Your search keyword '"Fiskum G"' showing total 20 results

1. Hyperoxic resuscitation improves survival but worsens neurologic outcome in a rat polytrauma model of traumatic brain injury plus hemorrhagic shock.

Author

Proctor JL, Scutella D, Pan Y, Vaughan J, Rosenthal RE, Puche A, and Fiskum G

Subjects

Animals, Brain Injuries physiopathology, Disease Models, Animal, Male, Multiple Trauma physiopathology, Multiple Trauma therapy, Random Allocation, Rats, Rats, Sprague-Dawley, Shock, Hemorrhagic physiopathology, Survival Rate, Brain Injuries therapy, Oxygen Inhalation Therapy, Resuscitation methods, Shock, Hemorrhagic therapy

Abstract

Background: Many traumatic brain injury (TBI) patients experience additional injuries, including those that result in hemorrhagic shock (HS). Interactions between HS and TBI can include reduced brain O2 delivery, resulting in partial cerebral ischemia and worse neurologic outcome. This study tested the hypothesis that inspiration of 100% O2 during resuscitation following TBI and HS improves survival, reduces brain lesion volume, and improves neurologic outcome compared with resuscitation in the absence of supplemental O2., Methods: The adult male rat polytrauma model consisted of controlled cortical impact-induced TBI followed by 30 minutes of HS (mean arterial pressure, 35-40 mm Hg) induced by blood withdrawal. The HS phase was followed by a 1-hour "prehospital" Hextend fluid resuscitation phase and then a 1-hour "hospital phase" when shed blood was reinfused. Rats were randomized on the day of surgery to three groups with 10 per group: sham, polytrauma normoxic, and polytrauma hyperoxic. Normoxic animals inspired room air, and hyperoxic animals inspired 100% O2 during both resuscitation phases. Neurobehavioral tests were conducted weekly until the rats were perfused with fixative at 30 days after injury. Brain sections were stained with Fluoro Jade B and used for quantification of contusion, penumbral, and healthy cortical volumes., Results: Survival was greater following hyperoxic compared with normoxic resuscitation. Composite neuroscores obtained at 2 weeks to 4 weeks following hyperoxic resuscitation were lower than those of shams. Balance beam foot faults measured at 2 weeks after injury were greater following hyperoxic resuscitation compared with normoxic resuscitation and those of shams. There was no significant difference in cerebrocortical pathology between the normoxic and hyperoxic polytrauma groups., Conclusion: The survival of rats following controlled cortical impact plus HS was greater following hyperoxic resuscitation. In contrast, neurologic outcomes were better following normoxic resuscitation.

Published

2015

2. Rat model of brain injury caused by under-vehicle blast-induced hyperacceleration.

Author

Proctor JL, Fourney WL, Leiste UH, and Fiskum G

Subjects

Acceleration adverse effects, Animals, Blast Injuries etiology, Bombs, Brain pathology, Brain Injuries etiology, Disease Models, Animal, Male, Rats, Rats, Sprague-Dawley, Blast Injuries pathology, Brain Injuries pathology

Abstract

Background: More than 300,000 US war fighters in Operations Iraqi and Enduring Freedom have sustained some form of traumatic brain injury (TBI), caused primarily by exposure to blasts. Many victims are occupants in vehicles that are targets of improvised explosive devices. These underbody blasts expose the occupants to vertical acceleration that can range from several to more than 1,000 G; however, it is unknown if blast-induced acceleration alone, in the absence of exposure to blast waves and in the absence of secondary impacts, can cause even mild TBI., Methods: We approached this knowledge gap using rats secured to a metal platform that is accelerated vertically at either 20 G or 50 G in response to detonation of a small explosive (pentaerythritol tetranitrate) located at precise underbody standoff distances. All rats survived the blasts and were perfusion fixed for brain histology at 4 hours to 30 days later., Results: Robust silver staining indicative of axonal injury was apparent throughout the internal capsule, corpus callosum, and cerebellum within 24 hours after blast exposure and was sustained for at least 7 days. Astrocyte activation, as measured morphologically with brains immunostained for glial fibrillary acidic protein, was also apparent early after the blast and persisted for at least 30 days., Conclusion: Exposure of rats to underbody blast-induced accelerations at either 20 G or 50 G results in histopathologic evidence of diffuse axonal injury and astrocyte activation but no significant neuronal death. The significance of these results is that they demonstrate that blast-induced vertical acceleration alone, in the absence of exposure to significant blast pressures, causes mild TBI. This unique animal model of TBI caused by underbody blasts may therefore be useful in understanding the pathophysiology of blast-induced mild TBI and for testing medical and engineering-based approaches toward mitigation.

Published

2014

3. Cerebral glucose metabolism in an immature rat model of pediatric traumatic brain injury.

Author

Robertson CL, Saraswati M, Scafidi S, Fiskum G, Casey P, and McKenna MC

Subjects

Age Factors, Animals, Animals, Newborn, Brain Injuries pathology, Male, Rats, Rats, Sprague-Dawley, Brain Injuries metabolism, Cerebral Cortex metabolism, Disease Models, Animal, Glucose metabolism

