Changes in cellular bioenergetic state following graded traumatic brain injury in rats: determination by phosphorus 31 magnetic resonance spectroscopy

Phosphorus 31 magnetic resonance spectroscopy (31P MRS) was used to study noninvasively the intracellular free Mg2+ concentration and cellular bioenergetic state of rat brain in vivo before and after fluid percussion-induced traumatic brain injury of graded severity. Brain injury was induced at four levels: low (1.0 +/- 0.5 atm); moderate (2.1 +/- 0.4 atm); high (3.9 +/- 0.9 atm); and severe (5.9 +/- 0.7 atm). Prior to injury, mean intracellular values for all groups (n = 24; mean +/- SE) were as follows: pH = 7.11 +/- 0.03; free [Mg2+] = 0.99 +/- 0.07 mM; cytosolic [ADP] = 25.2 +/- 0.8 nmol/g wet weight; cytosolic [AMP] = 0.29 +/- 0.02 nmol/g wet weight; cytosolic phosphorylation potential = 118.5 +/- 3.1 X 10(3) M-1; free energy of ATP hydrolysis = 62.11 +/- 0.04 kJ/mole; and energy charge = 0.99 +/- 0.01. Following every level of injury, there were decreases in intracellular free Mg2+ concentration, and alterations in the intracellular pH. These posttraumatic changes in Mg2+ and pH induced shifts in the equilibrium constants of the creatine kinase, adenylate kinase, and ATPase reactions, resulting in alterations in [ADP], [AMP], cytosolic phosphorylation potential, and free energy of hydrolysis, but not in the energy charge. The alterations in cytosolic phosphorylation potential following trauma were linearly correlated with the changes in intracellular free Mg2+ concentration. None of the individual bioenergetic parameters could be correlated with the severity of injury over the entire injury range; however, an association between cytosolic phosphorylation potential and reversibility of injury was apparent. These results suggest that reductions in cellular bioenergetic state following traumatic brain injury occur through a posttraumatic decrease in the cells' capacity for oxidative phosphorylation, which itself may be directly related to the intracellular free Mg2+ concentration.     

Effects of magnesium administration on brain edema and blood-brain barrier breakdown after experimental traumatic brain injury in rats

In this study, we examined the effects of magnesium sulfate administration on brain edema and blood-brain barrier breakdown after experimental traumatic brain injury in rats. Seventy-one adult male Sprague-Dawley rats were anesthetized, and experimental closed head trauma was induced by allowing a 450-g weight to fall from a 2-m height onto a metallic disk fixed to the intact skull. Sixty-eight surviving rats were randomly assigned to receive an intraperitoneal bolus of either 750 micromol/kg magnesium sulfate (group 4; n = 30) or 1 mL of saline (group 2; n = 30) 30 minutes after induction of traumatic brain injury; 39 nontraumatized animals received saline (group 1; n = 21) or magnesium sulfate (group 3; n = 18) with an identical protocol of administration. Brain water content and brain tissue specific gravity, as indicators of brain edema, were measured 24 hours after traumatic brain injury. Blood-brain barrier integrity was evaluated quantitatively 24 hours after injury by spectrophotometric assay of Evans blue dye extravasations. In the magnesium-treated injured group, brain water content was significantly reduced (left hemisphere: group 2, 83.2 +/- 0.8; group 4, 78.4 +/- 0.7 [P <.05]; right hemisphere: group 2, 83.1 +/- 0.7; group 4, 78.4 +/- 0.5. [P <.05]) and brain tissue specific gravity was significantly increased (left hemisphere: group 2, 1.0391 +/- 0.0008; group 4, 1.0437 +/- 0.001 [P <.05]; right hemisphere, group 2, 1.0384 +/- 0.001; group 4, 1.0442 +/- 0.005 [P <.05]) compared with the saline-treated injured group. Evans blue dye content in the brain tissue was significantly decreased in the magnesium-treated injured group (left hemisphere: group 2, 0.0204 +/- 0.03; group 4, 0.0013 +/- 0.0002 [P <.05]; right hemisphere: group 2, 0.0064 +/- 0.0009; group 4, 0.0013 +/- 0.0003 [P <.05]) compared with the saline-treated injured group. The findings of the present study support that beneficial effects of magnesium sulfate exist after severe traumatic brain injury in rats. These results also indicate that a blood-brain barrier permeability defect occurs after this model of diffuse traumatic brain injury, and magnesium seems to attenuate this defect.     

