天冬酰胺内肽酶和胶质细胞在创伤性脑损伤中的激活

摘要 目的：创伤性脑损伤（traumatic brain injury, TBI）缺乏安全有效的治疗手段,亟须寻找新的干预靶点。天冬酰胺内肽酶 (asparaginyl endopeptidase, AEP)在免疫和神经系统疾病中起重要作用,本研究观察了小鼠TBI模型中AEP的激活和变化,探讨AEP对脑损伤和修复的意义。方法：控制性皮层撞击法在小鼠右脑半球制作TBI损伤,在造模后的不同时间点,测定受损脑组织内的乳酸含量和AEP的活性变化,免疫荧光化学染色观察TBI之后3天的胶质细胞活化,以及AEP在其中的表达。结果：TBI造成乳酸在受损脑组织内逐渐堆积,导致小胶质细胞和星形胶质细胞的反应性活化和增生,AEP的上调和激活出现在TBI的继发性脑损伤阶段,AEP在小胶质细胞和星形胶质细胞内均出现上调。结论：AEP有可能参与调控TBI引发的胶质细胞活化,在神经损伤和修复中发挥重要作用。     

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.     

The inhibition of mammalian target of rapamycin (mTOR) in improving inflammatory response after traumatic brain injury

Traumatic brain injury (TBI) provokes primary and secondary damage on endothelium and brain parenchyma, leading neurons die rapidly by necrosis. The mammalian target of rapamycin signalling pathway (mTOR) manages numerous aspects of cellular growth, and it is up-regulated after moderate to severe traumatic brain injury (TBI). Currently, the significance of this increased signalling event for the recovery of brain function is unclear; therefore, we used two different selective inhibitors of mTOR activity to discover the functional role of mTOR inhibition in a mouse model of TBI performed by a controlled cortical impact injury (CCI). Treatment with KU0063794, a dual mTORC1 and mTORC2 inhibitor, and with rapamycin as well-known inhibitor of mTOR, was performed 1 and 4 hours subsequent to TBI. Results proved that mTOR inhibitors, especially KU0063794, significantly improved cognitive and motor recovery after TBI, reducing lesion volumes. Also, treatment with mTOR inhibitors ameliorated the neuroinflammation associated with TBI, showing a diminished neuronal death and astrogliosis after trauma. Our findings propose that the involvement of selective mTORC1/2 inhibitor may represent a therapeutic strategy to improve recovery after brain trauma.     

Rapid Accumulation of Endogenous Tau Oligomers in a Rat Model of Traumatic Brain Injury: POSSIBLE LINK BETWEEN TRAUMATIC BRAIN INJURY AND SPORADIC TAUOPATHIES*

Traumatic brain injury (TBI) is a serious problem that affects millions of people in the United States alone. Multiple concussions or even a single moderate to severe TBI can also predispose individuals to develop a pathologically distinct form of tauopathy-related dementia at an early age. No effective treatments are currently available for TBI or TBI-related dementia; moreover, only recently has insight been gained regarding the mechanisms behind their connection. Here, we used antibodies to detect oligomeric and phosphorylated Tau proteins in a non-transgenic rodent model of parasagittal fluid percussion injury. Oligomeric and phosphorylated Tau proteins were detected 4 and 24 h and 2 weeks post-TBI in injured, but not sham control rats. These findings suggest that diagnostic tools and therapeutics that target only toxic forms of Tau may provide earlier detection and safe, more effective treatments for tauopathies associated with repetitive neurotrauma.     

The gut reaction to traumatic brain injury

Traumatic brain injury (TBI) is a complex disorder that affects millions of people worldwide. The complexity of TBI partly stems from the fact that injuries to the brain instigate non-neurological injuries to other organs such as the intestine. Additionally, genetic variation is thought to play a large role in determining the nature and severity of non-neurological injuries. We recently reported that TBI in flies, as in humans, increases permeability of the intestinal epithelial barrier resulting in hyperglycemia and a higher risk of death. Furthermore, we demonstrated that genetic variation in flies is also pertinent to the complexity of non-neurological injuries following TBI. The goals of this review are to place our findings in the context of what is known about TBI-induced intestinal permeability from studies of TBI patients and rodent TBI models and to draw attention to how studies of the fly TBI model can provide unique insights that may facilitate diagnosis and treatment of TBI.     