Abstract

Altered cerebral metabolism and mitochondrial function have been identified in experimental and clinical studies of pediatric traumatic brain injury (TBI). Metabolic changes detected using (1)H (proton) magnetic resonance spectroscopy correlate with long-term outcomes in children after severe TBI. We previously identified early (4-h) and sustained (24-h and 7-day) abnormalities in brain metabolites after controlled cortical impact (CCI) in immature rats. The current study aimed to identify specific alterations of cerebral glucose metabolism at 24 h after TBI in immature rats. Rats (postnatal days 16-18) underwent CCI to the left parietal cortex. Sham rats underwent craniotomy only. Twenty-four hours after CCI, rats were injected (intraperitoneally) with [1,6-(13)C]glucose. Brains were removed, separated into hemispheres, and frozen. Metabolites were extracted with perchloric acid and analyzed using (1)H and (13)C-nuclear magnetic resonance spectroscopy. TBI resulted in decreases in N-acetylaspartate in both hemispheres, compared to sham contralateral. At 24 h after TBI, there was significant decrease in the incorporation of (13)C label into [3-(13)C]glutamate and [2-(13)C]glutamate in the injured brain. There were no differences in percent enrichment of [3-(13)C]glutamate, [4-(13)C]glutamate, [3-(13)C]glutamine, or [4-(13)C]glutamine. There was significantly lower percent enrichment of [2-(13)C]glutamate in both TBI sides and the sham craniotomy side, compared to sham contralateral. No differences were detected in enrichment of (13)C glucose label in [2-(13)C]glutamine, [2-(13)C]GABA (gamma-aminobutyric acid), [3-(13)C]GABA, or [4-(13)C]GABA, [3-(13)C]lactate, or [3-(13)C]alanine between groups. Results suggest that overall oxidative glucose metabolism in the immature brain recovers at 24 h after TBI. Specific reductions in [2-(13)C]glutamate could be the result of impairments in either neuronal or astrocytic metabolism. Future studies should aim to identify pathways leading to decreased metabolism and develop cell-selective "metabolic rescue."

Published

2013

4. Cellular alterations in human traumatic brain injury: changes in mitochondrial morphology reflect regional levels of injury severity.

Author

Balan IS, Saladino AJ, Aarabi B, Castellani RJ, Wade C, Stein DM, Eisenberg HM, Chen HH, and Fiskum G

Subjects

Adolescent, Adult, Aged, Female, Humans, Male, Microscopy, Electron, Transmission, Middle Aged, Young Adult, Brain ultrastructure, Brain Injuries pathology, Mitochondria ultrastructure

Abstract

Mitochondrial dysfunction may be central to the pathophysiology of traumatic brain injury (TBI) and often can be recognized cytologically by changes in mitochondrial ultrastructure. This study is the first to broadly characterize and quantify mitochondrial morphologic alterations in surgically resected human TBI tissues from three contiguous cortical injury zones. These zones were designated as injury center (Near), periphery (Far), and Penumbra. Tissues from 22 patients with TBI with varying degrees of damage and time intervals from TBI to surgical tissue collection within the first week post-injury were rapidly fixed in the surgical suite and processed for electron microscopy. A large number of mitochondrial structural patterns were identified and divided into four survival categories: normal, normal reactive, reactive degenerating, and end-stage degenerating profiles. A tissue sample acquired at 38 hours post-injury was selected for detailed mitochondrial quantification, because it best exhibited the wide variation in cellular and mitochondrial changes consistently noted in all the other cases. The distribution of mitochondrial morphologic phenotypes varied significantly between the three injury zones and when compared with control cortical tissue obtained from an epilepsy lobectomy. This study is unique in its comparative quantification of the mitochondrial ultrastructural alterations at progressive distances from the center of injury in surviving TBI patients and in relation to control human cortex. These quantitative observations may be useful in guiding the translation of mitochondrial-based neuroprotective interventions to clinical implementation.

Published

2013

5. Diffusion kurtosis as an in vivo imaging marker for reactive astrogliosis in traumatic brain injury.

Author

Zhuo J, Xu S, Proctor JL, Mullins RJ, Simon JZ, Fiskum G, and Gullapalli RP

Subjects

Animals, Anisotropy, Diffusion Magnetic Resonance Imaging, Diffusion Tensor Imaging, Male, Rats, Rats, Sprague-Dawley, Brain Injuries pathology, Gliosis pathology, Neuroimaging methods

Abstract

Diffusion Kurtosis Imaging (DKI) provides quantifiable information on the non-Gaussian behavior of water diffusion in biological tissue. Changes in water diffusion tensor imaging (DTI) parameters and DKI parameters in several white and gray matter regions were investigated in a mild controlled cortical impact (CCI) injury rat model at both the acute (2 h) and the sub-acute (7 days) stages following injury. Mixed model ANOVA analysis revealed significant changes in temporal patterns of both DTI and DKI parameters in the cortex, hippocampus, external capsule and corpus callosum. Post-hoc tests indicated acute changes in mean diffusivity (MD) in the bilateral cortex and hippocampus (p<0.0005) and fractional anisotropy (FA) in ipsilateral cortex (p<0.0005), hippocampus (p=0.014), corpus callosum (p=0.031) and contralateral external capsule (p=0.011). These changes returned to baseline by the sub-acute stage. However, mean kurtosis (MK) was significantly elevated at the sub-acute stages in all ipsilateral regions and scaled inversely with the distance from the impacted site (cortex and corpus callosum: p<0.0005; external capsule: p=0.003; hippocampus: p=0.011). Further, at the sub-acute stage increased MK was also observed in the contralateral regions compared to baseline (cortex: p=0.032; hippocampus: p=0.039) while no change was observed with MD and FA. An increase in mean kurtosis was associated with increased reactive astrogliosis from immunohistochemistry analysis. Our results suggest that DKI is sensitive to microstructural changes associated with reactive astrogliosis which may be missed by standard DTI parameters alone. Monitoring changes in MK allows the investigation of molecular and morphological changes in vivo due to reactive astrogliosis and may complement information available from standard DTI parameters. To date the use of diffusion tensor imaging has been limited to study changes in white matter integrity following traumatic insults. Given the sensitivity of DKI to detect microstructural changes even in the gray matter in vivo, allows the extension of the technique to understand patho-morphological changes in the whole brain following a traumatic insult., (Copyright © 2011 Elsevier Inc. All rights reserved.)

