Neuronal injury and loss after traumatic brain injury: time course and regional variability

We have examined regional neuronal injury after traumatic brain injury using Fluoro-Jade, an acidic dye that exhibits a marked affinity for both the degenerating neuronal cell body and its processes and have determined the extent to which early injury corresponds to regional patterns of neuronal loss. Rats (n=45) were subjected to lateral fluid percussion brain injury and euthanized at 3 h to 28 days post injury. Complementary Fluoro-Jade, silver impregnation methods and TUNEL were used to assess neuronal injury. Neuronal loss was evaluated in sections immunostained for NeuN, a neuronal specific nuclear protein. Overt neuronal cell loss was evident by 7 days post injury in the cortex, hippocampus and thalamus. Injured neurons were apparent in the ipsilateral cortex bordering the impact site, hippocampus (CA1 and dentate), thalamus, and vermis of the cerebellum as early as 3 h post injury. Degenerating neurons were maximal by 1 and 3 days in the cortex and hippocampus, by 3 and 7 days in the cerebellum, and by 7 days in the thalamus. The regional distribution of Fluoro-Jade-labeled neurons corresponded to a similar pattern of silver and TUNEL staining. Together, these findings demonstrate a regionally specific temporal pattern of neuronal injury that results in overt neuronal cell loss within both cortical and subcortical regions.     

Light and electron microscopic assessment of progressive atrophy following moderate traumatic brain injury in the rat

The presence of progressive white matter atrophy following traumatic brain injury (TBI) has been reported in humans as well as in animal models. However, a quantitative analysis of progressive alterations in myelinated axons and other cellular responses to trauma has not been conducted. This study examined quantitative differences in myelinated axons from several white and gray matter structures between non-traumatized and traumatized areas at several time points up to 1 year. We hypothesize that axonal numbers decrease over time within the structures analyzed, based on our previous work demonstrating shrinkage of tissue in these vulnerable areas. Intubated, anesthetized male Sprague-Dawley rats were subjected to moderate (1.8–2.2 atm) parasagittal fluid-percussion brain injury, and perfused at various intervals after surgery. Sections from the fimbria, external capsule, thalamus and cerebral cortex from the ipsilateral hemisphere of traumatized and sham-operated animals were prepared and. estimated total numbers of myelinated axons were determined by systematic random sampling. Electron micrographs were obtained for ultrastructural analysis. A significant (P<0.05) reduction in the number of myelinated axons in the traumatized hemisphere compared to control in all structures was observed. In addition, thalamic and cortical axonal counts decreased significantly (P<0.05) over time. Swollen axons and macrophage/microglia infiltration were present as late as 6 months post-TBI in various structures. This study is the first to describe quantitatively chronic axonal changes in vulnerable brains regions after injury. Based on these data, a time-dependent decrease in the number of myelinated axons is seen to occur in vulnerable gray matter regions including the cerebral cortex and thalamus along with distinct morphological changes within white matter tracts after TBI. Although this progressive axonal response to TBI may include Wallerian degeneration, other potential mechanisms underlying this progressive pathological response within the white matter are discussed.     

Selective temporal and regional alterations of Nogo-A and small proline-rich repeat protein 1A (SPRR1A) but not Nogo-66 receptor (NgR) occur following traumatic brain injury in the rat

Axons show a poor regenerative capacity following traumatic central nervous system (CNS) injury, partly due to the expression of inhibitors of axonal outgrowth, of which Nogo-A is considered the most important. We evaluated the acute expression of Nogo-A, the Nogo-66 receptor (NgR) and the novel small proline-rich repeat protein 1A (SPRR1A, previously undetected in brain), following experimental lateral fluid percussion (FP) brain injury in rats. Immunofluorescence with antibodies against Nogo-A, NgR and SPRR1A was combined with antibodies against the neuronal markers NeuN and microtubule-associated protein (MAP)-2 and the oligodendrocyte marker RIP, while Western blot analysis was performed for Nogo-A and NgR. Brain injury produced a significant increase in Nogo-A expression in injured cortex, ipsilateral external capsule and reticular thalamus from days 1-7 post-injury (P < 0.05) compared to controls. Increased expression of Nogo-A was observed in both RIP- and NeuN positive (+) cells in the ipsilateral cortex, in NeuN (+) cells in the CA3 region of the hippocampus and reticular thalamus and in RIP (+) cells in white matter tracts. Alterations in NgR expression were not observed following traumatic brain injury (TBI). Brain injury increased the extent of SPRR1A expression in the ipsilateral cortex and the CA3 at all post-injury time-points in NeuN (+) cells. The marked increases in Nogo-A and SPRR1A in several important brain regions suggest that although inhibitors of axonal growth may be upregulated, the injured brain is also capable of expressing proteins promoting axonal outgrowth following TBI.     