Toll-Like Receptor 4 Knockdown Attenuates Brain Damage and Neuroinflammation After Traumatic Brain Injury via Inhibiting Neuronal Autophagy and Astrocyte Activation

Toll-like receptor 4 (TLR4) has been linked to various pathophysiological conditions, such as traumatic brain injury (TBI). It is reported that posttraumatic neuroinflammation is an essential event in the progression of brain injury after TBI. Recent evidences indicate that TLR4 mediates glial phagocytic activity and inflammatory cytokines production. Thus, TLR4 may be an important therapeutic target for neuroinflammatory injury post-TBI. This study was designed to explore potential effects and underlying mechanisms of TLR4 in rats suffered from TBI. TBI model was induced using a controlled cortical impact in rats, and application of TLR4 shRNA silenced TLR4 expression in brain prior to TBI induction. Elevated TLR4 was specifically observed in the hippocampal astrocytes and neurons posttrauma. Interestingly, TLR4 shRNA decreased the concentrations of interleukin (IL)-1β, IL-6, and tissue necrosis factor-α; alleviated hippocampal neuronal damage; reduced brain edema formation; and improved neurological deficits after TBI. Meanwhile, to further explore underlying molecular mechanisms of this neuroprotective effects of TLR4 knockdown, our results showed that TLR4 knockdown significantly inhibited the upregulation of autophagy-associated proteins caused by TBI. More importantly, an autophagy inducer, rapamycin pretreated, could partially abolish neuroprotective effects of TLR4 knockdown on TBI rats. Furthermore, TLR4 silencing markedly suppressed GFAP upregulation and improved cell hypertrophy to attenuate TBI-induced astrocyte activation. Taken together, these findings suggested that TLR4 knockdown ameliorated neuroinflammatory response and brain injury after TBI through suppressing autophagy induction and astrocyte activation.     

Cross-Sectional Analysis of Data from the U.S. Clinical Trials Database Reveals Poor Translational Clinical Trial Effort for Traumatic Brain Injury,Compared with Stroke

Traumatic brain injury (TBI) is an important public health problem, comparable to stroke in incidence and prevalence. Few interventions have proven efficacy in TBI, and clinical trials are, therefore, necessary to advance management in TBI. We describe the current clinical trial landscape in traumatic brain injury and compare it with the trial efforts for stroke. For this, we analysed all stroke and TBI studies registered on the US Clinical Trials (www.clinicaltrials.gov) database over a 10-year period (01/01/2000 to 01/31/2013). This methodology has been previously used to analyse clinical trial efforts in other specialties. We describe the research profile in each area: total number of studies, total number of participants and change in number of research studies over time. We also analysed key study characteristics, such as enrolment number and scope of recruitment. We found a mismatch between relative public health burden and relative research effort in each disease. Despite TBI having comparable prevalence and higher incidence than stroke, it has around one fifth of the number of clinical trials and participant recruitment. Both stroke and TBI have experienced an increase in the number of studies over the examined time period, but the rate of growth for TBI is one third that for stroke. Small-scale (<1000 participants per trial) and single centre studies form the majority of clinical trials in both stroke and TBI, with TBI having significantly fewer studies with international recruitment. We discuss the consequences of these findings and how the situation might be improved. A sustained research effort, entailing increased international collaboration and rethinking the methodology of running clinical trials, is required in order to improve outcomes after traumatic brain injury.     