Published

2012

6. Early microstructural and metabolic changes following controlled cortical impact injury in rat: a magnetic resonance imaging and spectroscopy study.

Author

Xu S, Zhuo J, Racz J, Shi D, Roys S, Fiskum G, and Gullapalli R

Subjects

Animals, Brain Chemistry physiology, Brain Injuries metabolism, Cerebral Cortex metabolism, Data Interpretation, Statistical, Diffusion Tensor Imaging, Functional Laterality, Magnetic Resonance Spectroscopy, Male, Rats, Rats, Sprague-Dawley, Brain Injuries pathology, Cerebral Cortex injuries, Cerebral Cortex pathology

Abstract

Understanding tissue alterations at an early stage following traumatic brain injury (TBI) is critical for injury management and limiting severe consequences from secondary injury. We investigated the early microstructural and metabolic profiles using in vivo diffusion tensor imaging (DTI) and proton magnetic resonance spectroscopy ((1)H MRS) at 2 and 4 h following a controlled cortical impact injury in the rat brain using a 7.0 Tesla animal MRI system and compared profiles to baseline. Significant decrease in mean diffusivity (MD) and increased fractional anisotropy (FA) was found near the impact site (hippocampus and bilateral thalamus; p<0.05) immediately following TBI, suggesting cytotoxic edema. Although the DTI parameters largely normalized on the contralateral side by 4 h, a large inter-individual variation was observed with a trend towards recovery of MD and FA in the ipsilateral hippocampus and a sustained elevation of FA in the ipsilateral thalamus (p<0.05). Significant reduction in metabolite to total creatine ratios of N-acetylaspartate (NAA, p=0.0002), glutamate (p=0.0006), myo-inositol (Ins, p=0.04), phosphocholine and glycerophosphocholine (PCh+GPC, p=0.03), and taurine (Tau, p=0.009) were observed ipsilateral to the injury as early as 2 h, while glutamine concentration increased marginally (p=0.07). These metabolic alterations remained sustained over 4 h after TBI. Significant reductions of Ins (p=0.024) and Tau (p=0.013) and marginal reduction of NAA (p=0.06) were also observed on the contralateral side at 4 h after TBI. Overall our findings suggest significant microstructural and metabolic alterations as early as 2 h following injury. The tendency towards normalization at 4 h from the DTI data and no further metabolic changes at 4 h from MRS suggest an optimal temporal window of about 3 h for interventions that might limit secondary damage to the brain. Results indicate that early assessment of TBI patients using DTI and MRS may provide valuable information on the available treatment window to limit secondary brain damage.

Published

2011

7. Neuroprotection by acetyl-L-carnitine after traumatic injury to the immature rat brain.

Author

Scafidi S, Racz J, Hazelton J, McKenna MC, and Fiskum G

Subjects

Animals, Behavior, Animal drug effects, Brain pathology, Brain Injuries pathology, Disease Models, Animal, Male, Neuroprotective Agents therapeutic use, Rats, Rats, Sprague-Dawley, Acetylcarnitine therapeutic use, Brain drug effects, Brain Injuries drug therapy, Recovery of Function drug effects, Vitamin B Complex therapeutic use

Abstract

Traumatic brain injury (TBI) is the leading cause of mortality and morbidity in children and is characterized by reduced aerobic cerebral energy metabolism early after injury, possibly due to impaired activity of the pyruvate dehydrogenase complex. Exogenous acetyl-L-carnitine (ALCAR) is metabolized in the brain to acetyl coenzyme A and subsequently enters the tricarboxylic acid cycle. ALCAR administration is neuroprotective in animal models of cerebral ischemia and spinal cord injury, but has not been tested for TBI. This study tested the hypothesis that treatment with ALCAR during the first 24 h following TBI in immature rats improves neurologic outcome and reduces cortical lesion volume. Postnatal day 21-22 male rats were isoflurane anesthetized and used in a controlled cortical impact model of TBI to the left parietal cortex. At 1, 4, 12 and 23 h after injury, rats received ALCAR (100 mg/kg, intraperitoneally) or drug vehicle (normal saline). On days 3-7 after surgery, behavior was assessed using beam walking and novel object recognition tests. On day 7, rats were transcardially perfused and brains were harvested for histological assessment of cortical lesion volume, using stereology. Injured animals displayed a significant increase in foot slips compared to sham-operated rats (6 ± 1 SEM vs. 2 ± 0.2 on day 3 after trauma; n = 7; p < 0.05). The ALCAR-treated rats were not different from shams and had fewer foot slips compared to vehicle-treated animals (2 ± 0.4; n = 7; p< 0.05). The frequency of investigating a novel object for saline-treated TBI animals was reduced compared to shams (45 ± 5% vs. 65 ± 10%; n = 7; p < 0.05), whereas the frequency of investigation for TBI rats treated with ALCAR was not significantly different from that of shams but significantly higher than that of saline-treated TBI rats (68 ± 7; p < 0.05). The left parietal cortical lesion volume, expressed as a percentage of the volume of tissue in the right hemisphere, was significantly smaller in ALCAR-treated than in vehicle-treated TBI rats (14 ± 5% vs. 28 ± 6%; p < 0.05). We conclude that treatment with ALCAR during the first 24 h after TBI improves behavioral outcomes and reduces brain lesion volume in immature rats within the first 7 days after injury., (Copyright © 2011 S. Karger AG, Basel.)