Characterization of plasma magnesium concentration and oxidative stress following graded traumatic brain injury in humans

Plasma magnesium, calcium, and oxidative status were investigated in 31 male casualties with traumatic brain injury (TBI) during a 7-day posttraumatic period. The study group consisted of eight patients with mild closed head injury (Glasgow Coma Scale score [GCS] of 13-15), 10 patients with extensive penetrating head injury (GCS 4-6), and 13 patients with blast injuries but without direct head trauma. The latter group was included since previous experimental and clinical data have confirmed the development of indirect brain trauma in patients with blast injuries. Patients with multiple injuries were not included. Significant declines in plasma divalent cations were found in GCS 4-6 patients immediately after TBI and persisting for the entire 7-day study period. Similar changes in magnesium, but not calcium, were present in the GCS 13-15 and the blast injury groups, but only up until day 3 after injury. Alterations in lipid peroxidation products and superoxide anions were also observed following TBI. Increased lipid peroxidation was noted in all three groups over the entire posttraumatic period while increases in superoxide anion generation occurred transiently immediately following TBI. Thereafter, in the GCS 13-15 and blast injury groups, superoxide anions subsequently normalized, whereas in extensive head injury (GCS 4-6), superoxide anion generation significantly declined. A negative correlation between magnesium balance and oxidative stress was observed in all patients immediately after injury persisting in GCS 4-6 patients to the end of the observation period. Our findings suggest an interrelationship between magnesium changes and blood oxidants/antioxidants after TBI, which could be of both diagnostic and prognostic value in patients with neurotrauma.     

Effects of magnesium sulfate on traumatic brain edema in rats

svarietyofneuroprotectiveagentshavebeensynthesized .However ,besidessomeagentspresentlybeingevaluatedinclinicaltrails ,mostofthesecompoundshavelimitedclinicalusebecauseofneurotoxicityandbehavioralsideeffects .Recently ,severalstudiesdemonstratedthattraumaticinjurytothebraincausesadecreaseinmagnesiumconcentrationcorrelatedwithinjuryseverity .1Sincethen ,moreandmoreattentionhasbeen paidtoMgSO4 foritsneuroprotectiveeffects .Magnesiumsulfatehasbeenwidelyusedinclinicalpracticeforalmost 10 0 years.…     

Effects of magnesium sulfate on traumatic brain edema in ats

OBJECTIVE: To investigate the effects of magnesium sulfate on traumatic brain edema and explore its possible mechanism. METHODS: Forty-eight Sprague-Dawley (SD) rats were randomly divided into three groups: Control, Trauma and Treatment groups. In Treatment group, magnesium sulfate was intraperitoneally administered immediately after the induction of brain trauma. At 24 h after trauma, total tissue water content and Na(+), K(+), Ca(2+), Mg(2+) contents were measured. Permeability of blood-brain barrier (BBB) was assessed quantitatively by Evans Blue (EB) dye technique. The pathological changes were also studied. RESULTS: Water, Na(+), Ca(2+) and EB contents in Treatment group were significantly lower than those in Trauma group (P<0.05). Results of light microscopy and electron microscopy confirmed that magnesium sulfate can attenuate traumatic brain injury and relieve BBB injury. CONCLUSIONS: Treatment with MgSO4 in the early stage can attenuate traumatic brain edema and prevent BBB injury.     

Pretreatment with phencyclidine, an N-methyl-D-aspartate antagonist, attenuates long-term behavioral deficits in the rat produced by traumatic brain injury

This study examined the effects of pretreatment with phencyclidine (PCP), a selective N-methyl-D-aspartate (NMDA) antagonist, on behavioral and physiologic responses of the rat to experimental traumatic brain injury (TBI). For the behavioral experiments, rats were administered either saline or PCP (1.0, 2.0, or 4.0 mg/kg, intrapentoneally [IP] 15 min before TBI. Rats were ventilated as necessary following injury. The duration of acute suppression of several reflexes (pinna, corneal, righting, and flexion) and responses (escape, head support, and spontaneous locomotion) was recorded for up to 70 min after trauma. Longer-term behavioral assessments (beam walking, beam balance, inclined plane, ambulatory activity, and body weight) were made for up to 10 days after trauma. PCP did not significantly alter the duration of acute behavioral suppression. At a dosage of 1.0 mg/kg, PCP significantly attenuated all long-term deficits except beam walking. Maximal protection against beam walking deficits was provided by the 4.0 mg/kg dosage of PCP. Sixty-three percent of saline-treated animals died within 10 days after injury. For rats pretreated with 1.0, 2.0, and 4.0 mg/kg of PCP, 40%, 23%, and 33% died, respectively. In physiologic experiments, pretreatment with 4.0 mg/kg of PCP (IP) 15 min before injury did not significantly affect systemic cardiovascular responses, plasma glucose levels, or blood gas levels observed within 30 min after injury. While the possibility of effects mediated by other neurotransmitter systems cannot be excluded, these data suggest that NMDA agonist-receptor interactions contribute to the pathophysiology of brain injury. In addition, neural mechanisms that mediate transient unconsciousness following moderate levels of head injury may differ from mechanisms that mediate more persistent neurologic deficits.     