Molecular mechanisms in the pathogenesis of traumatic brain injury

Traumatic brain injury (TBI) is a serious neurodisorder commonly caused by car accidents, sports related events or violence. Preventive measures are highly recommended to reduce the risk and number of TBI cases. The primary injury to the brain initiates a secondary injury process that spreads via multiple molecular mechanisms in the pathogenesis of TBI. The events leading to both neurodegeneration and functional recovery after TBI are generalized into four categories: (i) primary injury that disrupts brain tissues; (ii) secondary injury that causes pathophysiology in the brain; (iii) inflammatory response that adds to neurodegeneration; and (iv) repair-regeneration that may contribute to neuronal repair and regeneration to some extent following TBI. Destructive multiple mediators of the secondary injury process ultimately dominate over a few intrinsic protective measures, leading to activation of cysteine proteases such as calpain and caspase-3 that cleave key cellular substrates and cause cell death. Experimental studies in rodent models of TBI suggest that treatment with calpain inhibitors (e.g., AK295, SJA6017) and neurotrophic factors (e.g., NGF, BDNF) can prevent neuronal death and dysfunction in TBI. Currently, there is still no precise therapeutic strategy for the prevention of pathogenesis and neurodegeneration following TBI in humans. The search continues to explore new therapeutic targets and development of promising drugs for the treatment of TBI.     

Alterations of microRNAs expression profiles in small extracellular vesicle after traumatic brain injury in mice

Traumatic brain injury (TBI) is one of the leading causes of mortality and morbidity worldwide. Tools available for diagnosis and therapy are limited. Small extracellular vesicle (sEV) microRNAs (miRNAs) play an important role in TBI disease progression. This study aimed to investigate the alterations in sEV miRNAs expression in the mouse brain extracellular space after TBI. Twenty-four C57BL/6J mice were randomly divided into two groups (12/group). The TBI group was subjected to all surgical procedures and fluid percussion injury (FPI). The sham group only underwent surgery. Brain specimens were collected 3 h after TBI/sham. The brain sEV were isolated. Differentially expressed miRNAs were identified. A total of 50 miRNAs were observed to be differentially expressed (fold change ≥1.5 and P<0.05) after TBI, including 5 upregulated and 45 downregulated. The major enriched Gene Ontology terms were metabolic processes, cell, intracellular, organelle, cytoplasm, axon, binding, protein kinase activity, protein binding, and protein dimerization activity. The KEGG pathway analysis predicted that the pathways affected by the variation of miRNAs in sEVs after TBI included the Wnt signaling pathway and NF-κB signaling pathway. The changes in five miRNAs were confirmed by qRT-PCR. In conclusion, this study demonstrated the differential expression of a series of miRNAs in brain sEV after TBI, which might be correlated with post-TBI physiological and pathological processes. The findings might also provide novel targets for further investigating the molecular mechanisms underlying TBI and potential therapeutic interventions.     

Traumatic Brain Injury Precipitates Cognitive Impairment and Extracellular Aβ Aggregation in Alzheimer's Disease Transgenic Mice

Traumatic brain injury (TBI) has become a signature wound of the wars in Iraq and Afghanistan. Many American soldiers, even those undiagnosed but likely suffering from mild TBI, display Alzheimer''s disease (AD)-like cognitive impairments, suggesting a pathological overlap between TBI and AD. This study examined the cognitive and neurohistological effects of TBI in presymptomatic APP/PS1 AD-transgenic mice. AD mice and non-transgenic (NT) mice received an experimental TBI on the right parietal cortex using the controlled cortical impact model. Animals were trained in a water maze task for spatial memory before TBI, and then reevaluated in the same task at two and six weeks post-TBI. The results showed that AD mice with TBI made significantly more errors in the task than AD mice without TBI and NT mice regardless of TBI. A separate group of AD mice and NT mice were evaluated neurohistologically at six weeks after TBI. The number of extracellular beta-amyloid (Aβ)-deposits significantly increased by at least one fold in the cortex of AD mice that received TBI compared to the NT mice that received TBI or the AD and NT mice that underwent sham surgery. A significant decrease in MAP2 positive cells, indicating neuronal loss, was observed in the cortex of both the AD and NT mice that received TBI compared to the AD and NT mice subjected to sham surgery. Similar changes in extracellular Aβ deposits and MAP2 positive cells were also seen in the hippocampus. These results demonstrate for the first time that TBI precipitates cognitive impairment in presymptomatic AD mice, while also confirming extracellular Aβ deposits following TBI. The recognition of this pathological link between TBI and AD should aid in developing novel treatments directed at abrogating cellular injury and extracellular Aβ deposition in the brain.     