Midline brain injury in the immature rat induces sustained cognitive deficits, bihemispheric axonal injury and neurodegeneration

Infants and children less than 4 years old suffer chronic cognitive deficits following mild, moderate or severe diffuse traumatic brain injury (TBI). It has been suggested that the underlying neuropathologic basis for behavioral deficits following severe TBI is acute brain swelling, subarachnoid hemorrhage and axonal injury. To better understand mechanisms of cognitive dysfunction in mild-moderate TBI, a closed head injury model of midline TBI in the immature rat was developed. Following an impact over the midline suture of the intact skull, 17-day-old rats exhibited short apnea times (3–15 s), did not require ventilatory support and suffered no mortality, suggestive of mild TBI. Compared to un-injured rats, brain-injured rats exhibited significant learning deficits over the first week post-injury (p < 0.0005), and, significant learning (p < 0.005) and memory deficits (p < 0.05) in the third post-injury week. Between 6 and 72 h, blood–brain barrier breakdown, extensive traumatic axonal injury in the subcortical white matter and thalamus, and focal areas of neurodegeneration in the cortex and hippocampus were observed in both hemispheres of the injured brain. At 8 to 18 days post-injury, reactive astrocytosis in the cortex, axonal degeneration in the subcortical white matter tracts, and degeneration of neuronal cell bodies and processes in the thalamus of both hemispheres were observed; however, cortical volumes were not different between un-injured and injured rat brains. These data suggest that diffuse TBI in the immature rat can lead to ongoing degeneration of both cell soma and axonal compartments of neurons, which may contribute, in part, to the observed sustained cognitive deficits.     

Repetitive closed-skull traumatic brain injury in mice causes persistent multifocal axonal injury and microglial reactivity

Repetitive mild or "concussive" traumatic brain injury (TBI) can cause substantial neurologic impairment, but the pathological features of this type of injury are not fully understood. We report an experimental model of TBI in which the closed skulls of anesthetized male C57BL/6J mice are struck with an electromagnetically controlled rubber impactor twice with an interval of 24 hours between impacts. The mice had deficits in Morris water maze performance in the first week after injury that only partially resolved 7 weeks later. By routine histology, there was no apparent bleeding, neuronal cell loss, or tissue disruption, and amyloid precursor protein immunohistochemistry demonstrated very few immunoreactive axonal varicosities. In contrast, silver staining revealed extensive abnormalities in the corpus callosum and bilateral external capsule, the ipsilateral cortex and thalamus, and the contralateral hippocampal CA1 stratum radiatum and stratum oriens. Electron microscopy of white matter regions demonstrated axonal cytoskeletal disruption, intra-axonal organelle compaction, and irregularities in axon caliber. Reactive microglia were observed in the same areas as the injured axons by both electron microscopy and Iba1 immunohistochemistry. Quantitative analyses of silver staining and Iba1 immunohistochemistry at multiple time points demonstrated transient cortical and thalamic abnormalities but persistent white matter pathology as late as 7 weeks after injury.Thus, prominent and long-lasting abnormalities in this TBI model were underestimated using conventional approaches. The model may be useful for mechanistic investigations and preclinical assessment of candidate therapeutics.     

Experimental investigation of cerebral contusion: histopathological and immunohistochemical evaluation of dynamic cortical deformation

