Temporal characterisation of pro- and anti-apoptotic mechanisms following diffuse traumatic brain injury in rats.

Few studies have characterised apoptosis in a brain injury model that causes a significant degree of diffuse axonal injury. Such characterisation is essential from a clinical viewpoint since diffuse axonal injury is a major component of human head injury. The present study therefore, examines the expression of active and proactive caspase-3, and the bax, bcl-2 and bcl-x members of the bcl-2 family, to characterise the temporal profile of apoptosis in a model of traumatic brain injury in rats that produces significant diffuse axonal injury. Pentobarbital anaesthetised male Sprague-Dawley rats were injured using the 2m impact-acceleration model of diffuse traumatic brain injury. After injury, diffuse trauma resulted in an increased bax expression followed by induction of caspase-3. The increase in caspase-3 was simultaneous with an increase in anti-apoptotic bcl-2 expression. Bcl-x levels were increased after induction of caspase-3 and the increased levels of bcl-x were sustained to the end of the 5-day observation period. Increased active caspase-3 expression was associated with the appearance of TUNEL positive cells. These cells were detected in different brain regions at different times, with some regions showing no apoptotic cells until 3 days after injury. No TUNEL positive cells were detected at 7 and 14 days after injury. DNA electrophoresis confirmed that DNA fragmentation was maximal at 3 days after injury. Increased active caspase-3 levels were also significantly correlated with increased bcl-2 levels (r=0.80; P<0.001) suggesting that the apoptotic cascade after diffuse traumatic brain injury is a carefully controlled cellular homeostatic response. Pharmacological manipulation of this balance may offer a therapeutic approach for preventing cell death and improving outcome after diffuse traumatic brain injury.     

盐酸纳洛酮治疗大鼠急性颅脑损伤的药效学观察

目的观察盐酸纳洛酮(金尔伦)在大鼠急性颅脑损伤实验模型中促进神经功能恢复的治疗作用,并做量效分析。方法SD大鼠250只,采用Feenly自由落体撞击法建立颅脑损伤模型,随机分成六组,于损伤后30min开始给药。前四组每天分别给予金尔伦0.3mg/kg、1mg/kg、3mg/kg和9mg/kg腹腔注射;阳性对照组:给予胞磷胆碱钠2mg/只腹腔注射;阴性对照组:给予0.5ml/只生理盐水腹腔注射。每天进行MNSS神经功能评分,最长疗程为14d。伤后2d和4d每组随机取8只大鼠,通过干—湿重法计算脑组织的含水量。结果金尔伦治疗组大鼠的神经功能恢复情况明显优于其他两组(P<0.01)。金尔伦1、3、9mg/kg三组的情况优于0.3mg/kg组(P<0.05),而这三组之间没有显著性差异(P>0.05)。金尔伦治疗组大鼠的脑含水量明显低于对照组(P<0.05);金尔伦内部各实验组之间,0.3mg/kg组的脑含水量高于其他三组(P<0.05),其他三组之间无显著性差异(P>0.05)。结论金尔伦能够降低大鼠急性颅脑损伤后的脑水肿,对大鼠的神经功能恢复有明显的促进作用,并在一定范围内随着剂量的增加效果更显著。     

Traumatic brain axonal injury produces sustained decline in intracellular free magnesium concentration

Decline in brain intracellular free magnesium concentration following experimental traumatic brain injury has been widely reported in a number of studies. However, to date, these studies have been confined to focal models of brain injury and temporally limited to the immediate 8-h period post-trauma. Recently, a new model of impact-acceleration brain injury has been developed which produces nonfocal diffuse axonal injury more typical of severe clinical trauma. The present study has used phosphorus magnetic resonance spectroscopy and the rotarod motor test to characterise magnesium homeostasis and neurologic outcome over a period of 8 days after induction of severe impact-acceleration injury in rats. Severe impact-acceleration induced injury resulted in a highly significant and sustained decline in intracellular free magnesium concentration that was apparent for 4 days post-trauma with recovery to preinjury levels by day six. There were no significant changes in pH or ATP concentration at any time point post-injury. All animals demonstrated a significant neurologic deficit over the assessment period. The extended period of magnesium decline after severe diffuse brain trauma suggests that repeated administration may be required for pharmacotherapies targeted at restoring magnesium homeostasis.     