Selective Inhibition of Matrix Metalloproteinase-9 Attenuates Secondary Damage Resulting from Severe Traumatic Brain Injury

Traumatic brain injury (TBI) is a leading cause of death and long-term disability. Following the initial insult, severe TBI progresses to a secondary injury phase associated with biochemical and cellular changes. The secondary injury is thought to be responsible for the development of many of the neurological deficits observed after TBI and also provides a window of opportunity for therapeutic intervention. Matrix metalloproteinase-9 (MMP-9 or gelatinase B) expression is elevated in neurological diseases and its activation is an important factor in detrimental outcomes including excitotoxicity, mitochondrial dysfunction and apoptosis, and increases in inflammatory responses and astrogliosis. In this study, we used an experimental mouse model of TBI to examine the role of MMP-9 and the therapeutic potential of SB-3CT, a mechanism-based gelatinase selective inhibitor, in ameliorating the secondary injury. We observed that activation of MMP-9 occurred within one day following TBI, and remained elevated for 7 days after the initial insult. SB-3CT effectively attenuated MMP-9 activity, reduced brain lesion volumes and prevented neuronal loss and dendritic degeneration. Pharmacokinetic studies revealed that SB-3CT and its active metabolite, p-OH SB-3CT, were rapidly absorbed and distributed to the brain. Moreover, SB-3CT treatment mitigated microglial activation and astrogliosis after TBI. Importantly, SB-3CT treatment improved long-term neurobehavioral outcomes, including sensorimotor function, and hippocampus-associated spatial learning and memory. These results demonstrate that MMP-9 is a key target for therapy to attenuate secondary injury cascades and that this class of mechanism-based gelatinase inhibitor–with such desirable pharmacokinetic properties–holds considerable promise as a potential pharmacological treatment of TBI.     

Brain trauma and autophagy: What flies and mice can teach us about conserved responses

Drosophila models have been successfully used to identify many genetic components that affect neurodegenerative disorders. Recently, there has been a growing interest in identifying innate and environmental factors that influence the individual outcomes following traumatic brain injury (TBI). This includes both severe TBI and more subtle, mild TBI (mTBI), which is common in people playing contact sports. Autophagy, as a clearance pathway, exerts protective effects in multiple neurological disease models. In a recent publication, we highlighted the development of a novel repetitive mTBI system using Drosophila, which recapitulates several phenotypes associated with trauma in mammalian models. In particular, flies subjected to mTBI exhibit an acute impairment of the macroautophagy/autophagy pathway that is restored 1 wk following traumatic injury exposure. These phenotypes closely resemble temporary autophagy defects observed in a mouse TBI model. Through these studies, we also identified methods to directly assess autophagic responses in the fly nervous system and laid the groundwork for future studies designed to identify genetic, epigenetic and environmental factors that have an impact on TBI outcomes.     

Ghrelin attenuates brain injury after traumatic brain injury and uncontrolled hemorrhagic shock in rats

Traumatic brain injury (TBI) and hemorrhagic shock often occur concomitantly due to multiple injuries. Gastrointestinal dysfunction occurs frequently in patients with TBI. However, whether alterations in the gastrointestinal system are involved in modulating neuronal damage and recovery after TBI is largely neglected. Ghrelin is a "gut-brain" hormone with multiple functions including antiinflammation and antiapoptosis. The purpose of this study was to determine whether ghrelin attenuates brain injury in a rat model of TBI and uncontrolled hemorrhage (UH). To study this, brain injury was induced by dropping a 450-g weight from 1.5 m onto a steel helmet attached to the skull of male adult rats. Immediately after TBI, a midline laparotomy was performed and both lumbar veins were isolated and severed at the junction with the vena cava. At 45 min after TBI/UH, ghrelin (4, 8 or 16 nmol/rat) or 1 mL normal saline (vehicle) was intravenously administered. Brain levels of TNF-α and IL-6, and cleaved PARP-1 levels in the cortex were measured at 4 h after TBI/UH. Beam balance test, forelimb placing test and hindlimb placing test were used to assess sensorimotor and reflex function. In additional groups of animals, ghrelin (16 nmol/rat) or vehicle was subcutaneously (s.c.) administered daily for 10 d after TBI/UH. The animals were monitored for 28 d to record body weight changes, neurological severity scale and survival. Our results showed that ghrelin downregulated brain levels of TNF-α and IL-6, reduced cortical levels of cleaved PARP-1, improved sensorimotor and reflex functions, and decreased mortality after TBI/UH. Thus, ghrelin has a great potential to be further developed as an effective resuscitation approach for the trauma victims with brain injury and severe blood loss.     