We used a new approach, termed dynamic cortical deformation (DCD), to study the neuronal, vascular, and glial responses that occur in focal cerebral contusions. DCD produces experimental contusion by rapidly deforming the cerebral cortex with a transient, nonablative vacuum pulse of short duration (25 milliseconds) to mimic the circumstances of traumatic injury. A neuropathological evaluation was performed on brain tissue from adult rats sacrificed 3 days following induction of either moderate (4 psi, n = 6) or high (8 psi, n = 6) severity DCD. In all animals, DCD produced focal hemorrhagic lesions at the vacuum site without overt damage to other regions. Examination of histological sections showed localized gross tissue and neuronal loss in the cortex at the injury site, with the volume of cell loss dependent upon the mechanical loading (p < 0.001). Axonal pathology shown with neurofilament immunostaining (SMI-31 and SMI-32) was observed in the subcortical white matter inferior to the injury site and in the ipsilateral internal capsule. No axonal injury was observed in the contralateral hemisphere or in any remote regions. Glial fibrillary acidic protein (GFAP) immunostaining revealed widespread reactive astrocytosis surrounding the necrotic region in the ipsilateral cortex. This analysis confirms that rapid mechanical deformation of the cortex induces focal contusions in the absence of primary damage to remote areas 3 days following injury. Although it is suggested that massive release of neurotoxic substances from a contusion may cause damage throughout the brain, these data emphasize the importance of combined injury mechanisms, e.g. mechanical distortion and excitatory amino acid mediated damage, that underlie the complex pathology patterns observed in traumatic brain injury.     

Neuronal loss as evidenced by automated quantification of neuronal density following moderate and severe traumatic brain injury in rats

Traumatic brain injury causes widespread neurological lesions that can be reproduced in animals with the lateral fluid percussion (LFP) model. The characterization of the pattern of neuronal death generated in this model remains unclear, involving both cortical and subcortical brain regions. Here, 7 days after moderate (3 atmospheres absolute [ATA]) or severe (3.8 ATA) LFP, we estimated neuronal loss by using immunohistochemistry together with a computer‐assisted automated method for quantifying neuronal density in brain sections. Neuronal counts were performed ipsilateral to the impact, in the parietal cortex ventral to the site of percussion, in the temporal cortex, in the dorsal thalamus, and in the hippocampus. These results were compared with the counts observed at similar areas in sham animals. We found that neuronal density was severely decreased in the temporal cortex (?60%), in the dorsal thalamus (?63%), and in area CA3 of the hippocampus (?36%) of injured animals compared with controls but was not significantly modified in the cortices located immediately ventral to the impact. Total cellular density increased in brain structures displaying neuronal death, suggesting the presence of gliosis. The increase in the severity of LFP did not change the pattern of neuronal injury. This automated method simplified the study of neuronal loss following traumatic brain injury and allowed the identification of a pattern of neuronal loss that spreads from the dorsal thalamus to the temporal cortex, with the most severe lesions being in brain structures remote from the site of impact. © 2015 Wiley Periodicals, Inc.     

Early Neurodegeneration after Hypoxia-Ischemia in Neonatal Rat Is Necrosis while Delayed Neuronal Death Is Apoptosis

We used silver staining to demonstrate neuronal cell body, axonal, and terminal degeneration in brains from p7 rat pups recovered for 0, 1.5, 3, 6, 24, 48, 72 h, and 6 days following hypoxia-ischemia. We found that initial injury is evident in ipsilateral forebrain by 3 h following hypoxia-ischemia, while injury in ventral basal thalamus develops at 24 h. A secondary phase of injury occurs at 48 h in ipsilateral cortex, but not until 6 days in basal ganglia. Initial injury in striatum and cortex is necrosis, but in thalamus the neurodegeneration is primarily apoptosis. Degeneration also occurs in bilateral white matter tracts, and in synaptic terminal fields associated with apoptosis in regions remote from the primary injury. These results show that hypoxia-ischemia in the developing brain causes both early and delayed neurodegeneration in specific systems in which the morphology of neuronal death is determined by time, region, and potentially by patterns of neuronal connectivity.     

Regional and temporal characterization of neuronal, glial, and axonal response after traumatic brain injury in the mouse

Fluid percussion injury (FPI) is a commonly used and clinically relevant model of traumatic brain injury (TBI) in the rat. Recently, our lab successfully adapted FPI to mice. To account for differences in response to injury between mice and rats and provide a foundation for further use of FPI in gene-targeting studies, we sought to characterize the temporal and regional response to FPI in male C57BL/6 mice. Animals were killed at 10 min, 24 h, and 4, 7, 14, and 35 days (n = 3 for each group) after a very severe parasagittal FPI (> 4.0 atm) or sham injury (n = 3). Extensive numbers of damaged neurons were consistently found in the ipsilateral cortex, thalamus, and hippocampus by 10 min. This damage was nearly identical at 24 h, but quickly declined at subsequent time points. Activated microglia were found only in regions of neuronal injury at the earliest time points. Glial fibrillary acidic protein immunoreactivity reached significantly higher levels compared with controls at 7 days (P < 0.05) in the cortex, thalamus, and hippocampus and remained elevated for 35 days. White matter degeneration was present in all regions examined. This damage did not appear until at least day 4, but progressed up to day 35. The spatial pattern of damage we observed in mice after FPI is similar to that seen in rats. However, the temporal progression of neuronal injury in mice is comparatively abbreviated in the hippocampus and thalamus. In conclusion, these results suggest that FPI in mice may be a particularly useful tool for studying mechanisms of TBI in gene-targeting studies. Received: 13 October 1998 / Revised: 22 February 1999 / Accepted: 24 March 1999     

