Macrophage- and astrocyte-derived transforming growth factor beta as a mediator of central nervous system dysfunction in acquired immune deficiency syndrome.

The multifunctional cytokine, transforming growth factor beta (TGF-beta), was identified by immunocytochemistry in the brain tissues of four patients with acquired immune deficiency syndrome (AIDS), but not in control brain tissue. The TGF-beta staining was localized to cells of monocytic lineage as well as astrocytes, especially in areas of brain pathology. In addition, the brain tissues from the AIDS patients contained transcripts for human immunodeficiency virus 1 (HIV-1) by in situ hybridization, suggesting a correlation between the presence of HIV-1 in the brain and the expression of TGF-beta. However, the expression of TGF-beta was not limited to HIV-1-positive cells, raising the possibility of alternative mechanisms for the induction of TGF-beta in these AIDS patients' brains. To investigate these mechanisms, purified human monocytes were infected in vitro with HIV-1 and were shown to secrete increased levels of TGF-beta. In addition, HIV-1-infected monocytes released a factor(s) capable of triggering cultured astrocytes that are not infected with HIV-1 to secrete TGF-beta. The release of TGF-beta, which is an extremely potent chemotactic factor, may contribute to the recruitment of HIV-1-infected monocytic cells, enabling viral spread to and within the central nervous system (CNS). Moreover, TGF-beta augments cytokine production, including cytokines known to be neurotoxic. The identification of TGF-beta within the CNS implicates this cytokine in the immunopathologic processes responsible for AIDS-related CNS dysfunction.

Cytokines and neuropathology.

Inflammatory processes in the brain require the cooperation of immunocompetent cells and glial cells, which communicate by secreting bidirectional mediators. Resident cells within the nervous system can synthesize and secrete inflammatory cytokines, as well as neuropeptides, contributing to the response within the CNS to injury or immunological challenge. Although the mechanisms of cell activation and immune interaction are poorly understood, accumulating evidence implicates these pathways in neuropathogenesis, as described here by Sharon Wahl and colleagues. For example, in the acquired immune deficiency syndrome (AIDS), HIV-1-induced nervous system dysfunction and dementia are associated with the presence of infiltrating leukocytes and the release of inflammatory cytokines. Defining the pathways of cytokine dysregulation and neurotoxicity invoked by the infiltrating leukocytes, as well as the contribution of the neural cells themselves, may help to identify mechanisms of intervention in this and other debilitating CNS diseases.

Interleukin-8 released into the cerebrospinal fluid after brain injury is associated with blood-brain barrier dysfunction and nerve growth factor production.

Interleukin (IL) 8 was measured in CSF of 14 patients with severe traumatic brain injury. IL-8 levels were significantly higher in CSF (up to 8,000 pg/ml) than serum (up to 2,400 pg/ml) (p < 0.05), suggesting intrathecal production. Maximal IL-8 values in CSF correlated with a severe dysfunction of the blood-brain barrier. Nerve growth factor (NGF) was detected in CSF of 7 of 14 patients (range of maximal NGF: 62-12,130 pg/ml). IL-8 concentrations were significantly higher in these patients than in those without NGF (p < 0.01). CSF containing high IL-8 (3,800-7,900 pg/ml) induced greater NGF production in cultured astrocytes (202-434 pg/ml) than samples with low IL-8 (600-1,000 pg/ml), which showed a smaller NGF increase (0-165 pg/ml). Anti-IL-8 antibodies strongly reduced (52-100%) the release of NGF in the group of high IL-8, whereas in the group with low IL-8, this effect was lower (0-52%). The inability of anti-IL-8 antibodies to inhibit the synthesis of NGF completely may depend on cytokines like tumor necrosis factor alpha and IL-6 found in these CSF samples, which may act in association with IL-8. Thus, IL-8 may represent a pivotal cytokine in the pathology of brain injury.

Experimental axonal injury triggers interleukin-6 mRNA, protein synthesis and release into cerebrospinal fluid.