Subdural hematoma following traumatic brain injury causes a secondary decline in brain free magnesium concentration

A number of studies have demonstrated that neurologic motor and cognitive deficits induced by traumatic brain injury (TBI) can be attenuated with administration of magnesium salts. However, many severe traumatic brain injuries have a significant hematoma that develops subsequent to the primary events, and it is unclear whether magnesium salts are effective in this situation. In the present study, an impact-acceleration rodent model of TBI was used to produce an injury that causes an extensive subdural hematoma in over 50% of injured animals. At 30 min after TBI, rats were randomly administered 250 micromoles/kg intravenous MgSO4 or equal volume saline before being monitored by magnetic resonance spectroscopy for 8 h to determine brain intracellular free magnesium concentration. Animals were then assessed for neurologic motor deficits over 1 week using a rotarod device, followed by postmortem examination for presence of subdural hematoma. Animals with subdural hematoma treated with MgSO4 showed no improvement in motor outcome when compared to nontreated controls. Animals with no visible subdural hematoma demonstrated a significant improvement (p < 0.05 by ANOVA) in rotarod scores with MgSO4 treatment. Brain free magnesium concentration in the magnesium treated/hematoma group demonstrated a biphasic decline made up of an immediate initial decline, recovery of brain magnesium levels with MgSO4 treatment, and then a significant second magnesium decline (p < 0.05). Such a secondary decline did not occur in the Mg treated/no hematoma animals. Our results suggest that development of a subdural hematoma following TBI results in a decline in brain magnesium, even after bolus administration of magnesium salts. Such effects of hematoma development will need to be considered in trials examining efficacy of magnesium salts as an intervention following TBI.     

Proton MRS in acute traumatic brain injury: role for glutamate/glutamine and choline for outcome prediction

Proton magnetic resonance spectroscopy (MRS) is being used to evaluate individuals with acute traumatic brain injury and several studies have shown that changes in certain brain metabolites (N-acetylaspartate, choline) are associated with poor neurologic outcomes. The majority of previous MRS studies have been obtained relatively late after injury and none have examined the role of glutamate/ glutamine (Glx). We conducted a prospective MRS study of 42 severely injured adults to measure quantitative metabolite changes early (7 days) after injury in normal appearing brain. We used these findings to predict long-term neurologic outcome and to determine if MRS data alone or in combination with clinical outcome variables provided better prediction of long-term outcomes. We found that glutamate/glutamine (Glx) and choline (Cho) were significantly elevated in occipital gray and parietal white matter early after injury in patients with poor long-term (6-12-month) outcomes. Glx and Cho ratios predicted long-term outcome with 94% accuracy and when combined with the motor Glasgow Coma Scale score provided the highest predictive accuracy (97%). Somatosensory evoked potentials were not as accurate as MRS data in predicting outcome. Elevated Glx and Cho are more sensitive indicators of injury and predictors of poor outcome when spectroscopy is done early after injury. This may be a reflection of early excitotoxic injury (i.e., elevated Glx) and of injury associated with membrane disruption (i.e., increased Cho) secondary to diffuse axonal injury.     

