Objective:To observe any effect of magnetic stimulation of the primary motor cortex and sacral nerve roots on urinary retention after spinal cord injury.Methods:Forty patients experiencing urine retention after a spinal cord injury were randomly divided into an experimental group and a control group, each of 20. Both groups received conventional treatment and repeated magnetic stimulation of the roots of the sacral nerve. The experimental group also received repeated magnetic stimulation of the bilateral primary motor cortices (M1 region). Bladder capacity and pressure indices, residual urine volume and life quality were evaluated in both groups before and after 8 weeks of treatment.Results:After the treatment, the average maximum bladder pressure, first sensation capacity, residual urine volume and life quality score of both groups had improved significantly, but the improvements in average first sensation capacity, residual urine volume and life quality score of the experimental group were significantly greater than those of the control group. There was, however, no significant difference in the groups′ average maximum bladder pressure after the treatment.Conclusion:Magnetic stimulation of the primary motor cortex and sacral nerve roots can significantly improve the sensory function of the bladder, reduce residual urine volume and improve the life quality of persons experiencing urinary retention after a spinal cord injury.

Objective:To investigate the effect of M1 microglia-derived exosomes (M1-exo) on neuronal injury after oxygen-glucose deprivation and restoration, and to explore its mechanism.Methods:The mouse microglia BV2 cells grown in logarithmic growth phase were added with 100 μg/L liposolysaccharide (LPS) and 20 μg/L interferon-γ (IFN-γ) to induce the polarization of microglia into M1 phenotype. M1 microglia were identified by Western blotting, quantitative real-time polymerase chain reaction (qPCR) and immunofluorescence. The supernatant of M1 microglia was collected, and exosomes were extracted by ExoQuick-TC TM kit. The morphology of exosomes were observed by transmission electron microscope and nanoparticle tracking analysis (NTA), and the expression of characteristic proteins CD9 and CD63 of exosomes were detected by Western blotting. The well-growing mouse neuroblastoma N2a cells were divided into six groups: the cells in group C were conventionally-cultured; and the cells in group O were subjected to oxygen-glucose deprivation for 3 hours followed by restoration of oxygen-glucose supply 24 hours to establish the model of oxygen-glucose deprivation and restoration injury; and the N2a cells in group E were co-cultured with M1-exo 24 hours after oxygen-glucose deprivation 3 hours; NC group, M group and I group constructed negative control, overexpression and knockdown of microRNA-20a-5p (miR-20a-5p) M1-exo, respectively. The succession of transfection was detected by qPCR and N2a cells in group NC, group M and group I were co-cultured with such transfected M1-exo for 24 hours after oxygen-glucose deprivation 3 hours. Cell viability were detected by cell counting kit-8 (CCK-8) assay, cell apoptosis were detected by flow cytometry, and the expression of miR-20a-5p were detected by qPCR. Results:Compared with M0 microglia, the fluorescence intensity and mRNA and protein expressions of CD32 and inducible nitric oxide synthase (iNOS), specific markers of M1 microglia, were increased [CD32 (fluorescence intensity): 36.919±1.541 vs. 3.533±0.351, CD32 mRNA (2 -ΔΔCt): 4.887±0.031 vs. 1.003±0.012, CD32/β-actin: 2.663±0.219 vs. 1.000±0.028; iNOS (fluorescence intensity): 29.513±1.197 vs. 7.933±0.378, iNOS mRNA (2 -ΔΔCt): 4.829±0.177 vs. 1.000±0.016, iNOS/β-actin: 1.991±0.035 vs. 1.000±0.045; all P < 0.01], indicating M1 microglia were successfully activated. Under electron microscopy, M1-exo had round or oval vesicular bodies with obvious membranous structures, with diameters ranging from 100 nm. Western blotting showed that the exosomes expressed specific CD63 and CD9 proteins. Compared with group C, the cell