Diffuse axonal injury is a frequent pathologic sequel of head trauma, which, despite its devastating consequences for the patients, remains to be fully elucidated. Here we studied the release of interleukin-6 (IL-6) into CSF and serum, as well as the expression of IL-6 messenger ribonucleic acid (mRNA) and protein in a weight drop model of axonal injury in the rat. The IL-6 activity was elevated in CSF within 1 hour and peaked between 2 and 4 hours, reaching maximal values of 82,108 pg/mL, and returned to control values after 24 hours. In serum, the levels of IL-6 remained below increased CSF levels and did not exceed 393 pg/mL. In situ hybridization demonstrated augmented IL-6 mRNA expression in several regions including cortical pyramidal cells, neurons in thalamic nuclei, and macrophages in the basal subarachnoid spaces. A weak constitutive expression of IL-6 protein was shown by immunohistochemical study in control brain. After injury, IL-6 increased at 1 hour and remained elevated through the first 24 hours, returning to normal afterward. Most cells producing IL-6 were cortical, thalamic, and hippocampal neurons as confirmed by staining for the neuronal marker NeuN. These results extend our previous studies showing IL-6 production in the cerebrospinal fluid of patients with severe head trauma and demonstrate that neurons are the main source of IL-6 after experimental axonal injury.

Experimental closed head injury: analysis of neurological outcome, blood-brain barrier dysfunction, intracranial neutrophil infiltration, and neuronal cell death in mice deficient in genes for pro-inflammatory cytokines.

Cytokines are important mediators of intracranial inflammation following traumatic brain injury (TBI). In the present study, the neurological impairment and mortality, blood-brain barrier (BBB) function, intracranial polymorphonuclear leukocyte (PMN) accumulation, and posttraumatic neuronal cell death were monitored in mice lacking the genes for tumor necrosis factor (TNF)/lymphotoxin-alpha (LT-alpha) (TNF/LT-alpha-/-) and interleukin-6 (IL-6) and in wild-type (WT) littermates subjected to experimental closed head injury (total n = 107). The posttraumatic mortality was significantly increased in TNF/LT-alpha-/- mice (40%; P < 0.02) compared with WT animals (10%). The IL-6-/- mice also showed a higher mortality (17%) than their WT littermates (5.6%), but the difference was not statistically significant (P > 0.05). The neurological severity score was similar among all groups from 1 to 72 hours after trauma, whereas at 7 days, the TNF/LT-alpha-/- mice showed a tendency toward better neurological recovery than their WT littermates. Interestingly, neither the degree of BBB dysfunction nor the number of infiltrating PMNs in the injured hemisphere was different between WT and cytokine-deficient mice. Furthermore, the analysis of brain sections by in situ DNA nick end labeling (TUNEL histochemistry) at 24 hours and 7 days after head injury revealed a similar extent of posttraumatic intracranial cell death in all animals. These results show that the pathophysiological sequelae of TBI are not significantly altered in mice lacking the genes for the proinflammatory cytokines TNF, LT-alpha, and IL-6. Nevertheless, the increased posttraumatic mortality in TNF/LT-alpha-deficient mice suggests a protective effect of these cytokines by mechanisms that have not been elucidated yet.

The duality of the inflammatory response to traumatic brain injury.

One and a half to two million people sustain a traumatic brain injury (TBI) in the US each year, of which approx 70,000-90,000 will suffer from long-term disability with dramatic impacts on their own and their families' lives and enormous socio-economic costs. Brain damage following traumatic injury is a result of direct (immediate mechanical disruption of brain tissue, or primary injury) and indirect (secondary or delayed) mechanisms. These secondary mechanisms involve the initiation of an acute inflammatory response, including breakdown of the blood-brain barrier (BBB), edema formation and swelling, infiltration of peripheral blood cells and activation of resident immunocompetent cells, as well as the intrathecal release of numerous immune mediators such as interleukins and chemotactic factors. An overview over the inflammatory response to trauma as observed in clinical and in experimental TBI is presented in this review. The possibly harmful/beneficial sequelae of post-traumatic inflammation in the central nervous system (CNS) are discussed using three model mediators of inflammation in the brain, tumor necrosis factor-alpha (TNF-alpha), interleukin-6 (IL-6), and transforming growth factor-beta (TGF-beta). While the former two may act as important mediators for the initiation and the support of post-traumatic inflammation, thus causing additional cell death and neurologic dysfunction, they may also pave the way for reparative processes. TGF-beta, on the other hand, is a potent anti-inflammatory agent, which may also have some deleterious long-term effects in the injured brain. The implications of this duality of the post-traumatic inflammatory response for the treatment of brain-injured patients using anti-inflammatory strategies are discussed.