Effect of posttraumatic hyperglycemia on contusion volume and neutrophil accumulation after moderate fluid-percussion brain injury in rats

The purpose of this study was to evaluate the effects of posttraumatic hyperglycemia on contusion volume and neutrophil accumulation following moderate traumatic brain injury (TBI) in rats. A parasagittal fluid-percussion (F-P) brain injury (1.8-2.1 atm) was induced in male Sprague-Dawley rats. Rats were then randomized into four trauma groups (n = 7/group) by the timing of dextrose injection (2.0 gm/kg/ip), which included (1) early (E) group: 5 min after TBI; (2) delayed (D) group: 4 h after TBI; (3) 24-h group: 24 h after TBI; or (4) control (C) group: no dextrose injection. A sham operated control group also received dextrose to document physiological parameters (n = 4). Rats were perfusion fixed 3 days following TBI, and the brains were processed for routine histopathological and immunocytochemical analysis. Contusion areas and volumes, as well as the frequency of myeloperoxidase immunoreactive polymorphonuclear leukocytes (PMNLs) were determined. Dextrose injections significantly increased blood glucose levels (p < 0.005) in all treated groups. Although acute hyperglycemia following TBI did not significantly affect total contusion volume, contusion area was significantly elevated in the early treatment group. In addition, early posttraumatic hyperglycemia enhanced neutrophil accumulation in the area of the cortical contusion (p < 0.005). In contrast, delayed induced hyperglycemia (i.e., 4 h, 24 h) did not significantly affect histopathological outcome or neutrophil accumulation. Taken together, these findings indicate that acute but not delayed hyperglycemia aggravates histopathological outcome and increased accumulation of PMNLs. Posttraumatic hyperglycemia in the acute phase may worsen traumatic outcome by enhancing secondary injury processes, including inflammation.     

Postinjury treatment with magnesium chloride attenuates cortical damage after traumatic brain injury in rats

The neuroprotective effect of magnesium chloride (MgCl2), a compound previously demonstrated to improve behavioral and neurochemical outcome in several models of experimental brain injury, was evaluated in the present study. Male Sprague-Dawley rats were anesthetized and subjected to lateral fluid-percussion brain injury of moderate severity (2.5-2.8 atm). A cannula was implanted in the left femoral vein and at 1 h following injury, animals randomly received a 15 min i.v. infusion of either MgCl2 (125 micromol/rat) or saline. A second group of animals received anesthesia, surgery, and either MgCl2 or vehicle to serve as uninjured (sham) controls. Two weeks following brain injury, animals were sacrificed, brains removed, and coronal sections were taken for quantitative analysis of cortical lesion volume and hippocampal CA3 cell counts. Traumatic brain injury resulted in a lesion in the ipsilateral cortex and loss of pyramidal neurons in the CA3 region of the hippocampus in vehicle-treated animals (p < 0.01 vs. uninjured animals). Administration of MgCl2 significantly reduced the injury-induced damage in the cortex (p < 0.01) but did not alter posttraumatic cell loss in the CA3 region of the ipsilateral hippocampus. The present study demonstrates that, in addition to its beneficial effects on behavioral outcome, MgCl2 treatment attenuates cortical histological damage when administered following traumatic brain injury.     

Sequential pharmacotherapy with magnesium chloride and basic fibroblast growth factor after fluid percussion brain injury results in less neuromotor efficacy than that achieved with magnesium alone

Combinational pharmacotherapy with individually efficacious agents is a potential strategy for the treatment of traumatic central nervous system (CNS) injury. Basic fibroblast growth factor (bFGF) has been shown to be neuroprotective against excitotoxic, ischemic, and traumatic injury to the CNS, while acute posttraumatic treatment with magnesium (Mg2+) has been shown to decrease the motor and cognitive deficits following experimental brain injury. In this study, bFGF and Mg2+ were evaluated separately and in combination to assess their potential additive effects on posttraumatic neurological recovery and histological cell loss (lesion volume). Twenty minutes after fluid percussion (FP) brain injury of moderate severity (2.2-2.4 atm), anesthetized rats received a 15-min intravenous infusion of either 125 mumol of MgCl2 or vehicle, followed 5 min later by a 24-h constant intravenous infusion of either bFGF (16 micrograms/h) or vehicle. Injured animals had a significant motor deficit when compared to sham (uninjured) animals at both 48 h and 7 days postinjury. At 48 h postinjury, there were no significant differences among injured animals when compared by treatment. By 7 days postinjury, injured animals treated with MgCl2 alone displayed significantly improved motor function when compared to brain-injured, vehicle-treated animals (p < 0.05). Animals treated with either bFGF alone or a combination of MgCl2 and bFGF displayed no significant neurological improvement relative to vehicle-treated injured animals at 7 days. No effect of any drug treatment of combination was observed on the extent of the postinjury lesion volume in the injured cortex. These results suggest that caution must be exercised when combining "cocktails" of potentially neuroprotective compounds in the setting of traumatic brain injury.     