The pathobiology of moderate diffuse traumatic brain injury as identified using a new experimental model of injury in rats

Experimental models of traumatic brain injury have been developed to replicate selected aspects of human head injury, such as contusion, concussion, and/or diffuse axonal injury. Although diffuse axonal injury is a major feature of clinical head injury, relatively few experimental models of diffuse traumatic brain injury (TBI) have been developed, particularly in smaller animals such as rodents. Here, we describe the pathophysiological consequences of moderate diffuse TBI in rats generated by a newly developed, highly controlled, and reproducible model. This model of TBI caused brain edema beginning 20 min after injury and peaking at 24 h post-trauma, as shown by wet weight/dry weight ratios and diffusion-weighted magnetic resonance imaging. Increased permeability of the blood-brain barrier was present up to 4 h post-injury as evaluated using Evans blue dye. Phosphorus magnetic resonance spectroscopy showed significant declines in brain-free magnesium concentration and reduced cytosolic phosphorylation potential at 4 h post-injury. Diffuse axonal damage was demonstrated using manganese-enhanced magnetic resonance imaging, and intracerebral injection of a fluorescent vital dye (Fluoro-Ruby) at 24-h and 7-day post-injury. Morphological evidence of apoptosis and caspase-3 activation were also found in the cerebral hemisphere and brainstem at 24 h after trauma. These results show that this model is capable of reproducing major biochemical and neurological changes of diffuse clinical TBI.     

Upregulation of ICAM-1 and MCP-1 but not of MIP-2 and sensorimotor deficit in response to traumatic axonal injury in rats

The pathophysiology of traumatic axonal injury (TAI) is only partially understood. In this study, we investigated the inflammatory response as well as the extent of neurological deficit in a rat model of traumatic brain injury (TBI). Forty-two adult rats were subjected to moderate impact-acceleration brain injury and their brains were analyzed immunohistochemically for ICAM-1 expression and neutrophil infiltration from 1 hr up to 14 days after trauma. In addition, the chemotactic factors MIP-2 and MCP-1 were measured in brain homogenates by ELISA. For evaluating the neurological deficit, three sensorimotor tests were applied for the first time in this model. In the first 24 hr after trauma, the number of ICAM-1 positive vessels increased up to 4-fold in cortical and subcortical regions compared with sham operated controls (P < 0.05). Maximal ICAM-1 expression (up to 8-fold increase) was detected after 4 days (P < 0.001 vs. 24 hr), returning to control levels in all brain regions by 7 days after trauma. MCP-1 was elevated between 4 hr and 16 hr post-injury as compared with controls. In contrast, neither neutrophil infiltration nor elevation of MIP-2, both events relevant in focal brain injury, could be detected. In all neurological tests, a significant deficit was observed in traumatized rats as compared with sham operated animals from Day 1 post-injury (grasping reflex of the hindpaws: P < 0.001, vibrissae-evoked forelimb placing: P = 0.002, lateral stepping: P = 0.037). In conclusion, after moderate impact acceleration brain injury ICAM-1 upregulation has been demonstrated in the absence of neutrophil infiltration and is paralleled by a selective induction of chemokines, pointing out that individual and distinct inflammatory events occur after diffuse vs. focal TBI.     

Accumulation of amyloid beta and tau and the formation of neurofilament inclusions following diffuse brain injury in the pig.

Brain trauma in humans increases the risk for developing Alzheimer disease (AD) and may induce the acute formation of AD-like plaques containing amyloid beta (A beta). To further explore the potential link between brain trauma and neurodegeneration, we conducted neuropathological studies using a pig model of diffuse brain injury. Brain injury was induced in anesthetized animals via nonimpact head rotational acceleration of 110 degrees over 20 ms in the coronal plane (n = 15 injured, n = 3 noninjured). At 1, 3, 7, and 10 days post-trauma, control and injured animals were euthanized and immunohistochemical analysis was performed on brain sections using antibodies specific for A beta, beta-amyloid precursor protein (betaPP), tau, and neurofilament (NF) proteins. In addition to diffuse axonal pathology, we detected accumulation of A beta and tau that colocalized with immunoreactive betaPP and NF in damaged axons throughout the white matter in all injured animals at 3-10 days post-trauma. In a subset of brain injured animals, diffuse A beta-containing plaque-like profiles were found in both the gray and white matter, and accumulations of tau and NF rich inclusions were observed in neuronal perikarya. These results show that this pig model of diffuse brain injury is characterized by accumulations of proteins that also form pathological aggregates in AD and related neurodegenerative diseases.     