Autocrine and paracrine regulation of astrocyte function by transforming growth factor-beta.

Recent evidence indicates that astrocytes have a wide range of functions, usually attributed to cells of the immune system, which are critical for maintaining a balanced homeostatic environment in the central nervous system (CNS). Moreover, these cells are known to participate in inflammatory events within the CNS by secreting cytokines such as transforming growth factor-beta (TGF-beta). In this study we have investigated the ability of TGF-beta to influence astrocyte functions. TGF-beta 1 mRNA is constitutively expressed by astrocytes in vitro, and when cultures are stimulated with exogenous TGF-beta 1 an increase in the expression of this mRNA can be shown, suggesting both autocrine and paracrine regulation. In in vitro assays, TGF-beta 1 is chemotactic for astrocytes in a dose-dependent fashion and inhibits astrocyte proliferation. These results indicating signal transduction by TGF-beta 1-prompted studies to explore receptor-ligand interactions on isolated astrocyte populations. In a receptor binding assay, we demonstrate that astrocytes appear to express three distinct TGF-beta receptor subtypes with nearly 10,000 receptors per cell. Thus, TGF-beta may play an important role in regulating astrocyte functions pivotal to the evolution of intracerebral immune responses including recruitment and activation of glial cells at local inflammatory sites within the CNS.

IL-10 levels in cerebrospinal fluid and serum of patients with severe traumatic brain injury: relationship to IL-6, TNF-alpha, TGF-beta1 and blood-brain barrier function.

Controlling the extent of inflammatory responses following brain injury may be beneficial since posttraumatic intracranial inflammation has been associated with adverse outcome. In order to elucidate the potential role of anti-inflammatory mediators, the production of interleukin-10 (IL-10) was monitored in paired cerebrospinal fluid (CSF) and serum of 28 patients with severe traumatic brain injury (TBI) and compared to control samples. The pattern of IL-10 was analyzed with respect to the patterns of IL-6, tumor necrosis factor-alpha (TNF-alpha) and transforming growth factor-beta1 (TGF-beta1) in both fluids during a time period of up to 22 days. In parallel, the function/dysfunction of the blood-brain barrier (BBB) was monitored using the CSF-/serum-albumin quotient (Q(A)) and compared to intrathecal cytokine levels. Mean IL-10 concentration in CSF was elevated in 26 out of 28 TBI patients (range: 1.3-41.7 pg/ml) compared to controls (cut-off: 1.06 pg/ml), whereas only seven patients had elevated mean IL-10 concentration in serum (range: 5.4-23 pg/ml; cut-off: 5.14 pg/ml). The time course of IL-10 was similar in both fluids, showing a peak during the first days and a second, lower rise in the second week. Intrathecal IL-10 synthesis is hypothesized since CSF-IL-10 levels exceeded serum-IL-10 levels in most of the patients, IL-10-index (CSF/serum-IL-10/QA) was elevated in 23 individuals, and elevation of CSF-IL-10 showed to be independent from severe BBB dysfunction. Neither CSF nor serum IL-10 values correlated with the dysfunction of the BBB. IL-10, IL-6 and TGF-beta1 showed similar patterns in CSF over time, whereas rises of TNF-alpha corresponded to declines of IL-10 levels. Our results suggest that IL-10 is predominantly induced intrathecally after severe TBI where it may downregulate inflammatory events following traumatic brain damage.

