螺旋藻对运动疲劳大鼠海马损伤的保护作用及机制研究

目的：研究BDNF/TrkB神经营养信号在运动疲劳大鼠海马神经元损伤中的作用与螺旋藻改善运动致脑海马损伤的作用及其可能的机制。方法：60只雄性SD大鼠随机分为：正常对照组（NC组）、正常+螺旋藻灌胃组（NS组）、运动模型组（EM组）、运动+螺旋藻灌胃组（ES组）、阳性对照组（PC组）,每组12只。EM组、ES组和PC组采用3周的递增式跑台训练建立运动疲劳模型。NC组不施加任何干预,用作对照。NS组和ES组按每天300 mg/kg体重灌胃螺旋藻,PC组以同等体积的人参提取物（1.92 g/kg）灌胃,连续灌胃3周。实验末,用免疫组化和免疫印迹法检测各组大鼠海马BDNF、TrkB、p-TrkB蛋白表达水平,并用尼氏染色法观察海马CA1区形态结构的变化,同时观察大鼠体重等一般情况。结果：与NC组比较,EM组大鼠的体重降低,海马CA1区神经元细胞形态异常且排列紊乱,部分细胞固缩呈不规则变化,部分神经元消失不见,海马BDNF、TrkB和p-TrkB蛋白表达均明显升高（P<0.01）;与EM组比较,ES组大鼠的体重增加,海马神经元损伤得到明显改善,神经元数目和尼氏小体数量增加,神经元排列渐趋规则,形态较完整,ES组海马BDNF、TrkB和p-TrkB蛋白表达均明显升高（P<0.05或P< 0.01）,且与PC组相比,已无明显差别（P>0.05）。结论：BDNF/TrkB神经营养信号可能参与运动致疲劳大鼠海马神经元损伤的修复过程;螺旋藻补充能改善运动疲劳大鼠海马神经元损伤,其原因可能与其上调BDNF和其受体（TrkB）及其受体磷酸化（p-TrkB）蛋白表达而发挥神经保护作用有关。     

Acetyl-DL-leucine对猫单侧前庭神经切断后运动平衡能力和前庭外侧核神经元放电活动恢复的影响

本文观测了Ａｃｅｔｙｌ－ＤＬ－ｌｅｕｃｉｎｅ（ＡＬ、一种抗眩晕药）对猫单侧前庭神经切断后前庭代偿的影响。结果显示：ＡＬ加快术后猫在转动横梁测试中运动平衡能力的恢复,但抑制去传入前庭外侧核神经元（ｎ＝５０６）静息自发放电频率的恢复。ＡＬ促进放电活动与头部左右摆动体位相关的神经元数量和比例的恢复,从术后的第１周的１０％（ｎ＝４５４）,逐渐提高到术后第３周的６０％,第５周的７５％     

复方中药对大鼠力竭运动与恢复过程中端脑神经递质含量的影响

目的：探讨复方中药对运动大鼠中枢神经递质含量的影响,进一步认识中药提高运动能力和促进运动性疲劳恢复的作用机理。方法：选8周龄大鼠64只,随机分成服药组和对照组,服药组灌服中药煎剂8周。然后,每组再分成4个亚组分别于不同状态下断头处死,测其中枢递质含量。结果：服药组大鼠力竭运动时间极显著长于对照组（P〈0．01）;安静时,除谷氨酸（GLU）含量服药组极显著高于对照组（P〈0．01）外、其余各指标无组间显著性差异;定量负荷后,服药组5-羟色胺（5-HT）、5-羟吲哚乙酸（5-HIAA）、弘氨基丁酸（GABA）、多巴胺（DA）含量和5-HT／5-HIAA显著低于对照组,GLU、GLU／GABA和DA／5-HT明显高于对照组;力竭即刻,服药组5-HT、GABA含量和5-HT／5-mAA显著低于对照组（P〈0．05）,GLU含量、DA／5-HT和GLU／GABA显著高于对照组（P〈0．05）;恢复12h。服药组5-HT含量和5-HT／5-HIAA极显著低于对照组（P〈0．01）,GLU、DA、GABA含量和DA／5-HT明显高于对照组（P〈0．05）。结论：在大鼠运动至力竭性的过程中,复方中药制剂有明显抑制5-HT、5-HIAA、DA、GABA生成和促进GLU中枢递质合成的作用,其综合效应表现为兴奋性递质相对显著增多,使中枢神经兴奋性增强、明显延长大鼠运动时间和促进中枢疲劳的恢复。     

