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Abstract

Spinal cord injury is a complex environment, with many conflicting growth factors present at different times throughout the injury timeline. Delivery of multiple growth factors has received mixed results, highlighting a need to consider the timing of delivery for possibly antagonistic growth factors. Cell-mediated degradation of delivery vehicles for delayed release of growth factors offers an attractive way to exploit the highly active immune response in the spinal cord injury environment. In this study, growth factor–loaded gelatin microspheres (GMS) combined with methacrylated hyaluronic acid (MeHA) were electrospun to create GMS fibers (GMSF) for delayed release of growth factors (GFs). GMS were successfully combined with MeHA while electrospinning, with an average fiber diameter of 365 ± 10 nm and 44% ± 8% fiber alignment. GMSF with nerve growth factor (NGF) was tested on dissociated chick dorsal root ganglia cells. We further tested the effect of M1 macrophage-conditioned media (M1CM) to simulate macrophage invasion after spinal cord injury for cell-mediated degradation. We hypothesized that neurons grown on GMSF with loaded NGF would exhibit longer neurites in M1CM, showing a release of functional NGF, as compared with controls. GMSF in M1CM was significantly different from MeHA in serum-free media (SFM) and M0-conditioned media (M0CM), as well as GMSF in M0CM (p < 0.05). Moreover, GMSF + NGF in all media conditions were significantly different from MeHA in SFM and M0CM (p < 0.05). The goal of this study was to develop a biomaterial system where drug delivery is triggered by immune response, allowing for more control and longer exposure to encapsulated drugs. The spinal cord injury microenvironment is known to have a robust immune response, making this immune-medicated drug release system particularly significant for directed repair.

Impact statement

This study harnesses the immune system to trigger drug release following biomaterial implantation. Growth factor loaded microspheres were fabricated and co-electrospun with hyaluronic acid nanofibers for directed cell regeneration following nerve injury. Macrophage-conditioned media was shown to trigger the release of growth factors from the microspheres allowing for immune cell mediated controlled release. Immune modulated drug release would allow for better control of regenerative cues in tissue engineered systems and prevent drug loss during burst release following implantation. This can particularly impact the spinal cord injury microenvironment where a robust immune response has been shown to occur.

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Enzyme-Mediated Nerve Growth Factor Release from Nanofibers Using Gelatin Microspheres

Abstract

Impact statement

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Supplementary Material