Elevated levels of the complement components C3 and factor B in ventricular cerebrospinal fluid of patients with traumatic brain injury.

Immunological events occurring in the central nervous system (CNS) as a result of head trauma are largely unexplored. We report here that the levels of the alternative pathway complement proteins C3 and factor B are elevated in the cerebrospinal fluid (CSF) of head-injured patients. C3 and factor B indices suggest that changes in C3 and factor B levels in CSF are most likely due to altered blood-brain barrier integrity and not to intrathecal synthesis. These data demonstrate, for the first time, elevated levels of complement proteins in CSF of patients with severe traumatic brain injury. Elevated complement levels in brain injury may contribute to secondary damage.

Intracerebral complement C5a receptor (CD88) expression is regulated by TNF and lymphotoxin-alpha following closed head injury in mice.

The anaphylatoxin C5a is a potent mediator of inflammation in the CNS. We analyzed the intracerebral expression of the C5a receptor (C5aR) in a model of closed head injury (CHI) in mice. Up-regulation of C5aR mRNA and protein expression was observed mainly on neurons in sham-operated and head-injured wild-type mice at 24 h. In contrast, in TNF/lymphotoxin-alpha knockout mice, the intracerebral C5aR expression remained at low constitutive levels after sham operation, whereas it strongly increased in response to trauma between 24 and 72 h. Interestingly, by 7 days after CHI, the intrathecal C5aR expression was clearly attenuated in the knockout animals. These data show that the posttraumatic neuronal expression of the C5aR is, at least in part, regulated by TNF and lymphotoxin-alpha at 7 days after trauma.

Role of cerebral inflammation after traumatic brain injury: a revisited concept.

Neuroinflammation occuring after traumatic brain injury (TBI) is a complex phenomenon comprising distinct cellular and molecular events involving the injured as well as the healthy cerebral tissue. Although immunoactivation only represents a one of the many cascades initiated in the pathophysiology of TBI, the exact function of each mediator, activated cell types or pathophysiological mechanism, needs to be further elucidated. It is widely accepted that inflammatory events display dual and opposing roles promoting, on the one hand, the repair of the injured tissue and, on the other hand, causing additional brain damage mediated by the numerous neurotoxic substances released. Most of the data supporting these hypotheses derive from experimental work based on both animal models and cultured neuronal cells. More recently, evidence has been provided that a complete elimination of selected inflammatory mediators is rather detrimental as shown by the attenuation of neurological recovery. However, there are conflicting results reported on this issue which strongly depend on the experimental setting used. The history of immunoactivation in neurotrauma is the subject of this review article, giving particular emphasis to the comparison of clinical versus experimental studies performed over the last 10 years. These results also are evaluated with respect to other neuropathologies, which are years ahead as compared to the research in TBI. The possible reciprocal influence of peripheral and intrathecal activation of the immune system will also be discussed. To conclude, the future directions of research in the field of neurotrauma is considered.

Experimental diffuse axonal injury induces enhanced neuronal C5a receptor mRNA expression in rats.

Several studies suggest the involvement of the complement system in the pathophysiology of traumatic brain injury (TBI). Since the intrathecal generation of anaphylatoxin C5a has been shown to mediate inflammatory effects within the central nervous system, we sought to characterize the cellular expression of the mRNA for the C5a receptor (C5aR, CD88) in brains of rats with experimental diffuse axonal injury (DAI) by in situ hybridization. Infiltrating leukocytes expressing C5aR mRNA were seen in meninges and lateral ventricles as early as 4 h after induction of DAI. The number of infiltrating C5aR-positive cells increased gradually up to 24 h after trauma. Within the brain parenchyma, up-regulation of C5aR mRNA expression was first seen in cerebellar Purkinje cells within 8 h. At 24 h after TBI, expression of C5aR mRNA was widespread bilaterally throughout the cortex and cerebellum, the cellular expression being restricted to pyramidal neurons and Purkinje cells. The intensity of C5aR transcript signals on neurons increased further up to 96 h after trauma. Ligand binding of C5a to its receptor on neurons might mediate previously unknown functions, thus possibly leading to neurotoxicity and secondary neuronal damage after TBI.

