RESUMEN
Electrospinning produces nanofibrous scaffolds with potential for tissue engineering and wound repair. Spinning parameters control scaffold morphology and properties. BioPEGylation of polyhydroxybutyrate (PHB) introduces terminal hydrophilic groups into the hydrophobic chain, making this natural-synthetic hybrid copolymer more susceptible to humidity. Varying the humidity from 10 to 50% RH during electrospinning had a relatively little effect on polyhydroxybutyrate (PHB) average fiber and pore diameters, which remained around 3.0 and 8.7 µm, respectively. In contrast, fiber and pore diameters for electrospun bioPEGylated PHB scaffolds varied significantly with humidity, peaking at 30% RH (5.5 and 14.1 µm, respectively). While scaffolds showed little change, hydrophobicity decreased linearly with humidity during electrospinning. Compared to solvent-cast films, electrospun scaffolds showed significantly greater average cell spread. A 108% increase for olfactory ensheathing cells (OECs) cultivated on bioPEGylated PHB scaffolds was proportionally greater than their counterparts on electrospun PHB scaffolds, (70%). OECS grown on BioPEGylated PHB scaffolds were over twice the size, 260 ± 20 µm diameter, than those on PHB electrospun scaffolds, 110 ± 18 µm diameter. Electrospun scaffolds also promoted cell health compared to their solvent-cast counterparts, with increases in the mitochondrial activity of 165 ± 13 and 196 ± 13% for PHB and bioPEGylated PHB, respectively. OECS cultivated on electrospun scaffolds of bioPEGylated PHB had significantly better membrane integrities compared to their counterparts on solvent-cast films, 47 ± 5% reducing to 17 ± 6%. The combination of bioPEGylation and humidity during electrospinning permitted significant controllable changes to scaffold morphology and properties. These changes resulted in the significantly greater promotion of cell growth on electrospun bioPEGylated PHB scaffolds compared to their solvent-cast counterparts and electrospun PHB.
RESUMEN
The outcome of peripheral nerve repair following transection is influenced by a number of factors but almost all approaches require anastomosis of the nerve using technically demanding microsurgical procedures. However, the use of sutures presents a number of unavoidable challenges including additional nerve trauma, stimulation of an inflammatory response, and endoneural fibrosis. The objective of the present study was to determine the efficacy of a sutureless approach to nerve repair. A rat sciatic nerve transection model was used with a laser-activated, chitosan-based adhesive (SurgiLux), combined with different forms of extracellular matrix (ECM), known to promote Schwann cell proliferation and nerve growth both in peripheral nerve applications. Following a 5 mm transection of the sciatic nerve, nerve guide wraps were prepared using: (1) laser-activated adhesive (SurgiLux) alone, (2) SurgiLux incorporating ECM (SurgiLux ECM), (3) ECM secured using SurgiLux, and (4) ECM secured using 8-0 Prolene sutures. A no treatment groups was used as a negative control. Evaluation of tissue remodeling was conducted with histolomorphometric assessment of neuroma, integrity of repair, nerve immunolabeling, ratio of myelinated to non-myelinated fibers, and amount of connective tissue. Quantitative and semi-quantitative analysis of the repaired nerve transections at 6 and 12 weeks showed that that SurgiLux incorporating powdered ECM (SurgiLux ECM), SurgiLux alone and ECM alone all improved the healing response compared to no-treatment controls, with less fibrotic tissue and more nerve staining. Histologic scoring showed that the SurgiLux ECM group showed the greatest increase in histologic score between the two time points tested. © 2017 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 106B: 1698-1711, 2018.