Neuronal network disturbance after focal ischemia in rats

We studied functional disturbances following left middle cerebral artery occlusion in rats. Neuronal function was evaluated by [14C]2-deoxyglucose autoradiography 1 day after occlusion. We analyzed the mechanisms of change in glucose utilization outside the infarct using Fink-Heimer silver impregnation, axonal transport of wheat germ agglutinin-conjugated-horseradish peroxidase, and succinate dehydrogenase histochemistry. One day after occlusion, glucose utilization was remarkably reduced in the areas surrounding the infarct. There were many silver grains indicating degeneration of the synaptic terminals in the cortical areas surrounding the infarct and the ipsilateral cingulate cortex. Moreover, in the left thalamus where the left middle cerebral artery supplied no blood, glucose utilization significantly decreased compared with sham-operated rats. In the left thalamus, massive silver staining of degenerated synaptic terminals and decreases in succinate dehydrogenase activity were observed 4 and 5 days after occlusion. The absence of succinate dehydrogenase staining may reflect early changes in retrograde degeneration of thalamic neurons after ischemic injury of the thalamocortical pathway. Terminal degeneration even affected areas remote from the infarct: there were silver grains in the contralateral hemisphere transcallosally connected to the infarct and in the ipsilateral substantia nigra. Axonal transport study showed disruption of the corticospinal tract by subcortical ischemia; the transcallosal pathways in the cortex surrounding the infarct were preserved. The relation between neural function and the neuronal network in the area surrounding the focal cerebral infarct is discussed with regard to ischemic penumbra and diaschisis.     

Quantitative structural changes in white and gray matter 1 year following traumatic brain injury in rats

There is evidence for chronic atrophy after human head trauma, which may be associated with long-term functional deficits. However, using established models of traumatic brain injury (TBI) only limited data are available for clarifying the extent of progressive gray and white matter atrophy. In the present study, male Sprague-Dawley rats underwent moderate (2.01-2.21 atm) parasagittal fluid percussion brain injury ( n=7) or sham ( n=3) surgery and were killed at 1 year post TBI. Semiserial sections were obtained through the neuraxis and double stained with hematoxylin and eosin to demarcate gray matter structures and Luxol fast blue for white matter visualization. Both ipsilateral and contralateral volume measurements were obtained for the following structures: cerebral cortex, hippocampus, dentate gyrus, thalamus, lateral ventricle, external capsule, internal capsule, cerebral peduncle and corpus callosum. Quantitative assessment of ipsilateral gray matter structures from TBI rats revealed significant reductions in cerebral cortical area measurements posterior from the trauma epicenter compared to sham animals. Importantly, several white matter tracts exhibited dramatic atrophy. A comparison of TBI and sham groups demonstrated a significant ( P<0.05) decrease in the external capsule and cerebral peduncle volumes ( P<0.007). In addition, there was a significant volume expansion (533% of control) of the ipsilateral lateral ventricle ( P<0.03). These novel data emphasize the need to clarify the pathophysiology of progressive white matter damage after TBI and the development of therapeutic strategies to target white matter pathology.     

Regionally distinct patterns of calpain activation and traumatic axonal injury following contusive brain injury in immature rats