viability was decreased, the apoptosis rate and the expression of miR-20a-5p were significantly increased in group O [cell viability ( A value): 0.540±0.032 vs. 1.001±0.014, apoptosis rate: (19.857±0.910)% vs. (13.508±0.460)%, miR-20a-5p (2 -ΔΔCt): 5.508±0.291 vs. 1.033±0.101, all P < 0.01]. Compared with O group, cell viability was decreased, apoptosis rate and the expression of miR-20a-5p were increased in group E [cell viability ( A value): 0.412±0.029 vs. 0.540±0.032, apoptosis rate: (31.802±0.647)% vs. (19.857±0.910)%, miR-20a-5p (2 -ΔΔCt): 8.912±0.183 vs. 5.508±0.291, all P < 0.01], indicating that M1 microglia-derived exosomes further aggravated the damage of N2a cells after oxygen-glucose deprivation and restoration. Compared with group E, cell viability was decreased, apoptosis rate and the expression of miR-20a-5p were increased in group M [cell viability ( A value): 0.311±0.028 vs. 0.412±0.029, apoptosis rate: (36.343±0.761)% vs. (31.802±0.647)%, miR-20a-5p (2 -ΔΔCt): 32.348±0.348 vs. 8.912±0.183, all P < 0.01]; and the cell viability was increased, apoptosis rate and the expression of miR-20a-5p were decreased in group I [cell viability ( A value): 0.498±0.017 vs. 0.412±0.029, apoptosis rate: (26.437±0.793)% vs. (31.802±0.647)%, miR-20a-5p (2 -ΔΔCt): 6.875±0.219 vs. 8.912±0.183, all P < 0.01]. There was no significant difference in cell viability, apoptosis rate and the expression of miR-20a-5p between group E and group NC. Conclusion:M1 microglia-derived exosomes aggravate the injury of neurons after oxygen and glucose deprivation and reoxygenation, which may be related to miR-20a-5p carried by M1-exo.

BACKGROUND: Radiation (IR)-induced DNA damage triggers cell cycle arrest and has a suppressive effect on the tumor microenvironment (TME). Wee1, a cell cycle regulator, can eliminate G2/M arrest by phosphorylating cyclin-dependent kinase 1 (CDK1). Meanwhile, programed death-1/programed death ligand-1 (PD-1/PDL-1) blockade is closely related to TME. This study aims to investigate the effects and mechanisms of Wee1 inhibitor AZD1775 and anti-PD-1 antibody (anti-PD-1 Ab) on radiosensitization of hepatoma. METHODS: The anti-tumor activity of AZD1775 and IR was determined by 3-(4,5-dimethylthiazol-2-y1)-2,5-diphenyltetrazolium bromide (MTT) assay on human and mouse hepatoma cells HepG2, Hepa1-6, and H22. The anti-hepatoma mechanism of AZD1775 and IR revealed by flow cytometry and Western blot in vitro . A hepatoma subcutaneous xenograft mice model was constructed on Balb/c mice, which were divided into control group, IR group, AZD1775 group, IR + AZD1775 group, IR + anti-PD-1 Ab group, and the IR + AZD1775 + anti-PD-1 Ab group. Cytotoxic CD8 + T cells in TME were analyzed by flow cytometry. RESULTS: Combining IR with AZD1775 synergistically reduced the viability of hepatoma cells in vitro . AZD1775 exhibited antitumor effects by decreasing CDK1 phosphorylation to reverse the IR-induced G2/M arrest and increasing IR-induced DNA damage. AZD1775 treatment also reduced the proportion of PD-1 + /CD8 + T cells in the spleen of hepatoma subcutaneous xenograft mice. Further studies revealed that AZD1775 and anti-PD-1 Ab could enhance the radiosensitivity of hepatoma by enhancing the levels of interferon γ (IFNγ) + or Ki67 + CD8 T cells and decreasing the levels of CD8 + Tregs cells in the tumor and spleen of the hepatoma mice model, indicating that the improvement of TME was manifested by increasing the cytotoxic factor IFNγ expression, enhancing CD8 + T cells proliferation, and weakening CD8 + T cells depletion. CONCLUSIONS This work suggests that AZD1775 and anti-PD-1 Ab synergistically sensitize hepatoma to radiotherapy by enhancing IR-induced DNA damage and improving cytotoxic CD8 + T cells in TME.
Humans ; Animals ; Mice ; Carcinoma, Hepatocellular/radiotherapy* ; Cell Cycle Proteins/metabolism* ; Protein-Tyrosine Kinases/genetics* ; Apoptosis ; Programmed Cell Death 1 Receptor ; Cell Line, Tumor ; G2 Phase Cell Cycle Checkpoints ; Liver Neoplasms/radiotherapy* ; Tumor Microenvironment ; Pyrazoles ; Pyrimidinones