Published

2010

8. Mitochondrial mechanisms of cell death and neuroprotection in pediatric ischemic and traumatic brain injury.

Author

Robertson CL, Scafidi S, McKenna MC, and Fiskum G

Subjects

Animals, Brain Injuries complications, Brain Injuries drug therapy, Brain Injuries pathology, Brain Injuries therapy, Brain Ischemia complications, Brain Ischemia drug therapy, Brain Ischemia pathology, Child, Energy Metabolism drug effects, Humans, Hypothermia, Induced, Mitochondria drug effects, Mitochondria pathology, Oxidative Stress drug effects, Brain Injuries metabolism, Brain Ischemia metabolism, Cell Death drug effects, Mitochondria metabolism, Neuroprotective Agents pharmacology

Abstract

There are several forms of acute pediatric brain injury, including neonatal asphyxia, pediatric cardiac arrest with global ischemia, and head trauma, that result in devastating, lifelong neurologic impairment. The only clinical intervention that appears neuroprotective is hypothermia initiated soon after the initial injury. Evidence indicates that oxidative stress, mitochondrial dysfunction, and impaired cerebral energy metabolism contribute to the brain cell death that is responsible for much of the poor neurologic outcome from these events. Recent results obtained from both in vitro and animal models of neuronal death in the immature brain point toward several molecular mechanisms that are either induced or promoted by oxidative modification of macromolecules, including consumption of cytosolic and mitochondrial NAD(+) by poly-ADP ribose polymerase, opening of the mitochondrial inner membrane permeability transition pore, and inactivation of key, rate-limiting metabolic enzymes, e.g., the pyruvate dehydrogenase complex. In addition, the relative abundance of pro-apoptotic proteins in immature brains and neurons, and particularly within their mitochondria, predisposes these cells to the intrinsic, mitochondrial pathway of apoptosis, mediated by Bax- or Bak-triggered release of proteins into the cytosol through the mitochondrial outer membrane. Based on these pathways of cell dysfunction and death, several approaches toward neuroprotection are being investigated that show promise toward clinical translation. These strategies include minimizing oxidative stress by avoiding unnecessary hyperoxia, promoting aerobic energy metabolism by repletion of NAD(+) and by providing alternative oxidative fuels, e.g., ketone bodies, directly interfering with apoptotic pathways at the mitochondrial level, and pharmacologic induction of antioxidant and anti-inflammatory gene expression.

Published

2009

9. Delayed cerebral oxidative glucose metabolism after traumatic brain injury in young rats.

Author

Scafidi S, O'Brien J, Hopkins I, Robertson C, Fiskum G, and McKenna M

Subjects

Amino Acids metabolism, Animals, Aspartic Acid metabolism, Brain Edema metabolism, Brain Edema pathology, Glutamic Acid metabolism, Glutamine metabolism, Lactic Acid metabolism, Magnetic Resonance Spectroscopy, Male, Nerve Tissue Proteins biosynthesis, Nerve Tissue Proteins genetics, Neurotransmitter Agents biosynthesis, Oxidation-Reduction, Rats, Rats, Sprague-Dawley, Brain Injuries metabolism, Glucose metabolism

Abstract

Traumatic brain injury (TBI) results in a cerebral metabolic crisis that contributes to poor neurologic outcome. The aim of this study was to characterize changes in oxidative glucose metabolism in early periods after injury in the brains of immature animals. At 5 h after controlled cortical impact TBI or sham surgery to the left cortex, 21-22 day old rats were injected intraperitoneally with [1,6-13C]glucose and brains removed 15, 30 and 60 min later and studied by ex vivo 13C-NMR spectroscopy. Oxidative metabolism, determined by incorporation of 13C into glutamate, glutamine and GABA over 15-60 min, was significantly delayed in both hemispheres of brain from TBI rats. The most striking delay was in labeling of the C4 position of glutamate from neuronal metabolism of glucose in the injured, ipsilateral hemisphere which peaked at 60 min, compared with the contralateral and sham-operated brains, where metabolism peaked at 30 and 15 min, respectively. Our findings indicate that (i) neuronal-specific oxidative metabolism of glucose at 5-6 h after TBI is delayed in both injured and contralateral sides compared with sham brain; (ii) labeling from metabolism of glucose via the pyruvate carboxylase pathway in astrocytes was also initially delayed in both sides of TBI brain compared with sham brain; (iii) despite this delayed incorporation, at 6 h after TBI, both sides of the brain showed apparent increased neuronal and glial metabolism, reflecting accumulation of labeled metabolites, suggesting impaired malate aspartate shuttle activity. The presence of delayed metabolism, followed by accumulation of labeled compounds is evidence of severe alterations in homeostasis that could impair mitochondrial metabolism in both ipsilateral and contralateral sides of brain after TBI. However, ongoing oxidative metabolism in mitochondria in injured brain suggests that there is a window of opportunity for therapeutic intervention up to at least 6 h after injury.