弥漫性脑损伤后代谢型谷氨酸受体亚型4及其激动剂L-AP 4的作用

目的　研究弥漫性脑损伤 (DBI)后大鼠脑皮质代谢型谷氨酸受体亚型 4 (mGluR 4 )及其激动剂L 2 氨基 4 膦酰基丁酸(L AP 4 )的变化及意义。方法　 16 1只SD大鼠随机分为两组。A组包括正常对照组、假手术组及DBI组。用Marmarou弥漫性脑损伤模型 ,制成DBI模型 ,于伤后不同时间进行mGluR 4mRNA原位杂交。B组包括单纯、DBI后生理盐水治疗及DBI后L AP 4治疗组。所有DBI动物伤前进行行为学训练。伤后 1h、12h脑室内分别给予L AP 4 (10 0mM ,10 μl)或生理盐水。大鼠在伤后 1、3、7、14d分批处死前进行运动和行为学检查 ,处死后检测神经元损伤数。结果　与正常对照组相比 ,假手术组阳性神经元数无改变 (P >0 .0 5 ) ;与假手术组相比 ,单纯DBI组mGluR 4mRNA表达于脑损伤后 1h即有明显增加(P <0 .0 1) ,在 6h达到高峰。与DBI后生理盐水治疗组比较 ,DBI后L AP 4治疗组神经元损伤数减少 ,神经功能检查指数增高。结论　mGluR 4参与了DBI的病理生理过程 ,具有神经保护作用。     

Tauroursodeoxycholic acid and secondary damage after spinal cord injury in rats.

Greater clinical understanding of the pivotal role of apoptosis in spinal cord injury (SCI) has led to new and innovative apoptosis-based therapies for patients with an SCI. Tauroursodeoxycholic acid (TUDCA) is a biliary acid with antiapoptotic properties. To our knowledge, this is the first study in the English language to evaluate the therapeutic efficacy of TUDCA in an experimental model of SCI. Thirty rats were randomized into three groups (sham-operated, trauma only, and trauma plus TUDCA treatment) of 10 each. In groups 2 and 3, spinal cord trauma was produced at the T8-T10 level via the Allen weight drop technique. Rats in group 3 were treated with TUDCA (200 mg/kg intraperitoneal) 1 min after trauma. The rats were killed either 24 h or 5 days after injury. The neuroprotective effect of TUDCA on injured spinal cord tissue and the effects of that agent on the recovery of hind-limb function were assessed. The efficacy of treatment was evaluated with histopathologic examination and terminal deoxynucleotidyl transferase-mediated dUTP-biotin nick-end labeling (TUNEL) analysis. Histopathologic characteristics were analyzed by comparison of hematoxylin-and-eosin stained specimens. Neurologic evaluations were performed 24 h, 3 days, and 5 days after trauma. Hind-limb function was assessed with the inclined plane technique of Rivlin and Tator and the modified version of Tarlov's grading scale. Twenty-four hours after injury, there was a significantly higher number of apoptotic cells in the lesioned spinal cord group than in the sham-operated control group. Treatment of the rats with TUDCA significantly reduced the number of apoptotic cells (4.52+/-0.30 vs. 2.31+/-0.24 in group 2) and the degree of tissue injury. Histopathologic examination showed that group 3 rats had better spinal cord architecture compared with group 2 rats. Five days after injury, the mean inclined plane angles in groups 1, 2, and 3 were 65.50 degrees +/- 2.09, 42.00 degrees +/- 2.74, and 53.50 degrees +/- 1.36. Motor grading of the rats revealed a similar trend. These differences were statistically significant (p<0.05). The mechanism of neuroprotection in the treated rats, although not yet elucidated, may be related to the marked antiapoptotic properties of TUDCA. A therapeutic strategy using TUDCA may eventually lead to effective treatment of SCI without toxic effects in humans.     