Soluble ICAM-1 in CSF coincides with the extent of cerebral damage in patients with severe traumatic brain injury.

The intercellular adhesion molecule-1 (ICAM-1) expressed by endothelial cells is crucial in promoting adhesion and transmigration of circulating leukocytes across the blood-brain barrier (BBB). Migrated immunocompetent cells, in turn, release mediators that stimulate glial and endothelial cells to express ICAM-1 and release cytokines, possibly sustaining cerebral damage. Following activation, proteolytic cleavage of membrane-anchored ICAM-1 results in measurable levels of a soluble form, sICAM-1. The aims of this study were to investigate the changes of sICAM-1 levels in ventricular CSF and serum and to elucidate the influence of structural brain damage as estimated by computerized tomography (CT) as well as the extent of BBB dysfunction as calculated by the CSF/serum albumin ratio (QA) in patients with severe traumatic brain injury (TBI). All investigated parameters revealed two subgroups. Patients belonging to group A had sICAM-1 levels in CSF above normal range, presented marked cerebral damage and a disturbance of the BBB (range 0.6-24.7 ng/ml, n = 8). In contrast, patients belonging to group B had no elevation of sICAM-1 values in CSF (range 0.3-3.9 ng/ml, n = 5; p < 0.017) and showed minor cerebral damage with an intact BBB in most cases. In addition, overall analysis showed that sICAM-1 in CSF correlated with the extent of BBB damage as indicated by the QA (r = 0.76; p < 0.001). These results suggest that increased sICAM-1 levels in CSF might depict ongoing immunologic activation and that sICAM-1 correlates with the extent of tissue and BBB damage. The origin of soluble ICAM-1 in CSF and its pathophysiologic role after TBI remains to be clarified.

S-100 beta reflects the extent of injury and outcome, whereas neuronal specific enolase is a better indicator of neuroinflammation in patients with severe traumatic brain injury.

It has been hypothesized that immunoactivation may contribute to brain damage and affect outcome after traumatic brain injury (TBI). In order to determine the role of inflammation after TBI, we studied the interrelationship of the immune mediators sICAM-1 and IL-6 with the levels of S-100beta and neuronal specific enolase (NSE), both recognized markers of brain damage. In addition, the extent and type of cerebral injury and the neurological outcome were related to these measured markers of injury. An evident elevation of S-100beta (range of means: 2.7-81.4 ng/mL) and NSE (range of means: 2.0-81.3 ng/mL) was observed in CSF of all 13 patients during the first 3 posttraumatic days and decreased over 2 weeks. In parallel, the production of sICAM-1 (range of means: 0.7-11.9 ng/mL) and IL-6 (range of means: 0.1-8.2 ng/mL) was also markedly enhanced in CSF. The CSF means of S-100beta and NSE per patient correlated with IL-6 (r = 0.60, p < 0.05; and r = 0.64, p < 0.05, respectively), whereas the corresponding means in serum showed a significant correlation only between NSE and IL-6 (r = 0.56, p < 0.05). Maximal CSF values of NSE and sICAM-1 correlated with each other (r = 0.57, p < 0.05). The contusion sizes assessed on the CT scans correlated with the means of S-100beta (r = 0.63, p < 0.05) and NSE (r = 0.71, p < 0.05) in CSF and with the mean of S-100beta in serum, although not statistically significant (r = 0.52, p = 0.06), but not with serum NSE. Interestingly, linear regression analysis demonstrated that means of S-100beta in CSF (r = 0.78, p = 0.002) and serum (r = 0.82, p < 0.001) correlated with the GOS. These results indicate that the elevation of these parameters in CSF depends on the extent of injury and that S-100beta may be a predictor of outcome after TBI, whereas NSE reflects better the inflammatory response.