Published

2009

10. Early and sustained alterations in cerebral metabolism after traumatic brain injury in immature rats.

Author

Casey PA, McKenna MC, Fiskum G, Saraswati M, and Robertson CL

Subjects

Alanine analysis, Alanine metabolism, Animals, Animals, Newborn, Aspartic Acid analogs & derivatives, Aspartic Acid analysis, Aspartic Acid metabolism, Brain growth & development, Brain Injuries pathology, Cell Respiration, Choline analysis, Choline metabolism, Creatine analysis, Creatine metabolism, Disease Progression, Glycolysis, Lactic Acid analysis, Lactic Acid metabolism, Magnetic Resonance Spectroscopy, Male, Mitochondria metabolism, Nerve Degeneration metabolism, Nerve Degeneration pathology, Oxidative Phosphorylation, Rats, Rats, Sprague-Dawley, Time Factors, Aging metabolism, Brain metabolism, Brain Injuries metabolism, Energy Metabolism

Abstract

Although studies have shown alterations in cerebral metabolism after traumatic brain injury (TBI), clinical data in the developing brain is limited. We hypothesized that post-traumatic metabolic changes occur early (<24 h) and persist for up to 1 week. Immature rats underwent TBI to the left parietal cortex. Brains were removed at 4 h, 24 h, and 7 days after injury, and separated into ipsilateral (injured) and contralateral (control) hemispheres. Proton nuclear magnetic resonance (NMR) spectra were obtained, and spectra were analyzed for N-acetyl-aspartate (NAA), lactate (Lac), creatine (Cr), choline, and alanine, with metabolite ratios determined (NAA/Cr, Lac/Cr). There were no metabolic differences at any time in sham controls between cerebral hemispheres. At 4 and 24 h, there was an increase in Lac/Cr, reflecting increased glycolysis and/or decreased oxidative metabolism. At 24 h and 7 days, there was a decrease in NAA/Cr, indicating loss of neuronal integrity. The NAA/Lac ratio was decreased ( approximately 15-20%) at all times (4 h, 24 h, 7 days) in the injured hemisphere of TBI rats. In conclusion, metabolic derangements begin early (<24 h) after TBI in the immature rat and are sustained for up to 7 days. Evaluation of early metabolic alterations after TBI could identify novel targets for neuroprotection in the developing brain.

Published

2008

11. Normoxic ventilatory resuscitation following controlled cortical impact reduces peroxynitrite-mediated protein nitration in the hippocampus.

Author

Ahn ES, Robertson CL, Vereczki V, Hoffman GE, and Fiskum G

Subjects

Animals, Disease Models, Animal, Male, Oxidative Stress physiology, Rats, Rats, Sprague-Dawley, Resuscitation, Tyrosine metabolism, Brain Injuries metabolism, Brain Injuries therapy, Hippocampus metabolism, Oxygen Inhalation Therapy methods, Reactive Oxygen Species metabolism, Tyrosine analogs & derivatives

Abstract

Objectives: Ventilatory resuscitation with 100% O2 after severe traumatic brain injury (TBI) raises concerns about the increased production of reactive oxygen species (ROS). The product of peroxynitrite-meditated tyrosine residue nitration, 3-nitrotyrosine (3-NT), is a marker for oxidative damage to proteins. The authors hypothesized that posttraumatic resuscitation with hyperoxia (100% fraction of inspired oxygen [FiO2] concentration) results in increased ROS-induced damage to proteins compared with resuscitation using normoxia (21% FiO2 concentration)., Methods: Male Sprague-Dawley rats underwent controlled cortical impact (CCI) injury and resuscitation with either normoxic or hyperoxic ventilation for 1 hour (5 rats per group). Twenty-four hours after injury, rat hippocampi were evaluated using 3-NT immunostaining. In a second experiment, animals similarly underwent CCI injury and normoxic or hyperoxic ventilation for 1 hour (4 rats per group). One week after injury, neuronal counts were performed after neuronal nuclei immunostaining., Results: The 3-NT staining was significantly increased in the hippocampi of the hyperoxic group. The normoxic group showed a 51.0% reduction of staining in the CA1 region compared with the hyperoxic group and a 50.8% reduction in the CA3 region (p < 0.05, both regions). There was no significant difference in staining between the injured normoxic group and sham-operated control groups. In the delayed analysis of neuronal survival (neuronal counts), there was no significant difference between the hyperoxic and normoxic groups., Conclusions: In this clinically relevant model of TBI, normoxic resuscitation significantly reduced oxidative damage to proteins compared with hyperoxic resuscitation. Neuronal counts showed no benefit from hyperoxic resuscitation. These findings indicate that hyperoxic ventilation in the early stages after severe TBI may exacerbate oxidative damage to proteins.

Published

2008

12. Mitochondrial dysfunction early after traumatic brain injury in immature rats.

Author

Robertson CL, Saraswati M, and Fiskum G

Subjects

Analysis of Variance, Animals, Animals, Newborn, Cells, Cultured, Cerebral Cortex pathology, Cerebral Cortex ultrastructure, Cytochromes c metabolism, Disease Models, Animal, Enzyme-Linked Immunosorbent Assay, Hippocampus pathology, Hippocampus ultrastructure, Ketone Oxidoreductases metabolism, Male, Mitochondria pathology, Oxygen Consumption, Phosphopyruvate Hydratase metabolism, Rats, Rats, Sprague-Dawley, Reactive Oxygen Species metabolism, Time Factors, Brain Injuries pathology, Mitochondria physiology