Association between elevated brain tissue glycerol levels and poor outcome following severe traumatic brain injury

OBJECT: Glycerol is considered to be a marker of cell membrane degradation and thus cellular lysis. Recently, it has become feasible to measure via microdialysis cerebral extracellular fluid (ECF) glycerol concentrations at the patient's bedside. Therefore the aim of this study was to investigate the ECF concentration and time course of glycerol after severe traumatic brain injury (TBI) and its relationship to patient outcome and other monitoring parameters. METHODS: As soon as possible after injury for up to 4 days, 76 severely head-injured patients were monitored using a microdialysis probe (cerebral glycerol) and a Neurotrend sensor (brain tissue PO2) in uninjured brain tissue confirmed by computerized tomography scanning. The mean brain tissue glycerol concentration in all monitored patients decreased significantly from 206 +/- 31 micromol/L on Day 1 to 9 +/- 3 micromol/L on Day 4 after injury (p < 0.0001). Note, however, that there was no significant difference in the time course between patients with a favorable outcome (Glasgow Outcome Scale [GOS] Scores 4 and 5) and those with an unfavorable outcome (GOS Scores 1-3). Significantly increased glycerol concentrations were observed when brain tissue PO2 was less than 10 mm Hg or when cerebral perfusion pressure was less than 70 mm Hg. CONCLUSIONS: Based on results in the present study one can infer that microdialysate glycerol is a marker of severe tissue damage, as seen immediately after brain injury or during profound tissue hypoxia. Given that brain tissue glycerol levels do not yet add new clinically significant information, however, routine monitoring of this parameter following traumatic brain injury needs further validation.     

Prognostic role of proton magnetic resonance spectroscopy in acute traumatic brain injury

Proton magnetic resonance spectroscopy (MRS) is being used to evaluate individuals after acute traumatic brain injury. These studies have shown that changes in certain brain metabolites are associated with poor neurologic outcomes. The majority of MRS studies have been obtained relatively late after injury, but there have been a few reports of use early after injury to assist with outcome prediction. Altered brain metabolites may be sensitive indicators of injury and thus provide additional prognostic information when spectroscopy is done early after injury. This technology may provide a noninvasive means to evaluate early excitotoxic injury, and show changes associated with both neuronal injury and membrane disruption secondary to diffuse axonal injury. This article will review the technology of MRS, discuss its role in patient assessment after traumatic brain injury, and present a summary of our published and ongoing research.     

Improved motor outcome in response to magnesium therapy received up to 24 hours after traumatic diffuse axonal brain injury in rats

OBJECT: The goal of this study was to establish the therapeutic window during which delayed therapy with MgSO4 improves neurological motor outcome in rats that have suffered severe traumatic axonal brain injury. METHODS: Severe brain injury was induced in male Sprague-Dawley rats by using the impact-acceleration model of severe traumatic diffuse axonal brain injury. Injured animals were subsequently treated with MgSO4 (750 micromol/kg) infused intramuscularly at 30 minutes or at 8, 12, or 24 hours after trauma and were tested for neurological motor outcome during the following week by using the rotarod test. Injured untreated (control) animals demonstrated highly significant (p < 0.001) neurological motor deficits that were sustained over the 1-week assessment period. Animals treated with MgSO4 at 30 minutes or at 8 or 12 hours postinjury demonstrated significantly improved motor outcomes compared with untreated control animals at all time points (0.001 < p < 0.05). Animals treated with MgSO4 at 24 hours had motor scores that were similar to those of untreated control animals early in the week, but demonstrated a significantly more rapid recovery in function and, by the end of the assessment period, they demonstrated significantly improved motor scores (p < 0.01). Repeated administration of MgSO4 over the 1-week observation period did not further improve outcome. CONCLUSIONS: The present results demonstrate that Mg++ plays a neuroprotective role following severe diffuse traumatic axonal brain injury. Moreover, Mg++ therapy significantly improved motor outcome when administered up to 24 hours after injury, with early treatments providing the most significant benefit. Repeated administration beyond 24 hours postinjury did not provide additional neuroprotection.     