早期跑步运动对大鼠脑缺血/再灌注损伤后神经行为与神经元凋亡的影响

目的: 探讨早期跑步运动对大鼠脑缺血后神经行为与神经元凋亡的影响。方法:雄性SD大鼠随机分为4组:假手术+安静组(Sham-St、假手术+运动组(Sham-Ex)、缺血(大脑中动脉闭塞(MCAO) +运动组((MCAO -Ex)和缺血+安静组(MCAO-St),每组15只。MCAO-Ex 和 MCAO-St 组大鼠行MCAO 60 min,再灌注2 d后,MCAO-Ex 和Sham-Ex大鼠在跑步机上进行5 d的30 min/d跑步运动(15 m/min),之后进行神经行为学评价,最后大鼠断头取脑进行TTC方法染色,评估各组大鼠梗死体积以及缺血半影Caspase-3和TUNEL阳性细胞表达水平。结果:与Sham-St相比,MCAO-St和MCAO-Ex大鼠缺血半影区Caspase-3表达均显著升高 (P＜0.05);与MCAO-St 组大鼠相比,MCAO-Ex组大鼠脑梗死体积明显减少,大鼠神经功能评分明显改善,大鼠缺血半影区Caspase-3和TUNEL阳性细胞表达水平显著降低 (P＜0.05)。结论: 早期运动可能通过抑制大鼠脑缺血后神经元凋亡发挥神经保护作用。     

糖尿病大鼠弓状核-海马肥胖抑素通路构成及对胃运动和胃排空的影响

目的: 探究糖尿病大鼠弓状核(ARC)-海马肥胖抑素(obestatin)神经通路构成,以及该通路对大鼠胃运动、胃排空的影响。方法: 健康雄性Wistar大鼠采用果糖溶液诱导胰岛素抵抗加腹腔注射链脲佐菌素的方法制备糖尿病模型,造模之后,随机分为5组:对照组(NS组)、0.1、1和10 pmol obestatin组、obestatin+NBI27914组,每组7只;各组通过置管分别向海马内注射0.5 μl 生理盐水(NS)、obestatin(0.1 pmol、1 pmol、10 pmol)和混合液(10 pmol obestatin + 60 pmol NBI27914),给药后立即记录大鼠胃运动,15 min后进行胃排空研究;通过荧光金(FG)逆行追踪及免疫组化方法比较正常及糖尿病大鼠ARC-海马obestatin神经通路构及ARC obestatin mRNA表达的异同。结果: 与正常大鼠相比,糖尿病大鼠ARC FG/obestatin双标神经元数目显著减少(P＜0.05),ARC obestatin mRNA表达量显著下降(P＜0.05);obestatin各组可剂量依赖性的抑制大鼠胃运动及胃排空(P＜0.05~0.01),obestatin的这些效应可被促肾上腺皮质激素受体1(CRFR1)阻断剂NBI27914部分阻断(P＜0.05);obestatin对糖尿病大鼠胃运动和胃排空的抑制效应显著减弱(P＜0.05)。结论: ARC-海马之间存在obestatin神经和功能通路,参与糖尿病大鼠胃运动及胃排空调控,且CRFR1信号通路参与该过程。该通路功能的减弱可能参与了糖尿病早期胃动力紊乱的发病。     