Abstract

Mitochondria play central roles in acute brain injury; however, little is known about mitochondrial function following traumatic brain injury (TBI) to the immature brain. We hypothesized that TBI would cause mitochondrial dysfunction early (<4 h) after injury. Immature rats underwent controlled cortical impact (CCI) or sham injury to the left cortex, and mitochondria were isolated from both hemispheres at 1 and 4 h after TBI. Rates of phosphorylating (State 3) and resting (State 4) respiration were measured with and without bovine serum albumin. The respiratory control ratio was calculated (State 3/State 4). Rates of mitochondrial H(2)O(2) production, pyruvate dehydrogenase complex enzyme activity, and cytochrome c content were measured. Mitochondrial State 4 rates (ipsilateral/contralateral ratios) were higher after TBI at 1 h, which was reversed with bovine serum albumin. Four hours after TBI, pyruvate dehydrogenase complex activity and cytochrome c content (ipsilateral/contralateral ratios) were lower in TBI mitochondria. These data demonstrate abnormal mitochondrial function early (

Published

2007

13. The potential role of mitochondria in pediatric traumatic brain injury.

Author

Robertson CL, Soane L, Siegel ZT, and Fiskum G

Subjects

Aging physiology, Animals, Brain growth & development, Brain physiopathology, Brain Injuries physiopathology, Calcium Signaling physiology, Child, Energy Metabolism physiology, Humans, Neurotoxins metabolism, Receptors, Glutamate metabolism, Apoptosis physiology, Brain metabolism, Brain Injuries metabolism, Mitochondria metabolism, Oxidative Stress physiology

Abstract

Mitochondria play a central role in cerebral energy metabolism, intracellular calcium homeostasis and reactive oxygen species generation and detoxification. Following traumatic brain injury (TBI), the degree of mitochondrial injury or dysfunction can be an important determinant of cell survival or death. Literature would suggest that brain mitochondria from the developing brain are very different from those from mature animals. Therefore, aspects of developmental differences in the mitochondrial response to TBI can make the immature brain more vulnerable to traumatic injury. This review will focus on four main areas of secondary injury after pediatric TBI, including excitotoxicity, oxidative stress, alterations in energy metabolism and cell death pathways. Specifically, we will describe what is known about developmental differences in mitochondrial function in these areas, in both the normal, physiologic state and the pathologic state after pediatric TBI. The ability to identify and target aspects of mitochondrial dysfunction could lead to novel neuroprotective therapies for infants and children after severe TBI., (Copyright (c) 2006 S. Karger AG, Basel.)

Published

2006

14. Physiologic progesterone reduces mitochondrial dysfunction and hippocampal cell loss after traumatic brain injury in female rats.

Author

Robertson CL, Puskar A, Hoffman GE, Murphy AZ, Saraswati M, and Fiskum G

Subjects

Animals, Brain Injuries metabolism, Cell Count, Cerebral Cortex metabolism, Cerebral Cortex pathology, Drug Implants, Female, Hippocampus metabolism, Ovariectomy, Oxygen Consumption drug effects, Oxygen Consumption physiology, Progesterone administration & dosage, Progesterone pharmacology, Rats, Rats, Sprague-Dawley, Brain Injuries pathology, Hippocampus pathology, Mitochondria physiology, Progesterone physiology

Abstract

Growing literature suggests important sex-based differences in outcome following traumatic brain injury (TBI) in animals and humans. Progesterone has emerged as a key hormone involved in many potential neuroprotective pathways after acute brain injury and may be responsible for some of these differences. Many studies have utilized supraphysiologic levels of post-traumatic progesterone to reverse pathologic processes after TBI, but few studies have focused on the role of endogenous physiologic levels of progesterone in neuroprotection. We hypothesized that progesterone at physiologic serum levels would be neuroprotective in female rats after TBI and that progesterone would reverse early mitochondrial dysfunction seen in this model. Female, Sprague-Dawley rats were ovariectomized and implanted with silastic capsules containing either low or high physiologic range progesterone at 7 days prior to TBI. Control rats received ovariectomy with implants containing no hormone. Rats underwent controlled cortical impact to the left parietotemporal cortex and were evaluated for evidence of early mitochondrial dysfunction (1 h) and delayed hippocampal neuronal injury and cortical tissue loss (7 days) after injury. Progesterone in the low physiologic range reversed the early postinjury alterations seen in mitochondrial respiration and reduced hippocampal neuronal loss in both the CA1 and CA3 subfields. Progesterone in the high physiologic range had a more limited pattern of hippocampal neuronal preservation in the CA3 region only. Neither progesterone dose significantly reduced cortical tissue loss. These findings have implications in understanding the sex-based differences in outcome following acute brain injury.

Published

2006

15. Expression of cellular FLICE inhibitory proteins (cFLIP) in normal and traumatic murine and human cerebral cortex.

Author

Hainsworth AH, Bermpohl D, Webb TE, Darwish R, Fiskum G, Qiu J, McCarthy D, Moskowitz MA, and Whalen MJ

Subjects

Adolescent, Adult, Aged, Animals, Blotting, Western, Brain Chemistry physiology, CASP8 and FADD-Like Apoptosis Regulating Protein, DNA, Complementary biosynthesis, DNA, Complementary genetics, Female, Humans, Immunohistochemistry, In Situ Nick-End Labeling, Indicators and Reagents, Isomerism, Male, Mice, Mice, Inbred C57BL, Middle Aged, RNA, Messenger biosynthesis, Reverse Transcriptase Polymerase Chain Reaction, Brain Injuries metabolism, Cerebral Cortex injuries, Cerebral Cortex metabolism, Intracellular Signaling Peptides and Proteins metabolism