TGF-beta is elevated in the CSF of patients with severe traumatic brain injuries and parallels blood-brain barrier function.

Traumatic brain injury (TBI) induces local and systemic immunologic changes, release of cytokines, and cell activation. Perpetuation of these cascades may contribute to secondary damage to the brain. Therefore, the ability of the antiinflammatory mediator transforming growth factor-beta (TGF-beta) to downregulate intrathecal immunoactivation may be of fundamental value for diminishing the incidence and extent of secondary insults. In this study, the release of TGF-beta into cerebrospinal fluid (CSF) and serum of 22 patients with severe TBI was analyzed with respect to the function of the blood-brain barrier (BBB) for 21 days. Levels of TGF-beta in CSF increased to their maximum on the first day (median, 1.26 ng/mL), thereafter decreasing gradually over time. Median TGF-beta values in serum always remained within the reference interval (6.5 to 71.5 ng/mL). Daily assessment of the CSF-serum albumin quotient (QA) and of the CSF-serum TGF-beta quotient (QTGF-beta) showed a strong correlation between maximal QTGF-beta and QA, indicating a passage of this cytokine from the periphery to the intrathecal compartment across the BBB. However, calculation of the TGF-beta index (QTGF-beta/Q(A)) suggested a cerebral production of TGF-beta in 9 of 22 patients. Levels of TGF-beta could not be correlated with extent of initial injury by computed tomography (CT), CD4/CD8 ratios, acute lung injury, or clinical outcome as rated by the Glasgow Outcome Scale (GOS). Although increased levels of TGF-beta in CSF seem to parallel BBB function, a partial intrathecal production is suggested, possibly modulated by elevation of interleukin-6 (IL-6). Thus, TGF-beta may function as a factor in the complex cytokine network following TBI, acting as an antiinflammatory and neuroprotective mediator.

Intrathecal levels of complement-derived soluble membrane attack complex (sC5b-9) correlate with blood-brain barrier dysfunction in patients with traumatic brain injury.

It has become evident in recent years that intracranial inflammation after traumatic brain injury (TBI) is, at least in part, mediated by activation of the complement system. However, most conclusions have been drawn from experimental studies, and the intrathecal activation of the complement cascade after TBI has not yet been demonstrated in humans. In the present study, we analyzed the levels of the soluble terminal complement complex sC5b-9 by ELISA in ventricular cerebrospinal fluid (CSF) of patients with severe TBI (n = 11) for up to 10 days after trauma. The mean sC5b-9 levels in CSF were significantly elevated in 10 of 11 TBI patients compared to control CSF from subjects without trauma or inflammatory neurological disease (n = 12; p < 0.001). In some patients, the maximal sC5b-9 concentrations were up to 1,800-fold higher than in control CSF. The analysis of the extent of posttraumatic blood-brain barrier (BBB) dysfunction, as determined by CSF/serum albumin quotient (Q(A)), revealed that patients with a moderate to severe BBB impairment (mean Q(A) > 0.01) had significantly higher intrathecal sC5b-9 levels as compared to patients with normal BBB function (mean Q(A) < 0.007; p < 0.0001). In addition, a significant correlation between the individual daily Q(A) values and the corresponding sC5b-9 CSF levels was detected in 8 of 11 patients (r = 0.72-0.998; p < 0.05). These data demonstrate for the first time that terminal pathway complement activation occurs after head injury and suggest a possible pathophysiological role of complement with regard to posttraumatic BBB dysfunction.

Markers for cell-mediated immune response are elevated in cerebrospinal fluid and serum after severe traumatic brain injury in humans.

