants without tubes, an 11.5-fold difference. Surviving E14 spinal progenitors gave rise to neurons when injected into tubes. Axon elongation and remyelination were observed, in addition to a significant increase in functional recovery in mice receiving IL-10 lentivirus-laden tubes with E14 spinal progenitor delivery compared to the injury only control by 4 weeks postinjury. All other conditions did not exhibit increased stepping until 8 or 12 weeks postinjury. This system affords increased control over the transplantation microenvironment, offering the potential to improve stem cell-mediated tissue regeneration.

Acute Implantation of Aligned Hydrogel Tubes Supports Delayed Spinal Progenitor Implantation.

An important role of neural stem cell transplantation is repopulating neural and glial cells that actively promote repair following spinal cord injury (SCI). However, stem cell survival after transplantation is severely hampered by the inflammatory environment that arises after SCI. Biomaterials have a demonstrated history of managing post-SCI inflammation and can serve as a vehicle for stem cell delivery. In this study, we utilize macroporous polyethylene glycol (PEG) tubes, which were previously found to modulate the post-SCI microenvironment, to serve as a viable, soft substrate for injecting mouse embryonic day 14 (E14) spinal progenitors 2 weeks after tube implantation into a mouse SCI model. At 2 weeks after transplantation (4 weeks after injury), 4.3% of transplanted E14 spinal progenitors survived when transplanted directly into tubes compared to 0.7% when transplanted into the injury alone. Surviving E14 spinal progenitors exhibited a commitment to the neuronal lineage at 4 weeks post-injury, as assessed by both early and late phenotypic markers. Mice receiving tubes with E14 spinal progenitor transplantations had on average 21 ± 4 axons/mm2 regenerated compared to 8 ± 1 axons/mm2 for the injury only control, which corresponded with a significant increase in remyelination compared to the injury only control, while all conditions exhibited improved forelimb control 4 weeks after injury compared to the injury only. Collectively, we have demonstrated the feasibility of using PEG tubes to modify the implantation site and improve survival of transplanted E14 spinal progenitors.