Abstract

Cellular Fas-associated death domain-like interleukin-1-beta converting enzyme (FLICE) inhibitory proteins (cFLIPs) are endogenous caspase homologues that inhibit programmed cell death. We hypothesized that cFLIPs are differentially expressed in response to traumatic brain injury (TBI). cFLIP-alpha and cFLIP-delta mRNA were expressed in normal mouse brain-specifically cFLIP-delta (but not cFLIP-alpha) protein was robustly expressed. After controlled cortical impact (CCI), cFLIP-alpha expression increased initially then decreased to control levels at 12 h, increasing again at 24-72 h (P<0.05). cFLIP-delta expression was decreased in brain homogenates by 12 h after CCI, then increased again at 24 to 72 h (P<0.05). cFLIP-delta immunostaining was markedly reduced in injured cortex, but not hippocampus, at 3 to 72 h after CCI. In cortex, reduced cFLIP-delta staining was found in TUNEL-positive cells, but in hippocampus TUNEL-positive cells expressed cFLIP-delta immunoreactivity. cFLIP-delta was increased in a subset of reactive astrocytes in pericontusional cortex and hippocampus at 48 to 72 h. Low levels of both cFLIP isoforms were detected in human cortical tissue with no TBI, from four patients undergoing brain surgery for epilepsy and <24 h post mortem from three patients without CNS pathologic assessment. In cortical tissue surgically removed <18 h after severe TBI (n=3), cFLIP-alpha expression was increased relative to epilepsy controls (P<0.05) but not relative to post-mortem controls. The data suggest differential spatial and temporal regulation of cFLIP-alpha and cFLIP-delta expression that may influence the magnitude of cell death and further implicate programmed mechanisms of cell death after TBI.

Published

2005

16. Synthes Award for Resident Research on Brain and Craniofacial Injury: normoxic ventilatory resuscitation after controlled cortical impact reduces peroxynitrite-mediated protein nitration in the hippocampus.

Author

Ahn ES, Robertson CL, Vereczki V, Hoffman GE, and Fiskum G

Subjects

Animals, Humans, Male, Rats, Rats, Sprague-Dawley, Awards and Prizes, Brain Injuries therapy, Craniocerebral Trauma therapy, Facial Injuries therapy, Hippocampus metabolism, Internship and Residency, Nitrites antagonists & inhibitors, Oxygen therapeutic use, Peroxynitrous Acid metabolism, Proteins metabolism, Research, Respiration, Artificial methods, Resuscitation methods

Abstract

Resuscitation with 100% ventilatory oxygen is routinely initiated after severe traumatic brain injury (TBI). Despite the objective to improve oxygenation of the injured brain, there are concerns about the increased production of reactive oxygen species (ROS), which can lead to further neuronal damage. 3-nitrotyrosine (3-NT), the product of peroxynitrite-meditated tyrosine residue nitration, has been used as a marker for ROS-induced oxidative damage to proteins. We hypothesized that posttraumatic resuscitation with hyperoxic ventilation with a fraction of inspired oxygen (Fio2, 100%) results in increased ROS-induced damage to proteins compared with resuscitation with normoxic ventilation or room air (Fio2, 21%). Male Sprague-Dawley rats underwent controlled cortical impact (CCI) and were resuscitated with either normoxic or hyperoxic ventilation for 1 hour after injury (n = 5 per group). Sham-operated control groups received 1 hour of normoxic or hyperoxic ventilation without CCI (n = 4-5 per group). Twenty-four hours after injury, rats were perfused with fixative, and hippocampi were evaluated for levels of 3-NT immunostaining. In a second experiment, for a delayed assessment of neuronal survival, another set of rats similarly underwent CCI and normoxic or hyperoxic ventilation for 1 hour (n = 4 per group), and a sham-operated group was used as a control (n = 4). One week after injury, neuronal cell counts and abnormal cell quantification were performed after staining with the neuron-specific NeuN antibody. Quantification of 3-NT staining revealed significantly increased levels in the ipsilateral hippocampus in the hyperoxic CCI group. The normoxic group showed a 51.0% reduction of staining in CA1 when compared with those rats resuscitated with hyperoxia and a 50.8% reduction in CA3 (both P < 0.05). There was no significant difference in staining between the injured normoxic group and the sham-operated groups. In the delayed analysis of neuronal survival, although neuronal counts were reduced in the hippocampus on the injured side in both injured groups, there was no significant difference between hyperoxic and normoxic groups. Similarly, abnormal cell counts were not significantly different between groups.

Published

2005

17. Perinatal brain injury: the role of development in vulnerability.

Author

Giffard RG and Fiskum G

Subjects

Animals, Animals, Newborn, Humans, Infant, Newborn, Aging physiology, Brain Injuries physiopathology, Hypothermia complications

Published

2003

18. Upregulation of the Fas receptor death-inducing signaling complex after traumatic brain injury in mice and humans.

Author

Qiu J, Whalen MJ, Lowenstein P, Fiskum G, Fahy B, Darwish R, Aarabi B, Yuan J, and Moskowitz MA

Subjects

Animals, Brain Injuries pathology, Carrier Proteins metabolism, Caspases metabolism, Cell Death, Cells, Cultured, Cerebral Cortex metabolism, Cerebral Cortex pathology, Disease Models, Animal, Disease Progression, Enzyme Activation, Enzyme Inhibitors pharmacology, Enzyme Precursors metabolism, Fas Ligand Protein, Fas-Associated Death Domain Protein, Genetic Vectors genetics, Genetic Vectors pharmacology, Humans, Macromolecular Substances, Membrane Glycoproteins genetics, Membrane Glycoproteins metabolism, Mice, Neurons drug effects, Neurons metabolism, Neurons pathology, Precipitin Tests, Protein Binding, Proteins metabolism, Receptor-Interacting Protein Serine-Threonine Kinases, Transfection, Adaptor Proteins, Signal Transducing, Brain Injuries metabolism, Signal Transduction, Up-Regulation, fas Receptor metabolism

