BDNF gene delivery within and beyond templated agarose multi-channel guidance scaffolds enhances peripheral nerve regeneration.

OBJECTIVE: We combined implantation of multi-channel templated agarose scaffolds with growth factor gene delivery to examine whether this combinatorial treatment can enhance peripheral axonal regeneration through long sciatic nerve gaps. APPROACH: 15 mm long scaffolds were templated into highly organized, strictly linear channels, mimicking the linear organization of natural nerves into fascicles of related function. Scaffolds were filled with syngeneic bone marrow stromal cells (MSCs) secreting the growth factor brain derived neurotrophic factor (BDNF), and lentiviral vectors expressing BDNF were injected into the sciatic nerve segment distal to the scaffold implantation site. MAIN RESULTS: Twelve weeks after injury, scaffolds supported highly linear regeneration of host axons across the 15 mm lesion gap. The incorporation of BDNF-secreting cells into scaffolds significantly increased axonal regeneration, and additional injection of viral vectors expressing BDNF into the distal segment of the transected nerve significantly enhanced axonal regeneration beyond the lesion. SIGNIFICANCE: Combinatorial treatment with multichannel bioengineered scaffolds and distal growth factor delivery significantly improves peripheral nerve repair, rivaling the gold standard of autografts.

Templated agarose scaffolds for the support of motor axon regeneration into sites of complete spinal cord transection.

Bioengineered scaffolds have the potential to support and guide injured axons after spinal cord injury, contributing to neural repair. In previous studies we have reported that templated agarose scaffolds can be fabricated into precise linear arrays and implanted into the partially injured spinal cord, organizing growth and enhancing the distance over which local spinal cord axons and ascending sensory axons extend into a lesion site. However, most human injuries are severe, sparing only thin rims of spinal cord tissue in the margins of a lesion site. Accordingly, in the present study we examined whether template agarose scaffolds seeded with bone marrow stromal cells secreting Brain-Derived Neurotrophic Factor (BDNF) would support regeneration into severe, complete spinal cord transection sites. Moreover, we tested responses of motor axon populations originating from the brainstem. We find that templated agarose scaffolds support motor axon regeneration into a severe spinal cord injury model and organize axons into fascicles of highly linear configuration. BDNF significantly enhances axonal growth. Collectively, these findings support the feasibility of scaffold implantation for enhancing central regeneration after even severe central nervous system injury.

Precision microchannel scaffolds for central and peripheral nervous system repair.

In previous studies, we demonstrated the ability to linearly guide axonal regeneration using scaffolds comprised of precision microchannels 2 mm in length. In this work, we report our efforts to augment the manufacturing process to achieve clinically relevant scaffold dimensions in the centimeter-scale range. By selective etching of multi-component fiber bundles, agarose hydrogel scaffolds with highly ordered, close-packed arrays of microchannels, ranging from 172 to 320 µm, were fabricated with overall dimensions approaching clinically relevant length scales. Cross-sectional analyses determined that the maximum microchannel volume per unit volume of scaffold approached 80%, which is nearly twice that compared to our previously reported study. Statistical analyses at various points along the length of the microchannels also show a significant degree of linearity along the entire length of the scaffold. Two types of multi-component fiber bundle templates were evaluated; polystyrene and poly(methyl methacrylate). The scaffolds consisting of 2 cm long microchannels were fabricated with the poly(methyl methacrylate) fiber-cores exhibited a higher degree of linearity compared to those fabricated using polystyrene fibers. It is believed that the materials process developed in this study is useful for fabricating high aspect ratio microchannels in biocompatible materials with a wide range of geometries for guiding nerve regeneration.