EGb761对血管性痴呆大鼠海马突触可塑性的影响

目的：探讨银杏叶提取物（EGb761）对血管性痴呆（VD）模型大鼠海马突触可塑性的影响。方法：Morris水迷宫检测大鼠空间学习记忆能力;电生理学方法在体记录大鼠海马长时程增强。结果：各时间点模型组大鼠的逃逸潜伏期（EL）均较假手术组明显延长（P〈0.01）,药物组各亚组大鼠的EL均显著短于模型组（P〈0.01）,但仍长于假手术组（P〈0.01,P〈0.05）。模型组各亚组大鼠长时程增强（LTP）诱导率显著低于假手术组和药物组（P〈0.01）。模型组大鼠各时间点群发峰电位（PS）的相对幅值明显低于假手术组和药物组（P〈0.01,P〈0.05）。假手术组、模型组和药物组各时间点的PS潜伏期无显著差别。结论：VD模型大鼠长时间存在空间学习记忆障碍,EGb761能促进VD模型大鼠海马病理性突触可塑性的恢复,这可能是其促智作用的重要机制。     

替加色罗对内脏高敏感大鼠结肠电及运动的恢复

目的：探讨内脏高敏感大鼠结肠电活动和结肠运动的特点以及替加色罗治疗的疗效。方法：实验分对照组、模型组和替加色罗组,后两组腹腔注射鸡卵清蛋白使大鼠内脏致敏。记录结肠快波、慢波及收缩波,观察消化间期复合肌电及结肠收缩波数目、指数。结果：模型组消化间期复合肌电及结肠收缩波数目、指数均有明显变化。经替加色罗治疗后,各数据均有显著恢复。结论：内脏高敏感大鼠结肠电及运动有明显的异常,替加色罗治疗后能恢复被改变的电及运动。     

肌苷促进脑损伤后神经功能恢复的实验研究

目的：中枢损伤是目前致残率最高的疾病之一,肌苷对于神经损伤后功能恢复的促进作用已经成为研究热点,本研究拟建立一侧前肢瘫痪的大鼠脑外伤模型,证实肌苷治疗促进中枢损伤后上肢功能恢复的有效性,同时初步探索其机制。方法：建立一侧运动皮层冲击损毁的大鼠模型,通过肢体不对称实验、抓取实验等行为学观察证实其惠侧上肢功能受损,后在实验组进行肌苷药物14天,观察28天内上肢功能的恢复情况,与对照组作对比。证实其行为学上的有效性,同时对损伤侧大脑进行顺行BDA染色,探索其内在机制。结果：通过28天的观察发现经过肌苷治疗的的实验组大鼠肢体不对称实验、抓取实验等行为学评分明显好于隐性对照组,顺行BDA染色证实其有促进损伤周围健存皮层突触再生和代偿的作用。结论：肌苷可以促进中枢损伤后大鼠残存神经元得突触再生,使其大脑能在最大程度上代偿其丧失的功能,该药物可能会成为一种新的中枢损伤治疗的前体药物。     

肌苷促进脑损伤后神经功能恢复的实验研究

目的:中枢损伤是目前致残率最高的疾病之一,肌苷对于神经损伤后功能恢复的促进作用已经成为研究热点,本研究拟建立一侧前肢瘫痪的大鼠脑外伤模型,证实肌苷治疗促进中枢损伤后上肢功能恢复的有效性,同时初步探索其机制。方法:建立一侧运动皮层冲击损毁的大鼠模型,通过肢体不对称实验、抓取实验等行为学观察证实其患侧上肢功能受损,后在实验组进行肌苷药物14天,观察28天内上肢功能的恢复情况,与对照组作对比,证实其行为学上的有效性,同时对损伤侧大脑进行顺行BDA染色,探索其内在机制。结果:通过28天的观察发现经过肌苷治疗的的实验组大鼠肢体不对称实验、抓取实验等行为学评分明显好于隐性对照组,顺行BDA染色证实其有促进损伤周围健存皮层突触再生和代偿的作用。结论:肌苷可以促进中枢损伤后大鼠残存神经元得突触再生,使其大脑能在最大程度上代偿其丧失的功能,该药物可能会成为一种新的中枢损伤治疗的前体药物。     

Oxidative stress and modification of synaptic proteins in hippocampus after traumatic brain injury