Abstract

Recent studies have implicated Fas in the pathogenesis of inflammatory, ischemic, and traumatic brain injury (TBI); however, a direct link between Fas activation and caspase-mediated cell death has not been established in injured brain. We detected Fas-Fas ligand binding and assembly of death-inducing signaling complexes (DISCs) [Fas, Fas-associated protein with death domain, and procaspase-8 or procaspase-10; receptor interacting protein (RIP)-RIP-associated interleukin-1beta converting enzyme and CED-3 homolog-1/Ced 3 homologous protein with a death domain-procaspase-2] by immunoprecipitation and immunoblotting within mouse parietal cortex after controlled cortical impact. At the time of DISC assembly, procaspase-8 was cleaved and the cleavage product appeared at 48 hr in terminal deoxynucleotidyl transferase-mediated biotinylated UTP nick end labeling-positive neurons. Cleavage of caspase-8 was accompanied by caspase-3 processing detected at 48 hr by immunohistochemistry, and by caspase-specific cleavage of poly(ADP-ribose) polymerase at 12 hr. Fas pathways were also stimulated by TBI in human brain, because Fas expression plus Fas-procaspase-8 interaction were robust in contused cortical tissue samples surgically removed between 2 and 30 hr after injury. To address whether Fas functions as a death receptor in brain cells, cultured embryonic day 17 cortical neurons were transfected with an adenoviral vector containing the gene encoding Fas ligand. After 48 hr in culture, Fas ligand expression and Fas-procaspase-8 DISC assembly increased, and by 72 hr, cell death was pronounced. Cell death was decreased by approximately 50% after pan-caspase inhibition (Z-Val-ALa-Asp(Ome)-fluoromethylketone). These data suggest that Fas-associated DISCs assemble in neurons overexpressing Fas ligand as well as within mouse and human contused brain after TBI. Therefore, Fas may function as a death receptor after brain injury.

Published

2002

19. Mitochondrial participation in ischemic and traumatic neural cell death.

Author

Fiskum G

Subjects

Animals, Astrocytes metabolism, Brain Injuries pathology, Brain Injuries physiopathology, Brain Ischemia pathology, Brain Ischemia physiopathology, Calcium metabolism, Cytochrome c Group metabolism, Energy Metabolism physiology, Humans, Mitochondria pathology, Nerve Degeneration pathology, Nerve Degeneration physiopathology, Neurons metabolism, Neurotoxins metabolism, Reactive Oxygen Species metabolism, Apoptosis physiology, Brain Injuries metabolism, Brain Ischemia metabolism, Mitochondria metabolism, Nerve Degeneration metabolism

Abstract

Mitochondria play critical roles in cerebral energy metabolism and in the regulation of cellular Ca2+ homeostasis. They are also the primary intracellular source of reactive oxygen species, due to the tremendous number of oxidation-reduction reactions and the massive utilization of O2 that occur there. Metabolic trafficking among cells is also highly dependent upon normal, well-controlled mitochondrial activities. Alterations of any of these functions can cause cell death directly or precipitate death indirectly by compromising the ability of cells to withstand stressful stimuli. Abnormal accumulation of Ca2+ by mitochondria in response to exposure of neurons to excitotoxic levels of excitatory neurotransmitters, for example, glutamate, is a primary mediator of mitochondrial dysfunction and delayed cell death. Excitoxicity, along with inflammatory reactions, mechanical stress, and altered trophic signal transduction, all likely contribute to mitochondrial damage observed during the evolution of traumatic brain injury. The release of apoptogenic proteins from mitochondria into the cytosol serves as a primary mechanism responsible for inducing apoptosis, a form of cell death that contributes significantly to neurologic impairment following neurotrauma. Although several signals for the release of mitochondrial cell death proteins have been identified, the mechanisms by which these signals increase the permeability of the mitochondrial outer membrane to apoptogenic proteins is controversial. Elucidation of the precise biochemical mechanisms responsible for mitochondrial dysfunction during neurotrauma and the roles that mitochondria play in both necrotic and apoptotic cell death should provide new molecular targets for neuroprotective interventions.

Published

2000

20. Mitochondrial dysfunction in mouse trisomy 16 brain

Author

Bambrick, L.L. and Fiskum, G.

Subjects

*PARKINSON'S disease, *NEURODEGENERATION, *BRAIN injuries, *BRAIN research

Abstract

Abstract: Mitochondrial function in the brain of mouse trisomy 16, an animal model of Down syndrome with accelerated neuron death, was studied in isolated cortex mitochondria. Using an oxygen-sensitive Clarke electrode, a selective 16% decrease in respiration was detected with the Complex I substrates malate and glutamate but not with the Complex II substrate succinate. Western blotting revealed a 20% decrease in the 20 kDa subunit of Complex I in Ts16 brain cortex homogenates with no significant decrease in marker proteins for the other complexes of the electron transport chain. Although no differences in H2O2 production or maximal calcium uptake were detected in the Ts16 mitochondria, there was an 18% decrease in pyruvate dehydrogenase levels, a change associated with oxidative stress in ischemia. These results are similar to those found in Parkinson''s disease suggesting some neurodegenerative diseases may have mitochondrial pathology as a common step. [Copyright &y& Elsevier]

Published

2008