Impact-induced head injury in infants results in acute focal contusions and traumatic axonal injury (TAI) that are associated with chronic holohemispheric cortical and white matter atrophy and may contribute to poor outcome in brain-injured children less than 4 years of age. Contusive brain trauma in postnatal day (PND) 11 or PND 17 rat pups, ages neurologically equivalent to a human infant and toddler, respectively, leads to cortical tissue loss and white matter atrophy which are associated with cognitive deficits. In adult models of brain trauma and in brain-injured humans, acute and sustained activation of the calpain family of calcium-activated neutral proteases has been implicated in neuronal death and TAI. PND 11 or PND 17 rat pups were subjected to closed head injury over the left hemisphere using the controlled cortical impact device and sacrificed at 6 h, 24 h or 3 days. Hemorrhagic contusions and tissue tears in the cortex and white matter were visible at 6 h, and neuronal loss was evident by 3 days. Calpain activation was observed in cell soma and dendrites of injured neurons at 6 h, and in degenerating dendrites and atrophic neurons at 24 h after injury at both ages. Axonal accumulation of amyloid precursor protein, indicative of TAI, was observed in the corpus callosum and lateral aspects of the white matter below the site of impact, and in the thalamus in PND 11 rats only. Intra-axonal calpain activation was observed to a limited extent in the corpus callosum and subcortical white matter tracts in both brain-injured PND 11 and PND 17 rats. Collectively, these results provide evidence that calpain activation may participate in neuronal loss in the injured cortex, but may not contribute to the pathogenesis of TAI following contusive brain trauma in the immature rat.     

Extent of nerve cell injury in Marmarou's model compared to other brain trauma models

OBJECTIVES: We sought to determine the extent of nerve cell injury in the Marmarou's acceleration impact model of diffuse brain injury. METHODS: Sensitive markers for cell injury including immunostaining for beta-amyloid precursor protein (beta-APP, a marker for diffuse axonal injury, DAI), Fluoro-Jade (FJ) histochemistry and electron microscopy (EM) were used in sham-operated and traumatized brains. RESULTS: APP immunostaining confirmed and extended previous findings of DAI in association and subcortical fiber systems in the white matter after injury. Increasing FJ labeling of neurons in layers II-III of sensorimotor cortex (smCx) from 4 to 48 hours after trauma and scattered labeled cells were found in the lower cortical layers. EM confirmed the presence of dystrophic pyramidal neurons in layers II-III of smCx 24 and 48 hours post-trauma. DISCUSSION: Taken together, the data revealed significant nerve cell injury without apparent cell death in this model.     

A new model of white matter injury in neonatal rats with bilateral carotid artery occlusion

Periventricular leukomalacia is an important cause of cerebral palsy and characterized by cysts and coagulation necrosis in the periventricular white matter. Since no model of periventricular leukomalacia has been established in small animals, it is expected to establish a new model of white matter injury in immature rodents. Bilateral carotid arteries were occluded in neonatal rats at 5 days of age, and the brain neuropathologically examined at 7 days of age. Among 22 brains histologically examined, 20 (90.9%) had white matter changes including coagulation necrosis and cystic lesions in and around the internal capsule, while only two had small cerebral infarction and five showed some ischemic neurons in the cerebral cortex. Cerebral blood flow (CBF) decreased to about 25% of controls in the subcortical white matter in the animals with bilateral carotid artery occlusion (BCAO). Amyloid precursor protein (APP) immunohistochemistry demonstrated various APP-immunoreactive axonal profiles in the internal capsule and the subcortical white matter, and stronger expression of APP in pyramidal neurons in the cerebral cortex of BCAO brains. These results indicated that the white matter is more vulnerable than the cerebral cortex in 5-day-old rats when CBF decreases to about 25% and suggested that this model is useful for investigating the white matter changes induced by cerebral hypoperfusion in the neonatal brain, since previous models of hypoxic-ischemic brain injury in neonatal mice and rats revealed preferential susceptibility of the gray matter. It was also indicated that APP is a sensitive marker for mild axonal disruption in the white matter of the immature brain.     

Temporal and spatial characterization of neuronal injury following lateral fluid-percussion brain injury in the rat

The pattern of neuronal injury following lateral fluid-percussion (FP) brain injury in the rat was systematically characterized at sequential time points to identify selectively vulnerable regions and to determine the temporal contribution of primary and delayed neuropathological events. Male Sprague-Dawley rats (n = 28) were killed 10 min, 2 h, 12 h, 24 h, 4 days, and 7 days following a lateral FP brain injury of moderate severity (2.2 atm), or 24 h after a sham injury. Brain sections were stained and analyzed using Nissl, acid fuchsin, and silver staining methods to identify regions with injured neurons or with visible lesions. Extensive numbers of acid fuchsin or silver-stained neurons were observed as early as 10 min after the FP brain injury in regions extending from the caudate/putamen to the pons. The frequency of injured neurons was greatest in the ipsilateral cortex, hippocampus, and thalamus, and a visible loss of Nissl-stained neurons was observed in these regions beginning at 12 h after the FP brain injury. Acid fuchsin-stained neurons were restricted to the same brain regions for all of the survival periods and gradually decreased in numbers between 24 h and 7 days after injury. These findings suggest that lateral FP brain injury in the rat produces a combination of focal cortical contusion and diffuse subcortical neuronal injury, which is present within minutes of the impact, progresses to a loss of neurons by 12 h, and does not markedly expand into other brain regions with survival periods up to 7 days. Furthermore, the acute onset and rapid evolution of the neuronal injury process may have important implications when considering a window of opportunity for pharmacological intervention. Received: 23 May 1995 / Revised, accepted: 15 September 1995     