Oxidative stress, an imbalance between oxidants and antioxidants, contributes to the pathogenesis of traumatic brain injury (TBI). Oxidative neurodegeneration is a key mediator of exacerbated morphological responses and deficits in behavioral recoveries. The present study assessed early hippocampal sequential imbalance to possibly enhance antioxidant therapy. Young adult male Sprague-Dawley rats were subjected to a unilateral moderate cortical contusion. At various times post-TBI, animals were killed and the hippocampus was analyzed for antioxidants (GSH, GSSG, glutathione peroxidase, glutathione reductase, glutathione-S-transferase, glucose-6-phosphate dehydrogenase, superoxide dismutase, and catalase) and oxidants (acrolein, 4-hydroxynonenal, protein carbonyl, and 3-nitrotyrosine). Synaptic markers (synapsin I, postsynaptic density protein 95, synapse-associated protein 97, growth-associated protein 43) were also analyzed. All values were compared with those for sham-operated animals. Significant time-dependent changes in antioxidants were observed as early as 3 h posttrauma and paralleled increases in oxidants (4-hydroxynonenal, acrolein, and protein carbonyl), with peak values obtained at 24-48 h. Time-dependent changes in synaptic proteins (synapsin I, postsynaptic density protein 95, and synapse-associated protein 97) occurred well after levels of oxidants peaked. These results indicate that depletion of antioxidant systems following trauma could adversely affect synaptic function and plasticity. Early onset of oxidative stress suggests that the initial therapeutic window following TBI appears to be relatively short, and it may be necessary to stagger selective types of antioxidant therapy to target specific oxidative components.     

Change in plasma visfatin level after severe traumatic brain injury

Higher plasma visfatin concentration has been associated with ischemic stroke. Thus, we sought to investigate change in plasma visfatin level after traumatic brain injury and to evaluate its relation with disease outcome. Seventy-six healthy controls and 98 patients with acute severe traumatic brain injury were recruited. Twenty-seven patients (27.6%) died and 48 patients (49.0%) suffered from unfavorable outcome (Glasgow outcome scale score of 1–3) in 6 months. On admission, plasma visfatin level was increased in patients than in healthy controls and was highly correlated with Glasgow Coma Scale score. A multivariate analysis identified plasma visfatin level as an independent predictor for 6-month mortality and unfavorable outcome. According to receiver operating characteristic curve analysis, the predictive value of the plasma visfatin concentration was similar to Glasgow Coma Scale score's. In a combined logistic-regression model, visfatin did not improve the predictive value of Glasgow Coma Scale score. Thus, increased plasma visfatin level is associated with 6-month clinical outcomes after severe traumatic brain injury.     

Minocycline improves the functional recovery after traumatic brain injury via inhibition of aquaporin-4

Traumatic brain injury (TBI) is one of the main concerns worldwide as there is still no comprehensive therapeutic intervention. Astrocytic water channel aquaporin-4 (AQP-4) system is closely related to the brain edema, water transport at blood-brain barrier (BBB) and astrocyte function in the central nervous system (CNS). Minocycline, a broad-spectrum semisynthetic tetracycline antibiotic, has shown anti-inflammation, anti-apoptotic, vascular protection and neuroprotective effects on TBI models. Here, we tried to further explore the underlying mechanism of minocycline treatment for TBI, especially the relationship of minocycline and AQP4 during TBI treatment. In present study, we observed that minocycline efficaciously reduces the elevation of AQP4 in TBI mice. Furthermore, minocycline significantly reduced neuronal apoptosis, ameliorated brain edema and BBB disruption after TBI. In addition, the expressions of tight junction protein and astrocyte morphology alteration were optimized by minocycline administration. Similar results were found after treating with TGN-020 (an inhibitor of AQP4) in TBI mice. Moreover, these effects were reversed by cyanamide (CYA) treatment, which notably upregulated AQP4 expression level in vivo. In primary cultured astrocytes, small-interfering RNA (siRNA) AQP4 treatment prevented glutamate-induced astrocyte swelling. To sum up, our study suggests that minocycline improves the functional recovery of TBI through reducing AQP4 level to optimize BBB integrity and astrocyte function, and highlights that the AQP4 may be an important therapeutic target during minocycline treating for TBI.     