Minocycline reduces traumatic brain injury-mediated caspase-1 activation, tissue damage, and neurological dysfunction

OBJECTIVE: Caspase-1 plays an important functional role mediating neuronal cell death and dysfunction after experimental traumatic brain injury (TBI) in mice. Minocycline, a derivative of the antibiotic tetracycline, inhibits caspase-1 expression. This study investigates whether minocycline can ameliorate TBI-mediated injury in mice. METHODS: Brains from mice subjected to traumatic brain injury underwent immunohistochemical analyses for caspase-1, caspase-3, and a neuronal specific marker (NeuN). Minocycline- and saline-treated mice subjected to traumatic brain injury were compared with respect to neurological function, lesion volume, and interleukin-1beta production. RESULTS: Immunohistochemical analysis revealed that activated caspase-1 and caspase-3 are present in neurons 24 hours after TBI. Intraperitoneal administration of minocycline 12 hours before or 30 minutes after TBI in mice resulted in improved neurological function when compared with mice given saline control, as assessed by Rotarod performance 1 to 4 days after TBI. The lesion volume, assessed 4 days after trauma, was significantly decreased in mice treated with minocycline before or after trauma when compared with saline-treated mice. Caspase-1 activity, quantified by measuring mature interleukin-1beta production by enzyme-linked immunosorbent assay, was considerably increased in mice that underwent TBI, and this increase was significantly diminished in minocycline-treated mice. CONCLUSION: We show for the first time that caspase-1 and caspase-3 activities localize specifically within neurons after experimental brain trauma. Further, these results indicate that minocycline is an effective pharmacological agent for reducing tissue injury and neurological deficits that result from experimental TBI, likely through a caspase-1-dependent mechanism. These results provide an experimental rationale for the evaluation of minocycline in human trauma patients.     

Effects of tacrolimus on hemispheric water content and cerebrospinal fluid levels of glutamate, hypoxanthine, interleukin-6, and tumor necrosis factor-alpha following controlled cortical impact injury in rats

OBJECT: Disturbance of calcium homeostasis contributes to evolving tissue damage and energetic impairment following traumatic brain injury (TBI). Calcium-mediated activation of calcineurin results in production of tissue-damaging nitric oxide and free oxygen radicals. Inhibition of calcineurin induced by the immunosuppressant tacrolimus (FK506) has been shown to reduce structural and functional damage after ischemia. The aims of the present study were to investigate time- and dose-dependent short-term antiedematous effects of tacrolimus following TBI. METHODS: A left temporoparietal contusion (controlled cortical impact injury [CCII]) was induced in 51 male Sprague-Dawley rats. Tacrolimus (1 or 3 mg/kg body weight) was administered by a single intraperitoneal injection at 5 minutes, 30 minutes, or 4 hours after CCII occurred. Control rats received physiological saline. Water contents of traumatized and nontraumatized hemispheres, as well as cerebrospinal fluid (CSF) levels of mediators reflecting tissue damage (the proinflammatory cytokines interleukin [IL]-6 and tumor necrosis factor [TNF]-alpha, the excitotoxin glutamate, and the adenosine triphosphate-degradation product hypoxanthine), were determined 24 hours after trauma. Although CSF levels of IL-6 and TNFalpha were completely suppressed by tacrolimus at all time points and at both concentrations, CSF levels of glutamate and hypoxanthine, as well as edema formation, were only marginally influenced. Significant reduction of cerebral water content was confined to nontraumatized hemispheres. In addition, the higher dose of tacrolimus failed to exert significant antiedematous effects on traumatized hemispheres. CONCLUSIONS: Under the present study design, the potency of tacrolimus in reducing edema formation following CCII seems limited. However, its immunosuppressive effects could be of value in influencing the posttraumatic inflammatory response known to aggravate tissue damage.     

Effects of the N-methyl-D-aspartate receptor blocker MK-801 on neurologic function after experimental brain injury

Pharmacologic inhibition of excitatory amino acid (EAA) neurotransmission attenuates cell death in models of global and focal ischemia and hypoglycemia and improves neurologic outcome after experimental traumatic spinal cord injury. The present study examined the effects of the noncompetitive N-methyl-D-aspartate (NMDA) receptor blocker MK-801 on cardiovascular and neurologic function after experimental fluid-percussion (FP) brain injury in the rat. Animals received either an intravenous bolus of MK-801 (1 mg/kg) or saline (equal volume) 15 min prior to FP brain injury or 15 min following FP brain injury. MK-801 pretreatment significantly improved postinjury cardiovascular variables and attenuated postinjury neurologic dysfunction. Postinjury treatment with MK-801 also significantly improved cardiovascular variables, but had little effect on postinjury neurologic scores. These results suggest that EAA neurotransmitters may be involved in the pathophysiological sequelae of traumatic brain injury and that noncompetitive blockade of the NMDA receptor prior to brain injury may reduce EAA-induced damage and limit neurologic dysfunction.     