Astroglial ciliary neurotrophic factor mRNA expression is increased in fields of axonal sprouting in deafferented hippocampus

Evidence that ciliary neurotrophic factor promotes axonal sprouting and regeneration in the periphery raises the possibility that this factor is involved in reactive axonal growth in the brain. In situ hybridization was used in the present study to determine whether ciliary neurotrophic factor mRNA expression is increased in association with axonal sprouting in deafferented adult rat hippocampus. In untreated rats, ciliary neurotrophic factor cRNA labeling density was high in the olfactory nerve, pia mater, and aspects of the ventricular ependyma and was relatively low within areas of white matter (fimbria, internal capsule) and select neuronal fields (hippocampal cell layers, habenula). After an entorhinal cortex lesion, hybridization was markedly increased in fields of anterograde degeneration, including most prominently the ipsilateral dentate gyrus outer molecular layer and hippocampal stratum lacunosum moleculare. Labeling in these fields was increased by 3 days postlesion, was maximal at 5 days, and returned to normal levels by 14 days. Double labeling demonstrated that, in both control and experimental tissue, ciliary neurotrophic factor mRNA was colocalized with glial fibrillary acidic protein immunoreactivity in astroglia, but it was not colocalized with markers for oligodendrocytes or microglia. These results demonstrate that astroglial ciliary neurotrophic factor expression is increased in fields of axonal and terminal degeneration and that increased expression is coincident with 1) increased insulin-like growth factor-1 and basic fibroblast growth factor expression and 2) the onset of reactive axonal growth. The synchronous expression of these glial factors in fields of deafferentation suggests the possibility of additive or synergistic interactions in the coordination of central axonal growth. J. Comp. Neurol. 386:137–148, 1997. © 1997 Wiley-Liss, Inc.     

Ischemic axonal injury and its recovery after focal cerebral ischemia

After focal cerebral infarction by occluding the middle cerebral artery (MCA) of the rat, the neuronal death occurred in the ipsilateral thalamic neurons, because axons of the thalamic neurons were injured by infarction and retrograde degeneration occurred in the thalamic neurons. However, cortical neurons adjacent to the infarction survived despite their axons injured by ischemia. We employed immunohistochemical staining for 200 kilodalton (kD) neurofilament (NF), in order to study those responses of cortical and thalamic neurons against axonal injury caused by focal cerebral infarction. In the sham operated rats the immunoreactivity to the anti-200 kD NF antibody was only detected in the axon but not in the cell bodies and dendrites. At 3 days after MCA occlusion, axonal swelling proximal to the site of ischemic injury was found in the caudoputamen and internal capsule of the ipsilateral side. At 7 days after occlusion, cell bodies and dendrites of the neurons in the ipsilateral cortex and thalamus were strongly stained with anti-NF antibodies. At 2 weeks after occlusion these responses disappeared in the cortex, but lasted in the thalamus. These phenomena are caused by stasis of the slow axonal transport, because the NF is transported by slow axonal transport. In the cortical neurons impairment of slow axonal transport recovered in the early phase after injury, but in the thalamic neurons the impairment prolonged up to 3 weeks after occlusion. The early recovery of axonal transport from ischemia seemed to be essential for survival of neurons after ischemic axonal injury.     