DNA fragmentation and nuclear endonuclease activity in rat brain after severe closed head injury

Previous studies have suggested that brain cells undergo apoptotic cell death during several neurodegenerative disorders such as Alzheimer's disease, Parkinsonism and ischemic stroke. In the present study, apoptotic DNA fragmentation and activation of nuclear endonuclease were evaluated in rat brain cells after head trauma. Severe closed head injury was induced in rats by the impact of a 450-g weight dropped from a height of 2 m. A 12% mortality was experienced after head trauma. Brain cell nuclei and DNA were isolated at intervals of 3, 10, 24 h, 3 and 10 days after head trauma. DNA fragmentation was measured by the random oligonucleotide-primed synthesis (ROPS) assay and was significantly increased with the maximum level of DNA fragmentation occurring at 10 h after trauma. The DNA and nuclei yields decreased 10 h after injury and remained at a reduced level at all subsequent sampling intervals. The DNA fragmentation induced after severe head trauma was accompanied by an increase in the activity of the Ca/Mg-dependent endonuclease associated with apoptosis. These data indicate that severe head injury is associated with significant brain cell death by apoptosis.     

Changes of mGluR4 and the effects of its specific agonist L-AP4 in a rodent model of diffuse brain injury.

OBJECTIVE: Excessive release of glutamate from nerve terminals following diffuse brain injury (DBI) is thought to contribute to neuronal calcium overload leading to calcium-mediated cell damage. Metabotropic glutamate receptor subtype 4 (mGluR4) is regarded as one of the neuroprotective receptors in mammalian brains. Therefore, the mGluR4 specific agonists might exert neuroprotective effects after DBI. The focus of this study is to examine the changes of expression of mGluR4 after DBI and the role of its specific agonist L-AP4 in vivo.METHODS: One hundred and sixty-one male SD rats were randomized into two groups. Group A included normal control, sham-operated control and DBI group. DBI was produced by Marmarou's diffuse head injury model. The mRNA expression of mGluR4 was detected by hybridization in situ. Group B included DBI alone, DBI treated with normal saline and DBI treated with L-AP4. All DBI rats were trained in a series of performance tests, following which they were subjected to DBI. At 1 and 12 h, animals were injected intracerebroventricularly with L-AP4 (100 mM, 10 microl) or normal saline, respectively. The rats were tested for motor and cognitive performance at 1, 3, 7, 14 days post-injury and the damaged neurons were detected.RESULTS: There was no significant difference between the normal control group and sham-operated group in the expression of mGluR4 (P>0.05). The animals exposed to DBI showed a significant increased expression of mRNA of mGluR4 compared with that of the sham-operated animals 1 h after injuries (P<0.05). At 6 h, the evolution of neuronal expression of mGluR4 in the trauma alone group was relatively static. Compared with saline-treated control animals, rats treated with L-AP4 showed decreased number of damaged neurons and a better motor and cognitive performance.CONCLUSIONS: The increased expression of mGluR4 is an important process in the pathophysiological of DBI and its specific agonist L-AP4 can provide a remarkable neuroprotection against DBI not only at the histopathological level but also in the motor and cognitive performance.     

8-hydroxy-2-(di-n-propylamino)tetralin intervenes with neural cell apoptosis following diffuse axonal injury

