Objective To review the research progress of electrospun nanofibers scaffold in nerve tissue engineering. Methods The related l iterature on electrospun nanofibers scaffold in nerve tissue engineering was extensively reviewed and analyzed. Results A variety of material nanofibers scaffolds can be fabricated through electrospinning. The chemical and physical properties of the scaffold can be modified and it was suitable for neuron. The scaffold can bridge the defect of peripheral nerve and partial function can be restored. Conclusion Electrospun nanofibers scaffold has broad appl ication prospects in nerve tissue engineering.
Objective To investigate the biocompatibil ity of silk fibroin nanofibers scaffold with olfactory ensheathing cells (OECs) and to provide an ideal tissue engineered scaffold for the repair of spinal cord injury (SCI). Methods Silk fibroin nanofibers were prepared using electrospinning techniques and were observed by scanning electron microscope (SEM). Freshly isolated OECs from SD rats purified by the modified differential adherent velocity method were cultured. The cells at passage 1 (1 × 104 cells/cm2) were seeded on the poly-l-lysine (control group) and the silk fibroin nanofibers (experimental group) coated coversl ips in Petri dish. At desired time points, the morphological features, growth,and adhesion of the cells were observed using phase contrast inverted microscopy. The OECs were identified by the nerve growth factor receptor p75 (NGFR p75) immunofluorescence staining. The viabil ity of OECs was examined by l ive/dead assay. The prol iferation of OECs was examined by MTT assay. The cytotoxicity of the nanofibers was evaluated. Results The SEM micrographs showed that the nanofibers had a smooth surface with sol id voids among the fibers, interconnecting a porous network, constituted a fibriform three dimensional structure and the average diameter of the fibers was about (260 ± 84) nm. The morphology of OECs on the experimental group was similar to the cell morphology on the control group, the cells distributed along the fibers, and the directions of the cell protrusions were in the same as that of the fibers. Fluorescence microscopy showed that the purity of OECs was 74.21% ± 2.48% in the experimental group and 79.05% ± 2.52% in the control group 5 days after culture. There was no significant difference on cell purity between two groups (P gt; 0.05). The OECs in the experimental group stained positive for NGFR p75 compared to the control group, indicating that the cells in the experimental group still maintained the OECs characteristic phenotype. Live/dead staining showed that high viabil ity was observed in both groups 3 days after culture. There was no significant difference on cell viabil ity between two groups. The prol iferation activity at 1, 3, 5, 7, and 10 days was examined by MTT assay. The absorbency values of the control group and the experimental group had significant differences 3 and 5 days after culture (P lt; 0.05). The relative growth rates were 95.11%, 90.35%, 92.63%, 94.12%, and 94.81%. The cytotoxicity of the material was grade 1 and nonvenomous according to GB/T 16886 standard. Conclusion Silk fibroin nanofibers scaffold has good compatibility with OECs and is a promising tissue engineered scaffold for the repair of SCI.
Objective To investigate the controlled release effect and the anti-cancer cell ability of a 5-FU loaded poly-L-lactic acid (PLLA) nanofibers membrane blending with keratin. Methods Making PLLA and keratin mix together and crosslinking to generate blending solution. Then the anti-cancer drug 5-FU was added into the solution to fabricate nanofibers membrane by high voltage electrospinning method. The micro morphology was observed by scanning electron microscope (SEM). The controlled release effect of 5-FU from the nanofibers membrane was measured by high performance liquid chromatography (HPLC). The cytotoxicity of 5-FU/PLLA keratin nanofibers membrane was evaluated by using 3-(4, 5-dimethylthiazol-2-yl)-2, 5-diphenyltetrazolium bromide (MTT) assay on HCT116 cell lines. At the meantime, cell growth morphology of HCT116 in experiment group were observed by microscope and transmission electron microscope. Results 5-FU could be dispersed homogeneous in the PLLA/keratin nanofibers membrane through SEM. HPLC suggested that 5-FU could be diffused out from the fibers slowly and uniformly, which corresponded the zero order kinetics basically. After different treatment, the longer time the 5-FU/PLLA keratin nanofibers (experiment group) immerse in the medium, the much more swelling, apoptosis, and necrocytosis of the cells were observed. The cell viability for experiment group was (47.5±2.8)% by MTT, while the PLLA keratin nanofibers without 5-FU had no significant impact on cell viability (93.9±2.8)%, which was statistic significance (P<0.01). Conclusion 5-FU/PLLA keratin nanofibers membrane owns good controlled release effect and satisfies cell inhibitory effect against HCT116 cells in vitro,which suggested that it has a promising prospect for clinical therapy.