Liu Ying, Lan Qing, Wang Difen, Chen Xianjun, Yuan Jia, Zhang Hailing
Department of Neurosurgery, the Second Affiliated Hospital of Soochow University, Suzhou 215004, Jiangsu, China (Liu Y, Lan Q); Department of Critical Care Medicine, the Affiliated Hospital of Guizhou Medical University, Guiyang 550004, Guizhou, China (Liu Y, Wang DF, Chen XJ, Yuan J, Zhang HL). Corresponding author: Lan Qing, Email:
Zhonghua Wei Zhong Bing Ji Jiu Yi Xue. 2017 Mar;29(3):260-264. doi: 10.3760/cma.j.issn.2095-4352.2017.03.013.
To observe the effect of hydrogen-rich water on the CD34 expression and angiogenesis in lesion boundary brain tissue of rats with traumatic brain injury (TBI).
A total of 54 adult male Sprague-Dawley (SD) rats were divided into three groups by random number table: namely sham-operated group (sham group), trauma group (TBI group), and trauma + hydrogen-rich water group (TBI+HW group), the rats in each group were subdivided into 1, 3 and 7 days subgroups according to the time points after trauma, with 6 rats in each subgroup. The TBI model was reproduced by using a modified Feency method for free fall impact, and the rats in sham group were not given brain impact after craniotomy. The rats in TBI+HW group were given intraperitoneal injection of hydrogen-rich water (5 mL/kg) after TBI model reproduction, and then once a day until being sacrificed, and the rats in sham group and TBI group were given the same amount of normal saline. The neurological severity scores (NSS) for neurologic deficits were calculated at corresponding time points, and then the rats were sacrificed for brain tissue at 3 mm around lesion boundary. After hematoxylin-eosin (HE) staining, the pathological changes in lesion boundary brain tissue were observed under light microscope. The expression of CD34 cells was observed by immunohistochemical analysis, which markers were used to count the newborn blood capillary sprouts around the traumatic brain tissue. The protein expression of CD34 was determined by Western Blot.
NSS scores at all time points in sham group were 0. NSS scores in TBI and TBI+HW groups showed a decreased tendency with time prolongation after TBI, which showed more significant in TBI+HW group, NSS scores at 3 days and 7 days were significantly lower than those of TBI group (3 day: 8.67±0.52 vs. 11.56±1.94, 7 days: 7.33±0.52 vs. 8.17±0.98, both P < 0.05). Under light microscope, the brain tissue of rats in sham group was normal. After injury, pathological changes in lesion boundary brain tissue in TBI group were characterized by obvious hemorrhagic necrosis, severe brain edema, a large number of degeneration and necrosis of nerve cells and inflammatory cell infiltration, and the pathological changes were more obvious at 3 days. The edema area in TBI+HW group was slightly smaller than that of TBI group, and the surrounding edema was slightly reduced. It was shown by immunohistochemistry that only a very small number of neoformative capillaries were found in sham group. The number of neoformative capillaries in lesion boundary brain tissue was gradually increased with time prolongation in TBI group. The number of neoformative capillaries in TBI+HW group was more significantly, which was significantly higher than that of TBI group at 3 days and 7 days after injury (cells/HP: 10.59±1.88 vs. 8.61±1.22 at 3 days, 23.20±3.16 vs. 17.01±2.64 at 7 days, both P < 0.05). It was shown by Western Blot that the expression of CD34 protein at all time points in TBI group was significantly increased as compared with that of sham group. The expression of CD34 protein at 1 day and 3 days in TBI+HW group was slightly increased as compared with that of TBI group without significant difference, but it was significantly up-regulated at 7 days after injury, which was significantly higher than that of TBI group (gray value: 1.36±0.36 vs. 0.74±0.08, P < 0.05).
Hydrogen-rich water promote CD34 cells home to the site of injured tissue in rats with TBI, is involved in angiogenesis, and improve clinical outcomes during brain functional recovery.
观察富氢水对创伤性脑损伤(TBI)大鼠损伤边界脑组织中CD34表达及血管生成的影响。
将54只成年雄性Sprague-Dawley(SD)大鼠按随机数字表法分为三组:即假手术组(假手术组)、创伤组(TBI组)和创伤+富氢水组(TBI+HW组),每组大鼠再根据创伤后时间点分为1、3和7天亚组,每个亚组6只大鼠。采用改良的Feeney自由落体撞击法复制TBI模型,假手术组大鼠开颅后不给予脑撞击。TBI+HW组大鼠在复制TBI模型后腹腔注射富氢水(5 mL/kg),然后每天一次直至处死,假手术组和TBI组大鼠给予等量生理盐水。在相应时间点计算神经功能缺损的神经严重程度评分(NSS),然后处死大鼠,取损伤边界周围3 mm脑组织。苏木精-伊红(HE)染色后,在光镜下观察损伤边界脑组织的病理变化。采用免疫组化分析观察CD34细胞的表达,以此标记物计数创伤脑组织周围新生毛细血管芽。采用蛋白质印迹法检测CD34的蛋白表达。
假手术组各时间点NSS评分均为0。TBI组和TBI+HW组NSS评分在TBI后随时间延长呈下降趋势,TBI+HW组下降更明显,3天和7天时NSS评分显著低于TBI组(3天:8.67±0.52 vs. 11.56±1.94,7天:7.33±0.52 vs. 8.17±0.98,均P<0.05)。光镜下,假手术组大鼠脑组织正常。损伤后,TBI组损伤边界脑组织病理变化表现为明显的出血坏死、严重脑水肿、大量神经细胞变性坏死及炎症细胞浸润,3天时病理变化更明显。TBI+HW组水肿面积略小于TBI组,周围水肿略有减轻。免疫组化显示,假手术组仅发现极少量新生毛细血管。TBI组损伤边界脑组织新生毛细血管数量随时间延长逐渐增加。TBI+HW组新生毛细血管数量增加更明显,损伤后3天和7天时显著高于TBI组(细胞/HP:3天时10.59±1.88 vs. 8.61±1.22,7天时23.20±3.16 vs. 17.01±2.64,均P<0.05)。蛋白质印迹法显示,TBI组各时间点CD34蛋白表达均显著高于假手术组。TBI+HW组1天和3天时CD34蛋白表达较TBI组略有增加,差异无统计学意义,但损伤后7天时显著上调,显著高于TBI组(灰度值:1.36±0.36 vs. 0.74±0.08,P<0.05)。
富氢水可促进TBI大鼠CD34细胞归巢至损伤组织部位,参与血管生成,并改善脑功能恢复过程中的临床结局。
