目的 观察乌司他丁对多发伤患者的治疗作用和对肝、肾功能的保护作用。方法 46例多发伤患者随机分为治疗组(23例)和对照组(23例)。治疗组从入院第1天开始,每天静脉点滴乌司他丁10万单位+生理盐水100 ml,每8 h 1次,连续用药6 d,观察患者的临床指标判断疗效,并在入院时以及术后第1、3、5、7天检测谷丙转氨酶(ALT)、谷草转氨酶(AST)、血尿素氮(BUN)、血肌酐(Scr)、血浆肿瘤坏死因子-α(TNF-α)、白细胞介素-2(IL-2)、白细胞介素-6(IL-6)以及白细胞介素-8(IL-8)含量的变化。结果 多发伤患者治疗组平均住院时间及平均住ICU时间均低于对照组,差异有显著性意义(P<0.05); 治疗组术后血浆ALT、AST、BUN及Scr浓度均明显低于对照组(P<0.05); 治疗组术后血浆TNF-α水平逐渐降低,对照组维持在较高水平; IL-2、IL-6及IL-8水平低于对照组(P<0.05)。结论 乌司他丁对多发伤有治疗作用,并能减轻机体的全身炎症反应程度,有保护和改善肝、肾功能的作用。
【摘要】 目的 探讨同种异基因骨髓间充质干细胞(bone mesenchamal stem cells,BMSC)静脉输注对大鼠到小鼠胰岛移植物的功能保护和小鼠糖尿病状态改善。 方法 全骨髓培养法获得C57BL/6小鼠BMSC。不连续梯度离心法分离纯化Sprague-Dawley(SD)大鼠胰岛,将300胰岛当量的胰岛单独或与BMSC联合移植入链脲菌素诱导的糖尿病BALB/c小鼠肾包膜下,并通过尾静脉在移植后0、3和5 d注射CM-DiI标记的BMSC 5×105/只,对照组给于磷酸盐缓冲溶液。移植后监测血糖,第9天处死小鼠,取肝、脾、胸腺、淋巴结和移植胰岛的肾脏,冰冻切片,荧光显微镜观察CM-DiI标记细胞的组织分布;免疫荧光法观察移植物中胰岛素和胰高血糖素表达,评价胰岛的功能。 结果 BMSC静脉输注后主要分布于胸腺,其次是脾脏和淋巴结,肾和肝组织中未观察到BMSC;BMSC联合胰岛移植组血糖控制水平优于其他组,且在第7天的口服糖耐量实验优于单纯胰岛移植组。 结论 与胰岛联合移植的BMSC对受者免疫器官和组织有明显的趋向性,且对胰岛细胞的体内存活有一定保护作用。【Abstract】 Objective To research on the protection function by the allogeneic rat bone mesenchymal stem cells (BMSC) on rat to mouse islet transplantation and the improvement of diabetic state in mouse. Methods BMSC were prepared from C57BL/6 mouse bone marrow cells and identified by flow cytometry (FCM). Islets were isolated from Sprague-Dawley (SD) rats with Ficoll discontinuous centrifugation. CM-DiI labeled BMSC at 5×105 for one mouse were intravenously infused into STZ induced diabetic BALB/c mice after rat to mouse islet transplantation at day 0, 3 and 5. Mice with PBS intravenously infused after islet transplantation were set as the negative controls. Blood glucose was monitored every day at the first 3 days after transplantation, and then monitored every two days. At day 9 after transplantation, spleen, thymus, lymph nods, liver and islets recipient kidney were harvested. Ice slices were prepared and CM-DiI labeled cells were investigated with fluorescence microscope. Results CM-DiI-labeled BMSC were mainly distributed in thymus followed by spleen and lymph nodes. In liver and kidney, there was no red fluorescence observed. The blood sugar control for combined BMSC infusion group was superior to other groups, and the control level of islet combined BMSC infusion group were better than single islet transplantation group in OGTT at day 7. Conclusion Allogeneic BMSC can sustain the insulin secretion of islets in vivo and tend to distribute in immune organs or adenoid tissues after infusion.
Objective To establish a method to isolate the CD4+CD25+ regulatory T cells (Tregs) and to identify the purity and function of these cells. Methods The peripheral blood (8 mL) were collected from the great saphenous vein of 10 rhesus monkeys (4 females and 6 males, aged 4-5 years, and weighing 5-8 kg). The mononuclear cells were isolated with density gradient centrifugation. CD4+ T cells were separated by the Magnetic cell sorting (MACS) negative selection and MACS positive selection. The cell yield rate, the cell viability, and the cell purity were compared between MACS negative selection and MACS positive selection. In CD4+ MACS negative selection, the anti-biotin MicroBeads and biotin-antibody cocktai in CD4+CD25+ Tregs isolation kit non-human primate were used, and in MACS positive selection, the anti-APC MicroBeads in CD4+CD25+ Tregs isolation kit non-human primate and CD4-APC were used. The CD4+ T cells separated by positive selection were selected to obtain CD4+CD25 Tregs with CD25 MicroBeads. The purity, activity, the FoxP3 level, and the suppressive function to concanavalin A (ConA) activated autologous CD4+CD24- effective T cells (Teffs) of CD4+CD25+ Tregs were detected by flow cytometry. Results After CD4+ T cells were separated by MACS negative selection and MACS positive selection, the cell viabilities were all up to 95%, showing no significant difference (P gt; 0.05). The cell yield rate and purity of CD4+ T cells by positive selection were significantly higher than those of CD4+ T cells by negative selection (P lt; 0.05). CD4+CD25+ Tregs can be successfully isolated by MACS double positive selection. The classifying purity was 76.2% ± 8.6%; the cell activity was 93.3% ± 4.7%; and the level of FoxP3 was 74.2% ± 6.9%. The CD4+CD25+ Tregs had suppressive effect on ConA activated autologous CD4+CD25- Teffs. Conclusion MACS double positive selection can be used to isolate high-purity CD4+CD25+ Tregs from the peripheral blood of rhesus monkeys and the process does not influence the activity of CD4+CD25+ Tregs.