Previous studies have reported a neuroprotective effect of 8-hydroxy-2-(di-n-propylamino)tetralin (8-OH-DPAT) against traumatic brain injury. In accordance with the Marmarou method, rat models of diffuse axonal injury were established. 8-OH-DPAT was intraperitoneally injected into model rats 8-OH-DPAT treated rats maintained at constant temperature served as normal temperature controls TUNEL results revealed that neural cell swelling, brain tissue necrosis and cell apoptosis occurred around the injured tissue. Moreover, the number of Bax-, Bcl-2- and caspase-3-positive cells increased at 6 hours after diffuse axonal injury, and peaked at 24 hours. However, brain injury was attenuated, the number of apoptotic cells reduced, Bax and caspase-3 expression decreased, and Bcl-2 expression increased at 6, 12, 24, 72 and 168 hours after diffuse axonal injury in normal temperature control and in 8-OH-DPAT-intervention rats. The difference was most significant at 24 hours. All indices in 8-OH-DPAT-intervention rats were better than those in the constant temperature group. These results suggest that 8-OH-DPAT inhibits Bax and caspase-3 expression, increases Bcl-2 expression, and reduces neural cell apoptosis, resulting in neuroprotection against diffuse axonal injury. This effect is associated with a decrease in brain temperature.     

Activation of caspase-1 dependent interleukins in developmental brain trauma

Focal mechanical cortical trauma triggers diffuse apoptotic neurodegeneration in the developing rat brain which is associated with invasion of brain tissue with inflammatory mediators. We hypothesized that caspase-1 and the two caspase-1-processed cytokines, interleukin (IL)-1beta and IL-18, are involved in trauma-induced neuronal cell death in the developing brain. 7-day-old Wistar rats or C57/BL6 mice were subjected to head trauma using a weight drop device. Animals were sacrificed at defined time points following trauma and brains were processed for histology and molecular analyses. Neuronal cell death in the immature brain peaked at 12-24 h and was accompanied by a marked increase of mRNA and protein levels for caspase-1, IL-1beta and IL-18 within 2 to 12 h following the injury. Caspase-1 levels were elevated for 72 h, whereas IL-1beta decreased earlier at 48 h. IL-18 remained high over a period of 3 days and decreased to normal levels by day 7 after the injury. Intraperitoneal injection of recombinant human IL-18-binding protein (IL-18BP), a specific inhibitor of IL-18, attenuated traumatic brain injury. Mice deficient in IL-18 (IL-18-/-) were protected against trauma-induced brain damage. These findings indicate that IL-18 is involved in trauma-induced neuronal cell death in the immature rodent brain and might serve as a potential therapeutic target.     

Pathophysiological response to experimental diffuse brain trauma differs as a function of developmental age

The purpose of experimental models of traumatic brain injury (TBI) is to reproduce selected aspects of human head injury such as brain edema, contusion or concussion, and functional deficits, among others. As the immature brain may be particularly vulnerable to injury during critical periods of development, and pediatric TBI may cause neurobehavioral deficits, our aim was to develop and characterize as a function of developmental age a model of diffuse TBI (DTBI) with quantifiable functional deficits. We modified a DTBI rat model initially developed by us in adult animals to study the graded response to injury as a function of developmental age - 7-, 14- and 21-day-old rats compared to young adult (3-month-old) animals. Our model caused motor deficits that persisted even after the pups reached adulthood, as well as reduced cognitive performance 2 weeks after injury. Moreover, our model induced prominent edema often seen in pediatric TBI, particularly evident in 7- and 14-day-old animals, as measured by both the wet weight/dry weight method and diffusion-weighted MRI. Blood-brain barrier permeability, as measured by the Evans blue dye technique, peaked at 20 min after trauma in all age groups, with a second peak found only in adult animals at 24 h after injury. Phosphorus MR spectroscopy showed no significant changes in the brain energy metabolism of immature rats with moderate DTBI, in contrast to significant decreases previously identified in adult animals.     

颅脑损伤后肺损伤发病机理的实验研究

目的 研究颅脑损伤后吸致肺损伤发病机理。方法 用自由落体致大鼠颅脑损伤后气管内注入衡盐酸（HCL）模型,通过肺泡灌洗检测肺泡灌洗液（BALF）中蛋白,SOD、MDA、TNF及IL－8含量。结果 误吸致BALF中蛋白增加,SOD下降,MDA升高,炎症介质TNF、IL－8含量显升高,病理显示肺出血、水肿、大量炎细胞浸润,脑损伤加重。结论：伤后误吸不仅对肺直接产生损害,且通过诱导TNF、IL－8的产生,导致PMN在肺内积聚,产生大量O2^－,引发强烈脂质过氧化反应,使肺毛细血管损伤,通透性增加,是肺水种和炎症的病理基础。     