创伤性脑损伤对大鼠海马骨架蛋白及学习记忆功能影响

创伤性脑损伤（traumatic brain injury,TBI）是极为常见的外伤性疾病,致死率和致残率很高。存活者伴随的空间认知功能障碍,给患者家庭和社会造成了极大的负担。目前,对TBI造成的空间记忆障碍缺乏系统研究。脑损伤后海马组织与记忆有关的分子以及组成神经元骨架的分子如何变化研究甚少。本研究采用Wistar大鼠为研究对象,并随机将其分为假手术（sham）组和创伤性脑损伤（TBI）组。TBI组再按致伤后时间长短分为6 h、12 h、24 h、72 h、15 d五个亚组。TBI组应用PinPointTM颅脑撞击器撞击而致伤,sham组不撞击。采用Morris水迷宫评价实验动物空间记忆能力;干湿重法测定脑含水量,评估脑水肿与海马水通道蛋白4（aquaporin-4,AQP-4）的相关性;海马神经元特异性核蛋白（neuron specific nuclear protein,NeuN）标记和免疫荧光检测评估TBI致大鼠神经元丢失情况;通过Western印迹检测TBI致海马骨架相关蛋白质和记忆相关蛋白质含量变化。本研究证实,与sham组相比,TBI组大鼠潜伏期明显增加［（61.98±12.82) s vs.(28.32±8.52) s,n=5,P<0.01,day 15］,探索时间明显缩短［（36.98±0.37) s vs. (73.68±5.09) s,n=5,P<0.01,day15］,表明脑创伤损害了动物的空间参考记忆能力和空间工作记忆能力。与sham组相比,TBI组大鼠海马AQP-4在蛋白质水平上的表达和脑含水量持续升高,15 d恢复正常;在12 h［（3.78±0.74),(83.78±0.35)%］和72 h［（3.49±0.85),(82.28±0.63)%］均形成两个波峰,n=5,P均<0.01,表明继发性脑损伤与持续脑水肿和海马AQP-4在蛋白质上的高表达有关。与sham组相比,NeuN标记和免疫荧光检测发现,TBI后24 h 致大鼠海马神经元丢失严重［（198.2±8.002) vs.(297.2±6.866) cells/mm2, n=5,P<0.01］,表明TBI动物的海马功能受损。与sham相比,TBI组海马神经元树突标志物微管结合蛋白2（microtubule associated proein 2,MAP2）和突触前终末特异性标记物突触素（synaptophysin,SYN）在蛋白质水平均伤后逐步降低（n=5,P均<0.01）,72 h［（0.55±0.05) vs.(1.27±0.08), (0.52±0.14) vs.(1.06±0.16), n=5,P均<0.01］降低最明显;TBI组形成神经元纤维缠结主要成分的过度磷酸化tau（ser404）,伤后逐步升高,72 h［（1.25±0.11)vs. (0.33±0.07), n=5,P<0.01］升高最明显。 MAP2、SYN和过度磷酸化的tau（ser404）检测指标的改变,表明脑损伤致神经元受损,神经元生长和损伤修复能力减弱,最终导致神经元骨架破环,TBI损害了动物的海马空间记忆能力。与sham组相比,TBI组大鼠海马环磷酸腺苷反应元件结合蛋白（cAMP response element binding protein,CREB）和磷酸化CREB ser133(phosphorylated CREB Ser133, pCREB Ser133)含量降低明显（n=5,P均<0.05）,表明脑损伤动物海马的存储记忆能力减弱;TBI组大鼠海马一般调控阻遏蛋白激酶2(general control nonderepressible 2 kinase,GCN2)蛋白质升高明显（n=5,P均<0.05）,表明脑损伤动物海马将新信息转化成长期记忆能力下降。本研究提示,创伤性脑损伤可使大鼠海马神经元骨架破坏,进而导致在学习记忆过程中起重要作用的分子蛋白质下调,抑制记忆储存的蛋白质（GCN2）上调,促使学习记忆功能障碍。     