The brain is believed to be an immunologically privileged organ, sheltered from the systemic immunological defense by the blood-brain barrier (BBB). However, there is increasing evidence for a marked inflammatory response in the brain after traumatic brain injury (TBI). Markers for cellular immune activation, neopterin, beta2-microglobulin (beta2M), and soluble interleukin-2 receptor (sIL-2R), were measured for up to 3 weeks in cerebrospinal fluid (CSF) and serum of 41 patients with severe TBI in order to elucidate the time course and the origin of the cellular immune response following TBI. Neopterin gradually increased during the first posttraumatic week in both CSF and serum. Concentrations in CSF were generally higher than in serum, suggesting intrathecal release of this marker. beta2M showed similar kinetics but with higher serum than CSF concentrations. Nonetheless, intrathecal release as assessed by the beta2M index could be postulated for most of the patients. The mean levels of sIL-2R in both CSF and serum were elevated during the whole study period, serum concentrations being up to 2 x 10(4) times higher than in CSF. No significant intrathecal production of sIL-2R could be detected. The present data shows that severe TBI leads to a marked cell-mediated immune response within the brain and in the systemic circulation. In the intrathecal compartment the activated cells appear to be predominantly of the macrophage/microglia lineage, while the immune activation in the systemic circulation seems to involve mainly T-lymphocytes.

Thiopental and midazolam do not seem to impede metabolism of glutamate in brain-injured patients.

Increased extracellular glutamate levels are related to glial and neuronal damage. Glutamate-mediated toxicity is limited by glial uptake and metabolic transformation of glutamate to glutamine and the energetic compounds alanine and lactate which are utilized by surrounding neurons. Under in vitro conditions, barbiturates have been shown to reduce glutamate uptake and its further metabolism, possibly impeding metabolic coupling between astrocytes and neurons. The aims were to investigate if under clinical conditions, the barbiturate thiopental reduces important detoxification of glutamate, resulting in lower CSF glutamine, alanine and lactate levels as opposed to patients receiving midazolam. During long-term administration of thiopental and midazolam, pathologically elevated ventricular CSF glutamate levels were associated with significantly increased glutamine and alanine levels up to 14 days after trauma. CSF lactate, however, remained normal. These data suggest that long-term administration of thiopental and midazolam under clinical conditions does not impede enzymatic activities responsible for detoxification and metabolism of glutamate.

Traumatic brain injury elevates the Alzheimer's amyloid peptide A beta 42 in human CSF. A possible role for nerve cell injury.

The increased risk for Alzheimer's Disease (AD) associated with traumatic brain injury (TBI) suggests that environmental insults may influence the development of this age-related dementia. Recently, we have shown that the levels of the beta-amyloid peptide (A beta 1-42) increase in the cerebrospinal fluid (CSF) of patients after severe brain injury and remain elevated for some time after the initial event. The relationships of elevated A beta with markers of blood-brain barrier (BBB) disruption, inflammation, and nerve cell or axonal injury were evaluated in CSF samples taken daily from TBI patients. This analysis reveals that the rise in A beta 1-42 is best correlated with possible markers of neuronal or axonal injury, the cytoskeletal protein tau, neuron-specific enolase (NSE), and apolipoprotein E (ApoE). Similar or better correlations were observed between A beta 1-40 and the three aforementioned markers. These results imply that the degree of brain injury may play a decisive role in determining the levels of A beta 1-42 and A beta 1-40 in the CSF of TBI patients. Inflammation and alterations in BBB may play lesser, but nonetheless significant, roles in determining the A beta level in CSF after brain injury.

Cell activation and inflammatory response following traumatic axonal injury in the rat.

In a rat model of traumatic brain injury cell activation was characterized immunohistochemically from 2 h up to 2 weeks. Reactive astrocytosis became apparent perivascularly and in the grey matter within 4h after trauma. Increased OX42 immunoreactivity indicated microglial activation in cortex and hippocampus as early as 4 h, whereas up-regulation of MHC class II (OX6) was evident in white matter tracts at 24 h. Although macrophage (ED1) numbers increased in the meninges and perivascularly, brain infiltration appeared marginal. Accumulation of lymphocytes and granulocytes was not observed. Our results show that traumatic axonal injury induces a rapid and sustained glial activation in the absence of leukocyte infiltration. Thus, cell activation following diffuse trauma strongly differs from that found after focal brain damage, awaiting further functional characterization.