Dexamethasone and indomethacin do not affect brain edema following head injury in rats

Head trauma was induced in rats by a weight-drop device, falling over the exposed skull over the left hemisphere. The neurological state of the rats was evaluated by a neurological severity score at 1 h and 18 h post head trauma. At 18 h post head trauma, rats were decapitated and tissue from the vicinity of the injury and from a corresponding area in the contralateral hemisphere was taken for specific gravity (SG) determination using linear gradient columns. Slices were taken from the same sites for incubation in Krebs-Ringer solution, and the concentrations of prostaglandin (PG)E2, 6-keto-PGF1 alpha, and thromboxane B2 accumulated in the medium during 1 h were measured by radioimmunoassay. In one experimental group, rats were pretreated with intraperitoneal dexamethasone sodium phosphate (4 mg/kg) 18 and 2 h before head trauma, and a third dose was given 8 h post head trauma. Another group was treated with intraperitoneal indomethacin (10 mg/kg) 1 h before and 7 h after head trauma. Other groups were treated immediately and 8 h after head trauma with 4, 8, 15, or 30 mg/kg of dexamethasone sodium phosphate. Another group of rats was treated with free dexamethasone (10 mg/kg) right after head trauma and 8 h later. Head trauma induced edema, as expressed by decreased SG, in the left hemisphere of all traumatized rats. Neither treatment protocol affected the neurological severity score of the injured rats or the SG of the contused hemisphere. PG synthesis, on the other hand, was significantly reduced following indomethacin or free dexamethasone, both in sham and traumatized rats, but not in dexamethasone sodium phosphate-treated rats. We conclude that pretreatment with indomethacin, dexamethasone sodium phosphate, or dexamethasone, used in the present protocols, does not affect posttraumatic cerebral edema. Thus, the role of PGs as mediators of edema formation remains unclear.     

Therapeutic efficacy of Ac-DMQD-CHO, a caspase 3 inhibitor, for rat spinal cord injury.

We investigated the therapeutic efficacy of Ac-DMQD-CHO, a caspase-3 inhibitor, and functional recovery in spinal cord injury in a rat model. Thirty rats were randomized into three groups of 10 each. In groups 2 and 3, spinal cord trauma was produced in the thoracic region. Group 3 rats were treated with Ac-DMQD-CHO. Treatment responses were evaluated based on histopathological and TUNEL staining findings at 24 h and 5 days post-injury. Neurologic performance was assessed during and following treatment. Twenty-four hours after injury, light microscopy examination revealed diffuse hemorrhagic necrosis, edema, vascular thrombi, and polymorphonuclear leukocyte infiltration in group 2 and 3 rats, but cavitation and demyelinization were less prominent in group 3. At this time point, treatment of the rats with Ac-DMQD-CHO significantly reduced the number of apoptotic cells. Traumatic injury to the spinal cord causes apoptosis and administration of Ac-DMQD-CHO decreases apoptosis and improves functional outcome.     

甲基强的松龙对大鼠颅脑损伤后一氧化氮合成酶活性的影响

目的观察甲基强的松龙对大鼠颅脑损伤后血、脑组织中NOS含量的影响,并探讨其作用机制。方法将45只SD大鼠随机分为3组:实验组(20只)、对照组(20只)、正常组(5只),均采用骨窗形成后硬膜外打击法造成鼠脑挫裂伤。正常组麻醉后,只行开颅手术,不作头颅打击,治疗组大鼠致伤后即刻腹腔内注射30mg/kg甲基强的松龙,对照组则注射30mg/kg生理盐水。对照组和治疗组大鼠分别在伤后1h、6h、12h、24h断头取脑,对大鼠脑外伤后脑组织中一氧化碳合成酶(NOS)含量进行检测。结果大鼠脑皮质中的NOS活性在伤后1h较正常组显著性升高(P <0.01),6h开始下降,12～24h降至基础水平。甲基强的松龙治疗组在伤后1h(P <0.01)、6h(P <0.05)NOS活性较损伤组显著性降低。结论颅脑损伤后,受损脑组织中NOS活性升高,甲基强的松龙可通过抑制损伤后NOS活性起到保护创伤神经元的作用。     