Classifying mild traumatic brain injuries with functional network analysis

Background

Traumatic brain injury (TBI) represents a critical health problem of which timely diagnosis and treatment remain challenging. TBI is a result of an external force damaging brain tissue, accompanied by delayed pathogenic events which aggravate the injury. Molecular responses to different mild TBI subtypes have not been well characterized. TBI subtype classification is an important step towards the development and application of novel treatments. The computational systems biology approach is proved to be a promising tool in biomarker discovery for central nervous system injury.

Results

In this study, we have performed a network-based analysis on gene expression profiles to identify functional gene subnetworks. The gene expression profiles were obtained from two experimental models of injury in rats: the controlled cortical impact and the fluid percussion injury. Our method integrates protein interaction information with gene expression profiles to identify subnetworks of genes as biomarkers. We have demonstrated that the selected gene subnetworks are more accurate to classify the heterogeneous responses to different injury models, compared to conventional analysis using individual marker genes selected without network information.

Conclusions

The systems approach can lead to a better understanding of the underlying complexities of the molecular responses after TBI and the identified subnetworks will have important prognostic functions for patients who sustain mild TBIs.

     

Reactive Oxygen Species-Activated Nanoprodrug of Ibuprofen for Targeting Traumatic Brain Injury in Mice

Traumatic brain injury (TBI) is an enormous public health problem, with 1.7 million new cases of TBI recorded annually by the Centers for Disease Control. However, TBI has proven to be an extremely challenging condition to treat. Here, we apply a nanoprodrug strategy in a mouse model of TBI. The novel nanoprodrug contains a derivative of the nonsteroidal anti-inflammatory drug (NSAID) ibuprofen in an emulsion with the antioxidant α-tocopherol. The ibuprofen derivative, Ibu₂TEG, contains a tetra ethylene glycol (TEG) spacer consisting of biodegradable ester bonds. The biodegradable ester bonds ensure that the prodrug molecules break down hydrolytically or enzymatically. The drug is labeled with the fluorescent reporter Cy5.5 using nonbiodegradable bonds to 1-octadecanethiol, allowing us to reliably track its accumulation in the brain after TBI. We delivered a moderate injury using a highly reproducible mouse model of closed-skull controlled cortical impact to the parietal region of the cortex, followed by an injection of the nanoprodrug at a dose of 0.2 mg per mouse. The blood brain barrier is known to exhibit increased permeability at the site of injury. We tested for accumulation of the fluorescent drug particles at the site of injury using confocal and bioluminescence imaging of whole brains and brain slices 36 hours after administration. We demonstrated that the drug does accumulate preferentially in the region of injured tissue, likely due to an enhanced permeability and retention (EPR) phenomenon. The use of a nanoprodrug approach to deliver therapeutics in TBI represents a promising potential therapeutic modality.     

