Effects of static pressure on the cytocompatibility of adipose-derived stem cells on electrospun nanofibers / 中国组织工程研究

ABSTRACT

BACKGROUND:Electrospun polylactic acid/polycaprolactone nanofibers (ENF) are a kind of self-synthesized biodegradable material. Our preliminary studies have indicated that the biomaterial exhibits excel ent biocompatibility;however, the research about its mechanics is stil little. OBJECTIVE:To explore the effects of static pressure on the cytocompatibility of adipose-derived stem cel s on the ENF scaffold. METHODS:Adipose-derived stem cel s were seeded onto the ENF scaffold, and then cultured in the low-glucose DMEM supplemented with 10%fetal bovine serum. The mixed constructs were submitted to the static pressure at 0, 15, 30, and 45 kPa for 4 hours using a static pressure device, respectively. Subsequently, the proliferation, adhesion and viability of adipose-derived stem cel s on the ENF scaffold were detected using MTT assay and living/dead staining to evaluate the cytocompatibility. RESULTS AND CONCLUSION:MTT assay showed that there were significant differences in absorbance values among groups by one-way analysis of variance after 4 hours of loading with different static pressures in vitro. Under 0-30 kPa static pressure, the absorbance values increased with static pressure, but the absorbance values declined until the pressure reached 45 kPa, and multiple comparisons between groups showed significant difference. The significant differences in the cel attachment percentage by MTT assay could be found among groups. The living/dead staining results supported the above findings. Furthermore, the significant differences in percentage of living cel s among groups were shown using either one-way analysis of variance or paired t test. In conclusion, the appropriate static pressure can promote the cytocompatibility, proliferation, adhesion and viability of adipose-derived stem cel s on the ENF scaffold. But the excessive pressure is likely to inhibit the cel ular biological behaviors, thus affecting cytocompatibility of adipose-derived stem cel s with the ENF scaffold.