Activation of Rho after traumatic brain injury and seizure in rats

Traumatic brain injury (TBI) is characterized by a progressive cell loss and a lack of axonal regeneration. In the central nervous system (CNS), the Rho signaling pathway regulates the neuronal response to growth inhibitory proteins and regeneration of damaged axons, and Rho activation is also correlated with an increased susceptibility to apoptosis. To evaluate whether traumatic brain injury (TBI) results in changes in Rho activation in vulnerable regions of the brain, GTP-RhoA pull down assays were performed on rat cortical and hippocampal tissue homogenates obtained from 24 h to 3 days following lateral fluid percussion brain injury (FPI). Following FPI, a significantly increased RhoA activation was observed from 24 h to 3 days post-injury in the cortex and by 3 days in the hippocampus ipsilateral to the injury. We also detected activated RhoA in the cortex and hippocampus contralateral to the injury, without concomitant changes in total RhoA levels. To determine if immediate post-traumatic events such as seizures may activate Rho, we examined RhoA activation in the brains of rats with kainic acid-induced seizures. Severe seizures resulted in bilateral RhoA activation in the cortex and hippocampus. Together, these results indicate that RhoA is activated in vulnerable brain regions following traumatic and epileptic insults to the CNS.     

大鼠轻型颅脑损伤后星形胶质细胞与神经元的病理改变

目的 探讨轻型颅脑损伤（TBI）后神经元及星形胶质细胞改变的病理生理过程。方法 将24只成年SD大鼠随机分为轻型TBI组（n=18）和假手术组（n=6）,轻型TBI组又分为伤后3 h（n=6）、伤后24 h（n=6）、伤后72 h（n=6）三亚组。采用液压冲击法制作轻型TBI模型。采用胶质纤维酸性蛋白（GFAP）染色检测星形胶质细胞,采用Fluoro-Jade B（FJ-B）荧光染色检测变性神经元。结果 与假手术组相比,轻型TBI后3 h、24 h、72 h邻近顶叶皮质、海马CA2/3区GFAP阳性细胞数量均明显减少（P<0.05）;缺失区周围星形胶质细胞肿胀增生明显。FJ-B阳性神经元在损伤后3 h无明显增加（P>0.05）,伤后24 h皮层区FJ-B阳性神经元显著增加（P<0.05）,伤后72 h海马区FJ-B阳性神经元显著增加（P<0.05）。伤后72 h伤侧皮层区与海马区GFAP阳性细胞数和FJ-B阳性细胞数呈显著负相关（r=-0.8285,P<0.05）。结论 轻型TBI后星形胶质细胞超急性期（3 h）即出现损害和胶质反应,神经元则在急性期（24 h）至亚急性期（72 h）出现明显损害,星形胶质细胞缺失程度可以反应神经元损伤程度。     

Expression of Fas and Fas ligand after experimental traumatic brain injury in the rat.

Apoptotic cell death plays an important role in the cascade of neuronal degeneration after traumatic brain injury (TBI), but the underlying mechanisms are not fully understood. However, increasing evidence suggests that expression of Fas and its ligand (FasL) could play a major role in mediating apoptotic cell death in acute and chronic neurologic disorders. To further investigate the temporal pattern of Fas and FasL expression after experimental TBI in the rat, male Sprague Dawley rats were subjected to unilateral cortical impact injury. The animals were killed and examined for Fas and FasL protein expression and for immunohistologic analysis at intervals from 15 minutes to 14 days after injury. Increased Fas and FasL immunoreactivity was seen in the cortex ipsilateral to the injury site from 15 minutes to 72 hours after the trauma, respectively. Immunohistologic investigation demonstrated a differential pattern of Fas and FasL expression in the cortex, respectively: increased Fas immunoreactivity was seen in cortical astrocytes and neurons from 15 minutes to 72 hours after the injury. In contrast, increased expression of FasL was seen in cortical neurons, astrocytes, and microglia from 15 minutes to 72 hours after impact injury. Concurrent double-labeling examinations using terminal deoxynucleotidyl transferase-mediated deoxyuridine-biotin nick end labeling identified Fas- and FasL-immunopositive cells with high frequency in the cortex ipsilateral to the injury site. In contrast, there was no evidence of Fas- and FasL-immunopositive cells in the hippocampus ipsilateral to the injury site up to 14 days after the trauma. Further, Fas and FasL immunoreactivity was absent in the contralateral cortex and hippocampus at all time points investigated. These results reveal induction of Fas and FasL expression in the cortex after TBI in the rat. Further, these data implicate an involvement of Fas and FasL in the pathophysiologic mechanism of apoptotic neurodegeneration after TBI. Last, these data suggest that strategies aimed to repress posttraumatic Fas- and FasL-induced apoptosis may open new perspectives for the treatment of TBI.