创伤性脑损伤对大鼠海马骨架蛋白及学习记忆功能影响

创伤性脑损伤（traumatic brain injury,TBI）是极为常见的外伤性疾病,致死率和致残率很高。存活者伴随的空间认知功能障碍,给患者家庭和社会造成了极大的负担。目前,对TBI造成的空间记忆障碍缺乏系统研究。脑损伤后海马组织与记忆有关的分子以及组成神经元骨架的分子如何变化研究甚少。本研究采用Wistar大鼠为研究对象,并随机将其分为假手术（sham）组和创伤性脑损伤（TBI）组。TBI组再按致伤后时间长短分为6 h、12 h、24 h、72 h、15 d五个亚组。TBI组应用PinPointTM颅脑撞击器撞击而致伤,sham组不撞击。采用Morris水迷宫评价实验动物空间记忆能力;干湿重法测定脑含水量,评估脑水肿与海马水通道蛋白4（aquaporin-4,AQP-4）的相关性;海马神经元特异性核蛋白（neuron specific nuclear protein,NeuN）标记和免疫荧光检测评估TBI致大鼠神经元丢失情况;通过Western印迹检测TBI致海马骨架相关蛋白质和记忆相关蛋白质含量变化。本研究证实,与sham组相比,TBI组大鼠潜伏期明显增加［（61.98±12.82) s vs.(28.32±8.52) s,n=5,P<0.01,day 15］,探索时间明显缩短［（36.98±0.37) s vs. (73.68±5.09) s,n=5,P<0.01,day15］,表明脑创伤损害了动物的空间参考记忆能力和空间工作记忆能力。与sham组相比,TBI组大鼠海马AQP-4在蛋白质水平上的表达和脑含水量持续升高,15 d恢复正常;在12 h［（3.78±0.74),(83.78±0.35)%］和72 h［（3.49±0.85),(82.28±0.63)%］均形成两个波峰,n=5,P均<0.01,表明继发性脑损伤与持续脑水肿和海马AQP-4在蛋白质上的高表达有关。与sham组相比,NeuN标记和免疫荧光检测发现,TBI后24 h 致大鼠海马神经元丢失严重［（198.2±8.002) vs.(297.2±6.866) cells/mm2, n=5,P<0.01］,表明TBI动物的海马功能受损。与sham相比,TBI组海马神经元树突标志物微管结合蛋白2（microtubule associated proein 2,MAP2）和突触前终末特异性标记物突触素（synaptophysin,SYN）在蛋白质水平均伤后逐步降低（n=5,P均<0.01）,72 h［（0.55±0.05) vs.(1.27±0.08), (0.52±0.14) vs.(1.06±0.16), n=5,P均<0.01］降低最明显;TBI组形成神经元纤维缠结主要成分的过度磷酸化tau（ser404）,伤后逐步升高,72 h［（1.25±0.11)vs. (0.33±0.07), n=5,P<0.01］升高最明显。 MAP2、SYN和过度磷酸化的tau（ser404）检测指标的改变,表明脑损伤致神经元受损,神经元生长和损伤修复能力减弱,最终导致神经元骨架破环,TBI损害了动物的海马空间记忆能力。与sham组相比,TBI组大鼠海马环磷酸腺苷反应元件结合蛋白（cAMP response element binding protein,CREB）和磷酸化CREB ser133(phosphorylated CREB Ser133, pCREB Ser133)含量降低明显（n=5,P均<0.05）,表明脑损伤动物海马的存储记忆能力减弱;TBI组大鼠海马一般调控阻遏蛋白激酶2(general control nonderepressible 2 kinase,GCN2)蛋白质升高明显（n=5,P均<0.05）,表明脑损伤动物海马将新信息转化成长期记忆能力下降。本研究提示,创伤性脑损伤可使大鼠海马神经元骨架破坏,进而导致在学习记忆过程中起重要作用的分子蛋白质下调,抑制记忆储存的蛋白质（GCN2）上调,促使学习记忆功能障碍。     

GABAergic circuits of the basolateral amygdala and generation of anxiety after traumatic brain injury

Traumatic brain injury (TBI) has reached epidemic proportions around the world and is a major public health concern in the United States. Approximately 2.8 million individuals sustain a traumatic brain injury and are treated in an Emergency Department yearly in the U.S., and about 50,000 of them die. Persistent symptoms develop in 10–15% of the cases including neuropsychiatric disorders. Anxiety is the second most common neuropsychiatric disorder that develops in those with persistent neuropsychiatric symptoms after TBI. Abnormalities or atrophy in the temporal lobe has been shown in the overwhelming number of TBI cases. The basolateral amygdala (BLA), a temporal lobe structure that consolidates, stores and generates fear and anxiety-based behavioral outputs, is a critical brain region in the anxiety circuitry. In this review, we sought to capture studies that characterized the relationship between human post-traumatic anxiety and structural/functional alterations in the amygdala. We compared the human findings with results obtained with a reproducible mild TBI animal model that demonstrated a direct relationship between the alterations in the BLA and an anxiety-like phenotype. From this analysis, both preliminary insights, and gaps in knowledge, have emerged which may open new directions for the development of rational and more efficacious treatments.