Interaction between anesthesia,gender, and functional outcome task following diffuse traumatic brain injury in rats

A number of experimental and clinical studies have demonstrated that functional outcome following traumatic brain injury differs between males and females. Some studies report that females have a better outcome than males following trauma while others report the opposite. In experimental studies, some of the contradictory results may be due to the different experimental conditions, including type of anesthesia and the outcome measures employed. In the present study we have used three different anesthetic protocols and four different outcome measures to determine how these parameters interact and affect functional outcome following traumatic brain injury in male and female rats. Diffuse traumatic brain injury was induced in adult male and female animals using the impact-acceleration brain injury model. Mortality in female animals was no different than males when using halothane anesthesia, slightly better than males when using isoflurane anesthesia, but significantly worse than males under pentobarbital anesthesia. Female animals always performed better than males on rotarod tests of motor outcome, with this effect being unrelated to anesthetic effects. Conversely, in cognitive tests using the Barnes Maze, only isoflurane-anesthetized females performed better than their male counterparts. Similarly, in an open field activity task, females always performed better than males after trauma, with isoflurane-anesthetized females also performing significantly better than the halothane-anesthetized female group after injury. Our results suggest that female animals do better than males after diffuse traumatic brain injury, although this observation is dependent upon the type of anesthesia and the functional task employed. Isoflurane is particularly protective in females, pentobarbital is deleterious to female outcome, while halothane anesthesia has the least influence on gender-related outcome.     

Downregulation of matrix metalloproteinase-9 and attenuation of edema via inhibition of ERK mitogen activated protein kinase in traumatic brain injury

Emerging data suggest that matrix metalloproteinase-9 (MMP-9) plays a critical role in the pathophysiology of brain injury. However, the regulatory mechanisms involved in vivo remain unclear. In this study, we focus on a mitogen activated protein kinase (MAPK) pathway that may trigger MMP-9 after traumatic brain injury. We aim to show that inhibition of the extracellular signal regulated kinase (ERK) would attenuate MMP-9 levels, reduce blood-brain barrier damage, and attenuate edema after trauma induced by controlled cortical impact in mouse brain. Western blots showed that phospho-ERK was rapidly upregulated after trauma. Treatment with U0126, which inhibits MEK, the kinase upstream of ERK, effectively prevented the activation of ERK. After trauma, gelatin zymography showed an increase in MMP-9. U0126 significantly reduced trauma-induced MMP-9 levels. Correspondingly, U0126 ameliorated the degradation of the tight junction protein ZO-1, which is an MMP-9 substrate, and significantly attenuated tissue edema. At 7 days after trauma, traumatic lesion volumes were significantly reduced by U0126 compared with saline-treated controls. These data indicate that the ERK MAPK pathway triggers the upregulation in MMP-9 after trauma, and further suggest that targeting the upstream signaling mechanisms that regulate deleterious MMP-9 activity may reveal new therapeutic opportunities for traumatic brain injury.     

Hyperglycemia and outcomes from pediatric traumatic brain injury

BACKGROUND: The clinical significance of hyperglycemia after pediatric traumatic brain injury is controversial. This study addresses the relationship between hyperglycemia and outcomes after traumatic brain injury in pediatric patients. METHODS: We identified trauma patients admitted during a single year to our regional pediatric referral center with head regional Abbreviated Injury Scale scores > or = 3. We studied identified patients for admission characteristics potentially influencing their outcomes. The primary outcome measure was Glasgow Outcome Scale score. RESULTS: Patients who died had significantly higher admission serum glucose values than those patients who survived (267 mg/dL vs. 135 mg/dL; p = 0.000). Admission serum glucose > or = 300 mg/dL was uniformly associated with death. Admission Glasgow Coma Scale score (odds ratio, 0.560; 95% confidence interval, 0.358-0.877) and serum glucose (odds ratio, 1.013; 95% confidence interval, 1.003-1.023) are independent predictors of mortality in children with traumatic head injuries. CONCLUSION Hyperglycemia and poor neurologic outcome in head-injured children are associated. The pathophysiology of hyperglycemia in neurologic injury after head trauma remains unclear.