RESUMEN
Background: Various cytokines are involved in the pathogenesis of neuromyelitis optica spectrum disorders (NMOSD), but whether serum interleukin-32 (IL-32) level is related to disease activity in cases with NMOSD remains poorly understood. Thus, we investigated the underlying role of IL-32 in NMOSD cases. Methods: Our observation recruited 32 cases with acute NMOSD, 36 NMOSD cases in remission, and 60 healthy individuals in this study. Serum concentrations of IL-32 were detected using ELISA. The associations among IL-32 levels and clinical characteristics were assessed by Spearman correlation coefficient and logistic regression analysis. Results: IL-32 concentrations were strongly increased in cases with acute NMOSD [(52.06 ± 16.56) pg/mL] and NMOSD in remission [(25.78 ± 8.31) pg/mL] compared with healthy controls [(10.83 ± 6.94) pg/mL] (all p <0.001). ROC analysis suggested that the AUC for IL-32 and the combined diagnosis of acute NMOSD was 0.811 (P = 0.026, 95% CI 0.673-0.949), with a sensitivity of 0.800 and a specificity of 0.806. The level of IL-32 was positively correlated with EDSS scores in patients with acute NMOSD (r = 0.620, p < 0.001). EDSS score was independently associated with increased serum levels of LI-32 (B = 1.529, p < 0.001). Conclusion: Higher level of IL-32 is related to disease severity in NMOSD. Therefore, serum IL-32 may be a novel biomarker for acute NMOSD.
RESUMEN
Various stem cells, including neural stem cells (NSCs), have been extensively studied in stroke models, but how to increase neuronal differentiation rate of NSCs remains unresolved, particularly in a damaged environment. The purpose of this study was to investigate the effects of cerebral microvascular endothelial cells (CMECs) on the neurogenesis of NSCs with or without oxygen-glucose deprivation (OGD). The NSCs acquired from primary culture were immunostained to prove cell purity. Survival and proliferation of NSCs were determined after the co-culture with CMECs for 7 days. After removing the CMECs, NSCs were randomly divided into two groups as follows: OGD and non-OGD groups. Both groups were maintained in differentiation culture for 4 days to evaluate the differentiation rate. Mouse embryo fibroblast (MEF) cells co-cultured with NSCs served as control group. NSCs co-cultured with CMECs had an increase in size (on the 7th day: 89.80±26.12 µm vs. 73.08±15.01 µm, P<0.001) (n=12) and number [on the 7th day: 6.33±5.61/high power objective (HP) vs. 2.23±1.61/HP, P<0.001] (n=12) as compared with those co-cultured with MEF cells. After further differentiation culture for 4 days, NSCs co-cultured with CMECs had an increase in neuronal differentiation rate in OGD and non-OGD groups, but not in the control group (15.16% and 16.07% vs. 8.81%; both P<0.001) (n=6). This study provided evidence that OGD could not alter the effects of CMECs in promoting the neuronal differentiation potential of NSCs. These findings may have important implications for the development of new cell therapies for cerebral vascular diseases.