The influence of acceleration loading curve characteristics on traumatic brain injury

To prevent brain trauma, understanding the mechanism of injury is essential. Once the mechanism of brain injury has been identified, prevention technologies could then be developed to aid in their prevention. The incidence of brain injury is linked to how the kinematics of a brain injury event affects the internal structures of the brain. As a result it is essential that an attempt be made to describe how the characteristics of the linear and rotational acceleration influence specific traumatic brain injury lesions. As a result, the purpose of this study was to examine the influence of the characteristics of linear and rotational acceleration pulses and how they account for the variance in predicting the outcome of TBI lesions, namely contusion, subdural hematoma (SDH), subarachnoid hemorrhage (SAH), and epidural hematoma (EDH) using a principal components analysis (PCA). Monorail impacts were conducted which simulated falls which caused the TBI lesions. From these reconstructions, the characteristics of the linear and rotational acceleration were determined and used for a PCA analysis. The results indicated that peak resultant acceleration variables did not account for any of the variance in predicting TBI lesions. The majority of the variance was accounted for by duration of the resultant and component linear and rotational acceleration. In addition, the components of linear and rotational acceleration characteristics on the x, y, and z axes accounted for the majority of the remainder of the variance after duration.     

Zinc chelation reduces traumatic brain injury-induced neurogenesis in the subgranular zone of the hippocampal dentate gyrus

Numerous studies have demonstrated that traumatic brain injury (TBI) increases hippocampal neurogenesis in the rodent brain. However, the mechanisms underlying increased neurogenesis after TBI remain unknown. Continuous neurogenesis occurs in the subgranular zone (SGZ) of the hippocampal dentate gyrus (DG) in the adult brain. The mechanism that maintains active neurogenesis in the hippocampal area is not known. A high level of vesicular zinc is localized in the presynaptic terminals of the SGZ (mossy fiber). The mossy fiber of dentate granular cells contains high levels of chelatable zinc in their terminal vesicles, which can be released into the extracellular space during neuronal activity. Previously, our lab presented findings indicating that a possible correlation may exist between synaptic zinc localization and high rates of neurogenesis in this area after hypoglycemia or epilepsy. Using a weight drop animal model to mimic human TBI, we tested our hypothesis that zinc plays a key role in modulating hippocampal neurogenesis after TBI. Thus, we injected a zinc chelator, clioquinol (CQ, 30 mg/kg), into the intraperitoneal space to reduce brain zinc availability twice per day for 1 week. Neuronal death was evaluated with Fluoro Jade-B and NeuN staining to determine whether CQ has neuroprotective effects after TBI. The number of degenerating neurons (FJB (+)) and live neurons (NeuN (+)) was similar in vehicle and in CQ-treated rats at 1 week after TBI. Neurogenesis was evaluated using BrdU, Ki67 and doublecortin (DCX) immunostaining 1 week after TBI. The number of BrdU, Ki67 and DCX positive cell was increased after TBI. However, the number of BrdU, Ki67 and DCX positive cells was significantly decreased by CQ treatment. The present study shows that zinc chelation did not prevent neurodegeneration but did reduce TBI-induced progenitor cell proliferation and neurogenesis. Therefore, this study suggests that zinc has an essential role for modulating hippocampal neurogenesis after TBI.     

牛磺酸对脑创伤大鼠的脑保护作用

目的:探讨牛磺酸(Tau)预处理对弥漫性脑创伤(TBI)大鼠脑皮层超氧化物歧化酶(SOD)活力、丙二醛(MDA)含量、脑含水量(BWC)和脑皮层水孔通道蛋白4(AQP4)表达的影响。方法:复制大鼠TBI模型,分为假手术组(S组)、TBI组(T组)、低剂量Tau组(L组)和高剂量Tau组(H组),用比色法测定脑皮层匀浆液中SOD活力和MDA含量;干/湿法测定BWC;免疫组织化学检测脑皮层AQP4的表达。结果:T组大鼠脑皮层SOD活力显著低于S组,T组MDA含量、BWC和脑皮层AQP4的表达显著高于S组;H、L组脑皮层SOD活力显著高于T组,H、L组MDA含量、BWC和脑皮层AQP4的表达显著低于T组;H、L组之间差异无显著性。结论:Tau可能通过清除TBI后产生的的氧自由基、下调TBI大鼠脑皮层AQP4的表达减轻脑水肿,发挥其脑保护作用。