Evaluation of cerebral autoregulation following diffuse brain injury in rats

Abstract

The normal cerebral circulation has the ability to maintain a stable cerebral blood flow over a wide range of cerebral perfusion p(essures and this is known as cerebral autoregulation. This autoregulation may be impaired in the injured brain. Closed head injury was induced in 28 Sprague-Dawley rats weighing 400-450 g. Four groups were studied: control group, head injured rat from meter height using 350 g, 400 g and 450 g respectively. CBF, volume velocity was monitored using laser-Doppler flowmetry together with monitoring of ICP and arterial blood pressure. Correlation to assess the relationship between CBF and CPP was done in each animal every hour. If correlation coefficient was> 0.85 and CPP was within normal range, loss of autoregulation was hypothesized. Chi square test, ANOVA test and unpaired Studen(s t-test were done and significant level of p < 0.05 was established. Mean CBF in injured rats was significantly lower than controls (p = 0.028) at the fifth hour. CBV was lower in the group of 450 g 1 m impact than in controls at 3 h (p = 0.04). Velocity in the group ofall injured rats, was significantly lower than in controls at 3 h (p = 0.032) and at 4 h (p = 0.027). Loss ofautoregulation was seen during first four hours after trauma in all groups of rats who sustained injury. Statistical significant difference (p = 0.041) in loss of autoregulation between injured and control animals was seen. No loss of autoregulation was observed in the control group. In conclusion CBF and CPP provide information about loss of autoregulation in diffuse brain injury. Decrease in CBF and increase of ICP is observed as a result ofloss of cerebral autoregulation. Knowledge of loss of autoregulation could give important information and help in the management of head injured patients. [Neural Res 1997; 19: 393-402]     

血晶素诱导血红素氧合酶-1在脑外伤中的表达及意义

目的 探讨血红素氧合酶-1(HO-1)在颅脑外伤中的作用. 方法 48只SD大鼠按照随机数字表法分为血晶素处理组、生理盐水组和假手术组.用液压冲击伤复制颅脑外伤的大模型,伤后予以45mg/100mg体质量血晶素、生理盐水腹腔注射干预HO-1的表达.假手术组只切开头皮,颅骨钻孔.其他不作任何处理.斜坡试验观测大的行为学改变.尾静脉注射伊文思兰测定血脑屏障的通透性.SP免疫组织化学测定HO-1的表达. 结果 血晶素处理组HO-1的表达[(125.52±14.39)个]较生理盐水组[(100.63±12.32)个]和假手术组[(79.37±12.89)个]明显增加,差异有统计学意义(P<0.05).血晶素处理组大鼠斜坡试验时间[(7.38±1.69)s]较生理盐水组[(10.01±1.61)s]缩短,差异有统计学意义(P<0.05).血晶素处理组血脑屏障的通透性较生理盐水组明显降低.差异有统计学意义(P<0.05). 结论 HO-1在颅脑外伤中的表达对中枢神经系统具有保护作用.     

弥漫性轴突损伤胆碱能纤维改变的实验研究

目的通过大鼠弥漫性脑损伤模型观察海马及乳头体内的轴突损伤,了解轴突损伤后上述结构中胆碱酯酶纤维的变化,探讨轴突损伤与伤后记忆功能障碍的相关性.方法用Marmarou介绍的落体打击装置致伤动物,对海马和乳头体区脑组织进行胆碱酯酶(AChE)纤维染色.结果该模型较好地模拟了轴突损伤的表现,简便实用.在这个模型中轴突损伤的最常见部位为桥脑基底部和小脑上脚,其次为大脑半球白质、海马和乳头体.海马结构内含有大量胆碱酯酶阳性染色纤维.与对照组相比中,损伤10天海马CA1区,CA3区,齿状回分子层和乳头体内纤维密度明显低于对照组大鼠(P＜0.01).结论大鼠损伤后海马区和乳头体内胆碱酯酶阳性纤维明显减少,这可能是弥漫性轴突损伤病人记忆功能损害的原因.