Your search keyword '"Povlishock, John T."' showing total 264 results

251. The future of combinational therapy in the treatment of traumatic brain injury.

Author

Povlishock JT

Subjects

Biomedical Research standards, Biomedical Research trends, Drug Evaluation, Preclinical methods, Drug Evaluation, Preclinical standards, Drug Therapy, Combination, Forecasting, Humans, Outcome Assessment, Health Care methods, Outcome Assessment, Health Care standards, Research standards, Research trends, Treatment Outcome, Biomedical Research methods, Brain Injuries physiopathology, Brain Injuries therapy

Published

2009

252. Biochemical, structural, and biomarker evidence for calpain-mediated cytoskeletal change after diffuse brain injury uncomplicated by contusion.

Author

McGinn MJ, Kelley BJ, Akinyi L, Oli MW, Liu MC, Hayes RL, Wang KK, and Povlishock JT

Subjects

Animals, Blotting, Western, Cytoskeleton metabolism, Cytoskeleton pathology, Enzyme-Linked Immunosorbent Assay, Immunohistochemistry, Male, Microscopy, Electron, Transmission, Rats, Rats, Sprague-Dawley, Spectrin cerebrospinal fluid, Spectrin metabolism, Biomarkers cerebrospinal fluid, Brain Injuries enzymology, Brain Injuries pathology, Calpain metabolism

Abstract

Calpain-mediated degradation of the cytoskeletal protein alpha-II-spectrin has been implicated in the pathobiology of experimental and human traumatic brain injury (TBI). Spectrin proteolysis after diffuse/widespread TBI uncomplicated by either subtle or overt contusion and/or mass lesions, (i.e. mild to moderate TBI), has not been previously evaluated. To determine the spatiotemporal pattern and cellular localization of calpain-mediated spectrin proteolysis after diffuse/widespread TBI and the extent to which parenchymal changes in calpain-mediated spectrin proteolysis are reflected in the cerebrospinal fluid, adult rats were subjected to a moderate midline fluid percussion injury and allowed to survive for 3 hours to 7 days postinjury. Light and electron microscopic immunocytochemical and Western blot analyses were performed to identify the calpain-specific 145-kDa breakdown product of alpha-II-spectrin (SBDP145). After diffuse TBI, enhanced levels of SBDP145 immunoreactivity were observed in the neocortex, subcortical white matter, thalamus, and hippocampus, peaking between 24 and 48 hours postinjury. Immunoreactivity was localized almost exclusively to damaged axons and axonal terminal debris. Heightened levels of SBDP145 were also observed in the cerebrospinal fluid at 24 hours postinjury. These results confirm the widespread occurrence of calpain-mediated spectrin proteolysis after diffuse TBI without contusion and support the potential utility of SBDPs as biomarkers of a diffusely injured brain.

Published

2009

253. Journal of neurotrauma. Editorial.

Author

Povlishock JT

Subjects

Biomedical Research trends, Brain Injuries physiopathology, Disability Evaluation, Humans, Outcome Assessment, Health Care standards, Quality of Life psychology, Registries standards, Trauma Centers standards, Brain Injuries therapy, Neurosciences trends

Published

2008

254. The classification of traumatic brain injury (TBI) for targeted therapies.

Author

Povlishock JT

Subjects

Animals, Brain Injuries diagnosis, Clinical Trials as Topic standards, Congresses as Topic, Diagnostic Imaging standards, Diagnostic Imaging trends, Disease Models, Animal, Endpoint Determination standards, Glasgow Coma Scale standards, Humans, Outcome Assessment, Health Care standards, Prognosis, Brain Injuries classification, Brain Injuries therapy, Disability Evaluation, Trauma Severity Indices

Published

2008

255. Guidelines for the management of severe traumatic brain injury. Editor's Commentary.

Author

Bullock MR and Povlishock JT

Subjects

Humans, Brain Injuries therapy, Practice Guidelines as Topic

Published

2007

256. Cellular and subcellular change evoked by diffuse traumatic brain injury: a complex web of change extending far beyond focal damage.

Author

Farkas O and Povlishock JT

Subjects

Animals, Axons metabolism, Axons pathology, Brain Injuries metabolism, Free Radicals metabolism, Humans, Neurons metabolism, Subcellular Fractions metabolism, Brain Injuries pathology, Neurons pathology, Subcellular Fractions pathology

Abstract

Until recently, our understanding of the cellular and subcellular changes evoked by diffuse traumatic brain injury has been framed in the context of primary focal injury. In this regard, the ensuing cell death cascades were linked to contusional-mediated changes associated with frank hemorrhage and ischemia, and these were assumed to contribute to the observed apoptotic and necrotic neuronal death. Little consideration was given to the potential that other non-contusional cell death cascades could have been triggered by the diffuse mechanical forces of injury. While the importance of these classical, contusion-related apoptotic and necrotic cell death cascades cannot be discounted with diffuse injury, more recent information suggests that the mechanical force of injury itself can diffusely porate the neuronal plasmalemma and its axolemmal membranes, evoking other forms of cellular response that can contribute to cell injury or death. In this regard, the duration of the membrane alteration appears to be a dependent factor, with enduring membrane change, potentially leading to irreversible damage, whereas more transient membrane perturbation can be followed by cell membrane resealing associated with recovery and/or adaptive change. With more enduring mechanical membrane perturbation, it appears that some of the traditional death cascades involving the activation of cysteine proteases are at work. Equally important, non-traditional pathways involving the lysosomal dependent release of hydrolytic enzymes may also be players in the ensuing neuronal death. These mechanically related factors that directly impact upon the neuronal somata may also be influenced by concomitant and/or secondary axotomy-mediated responses. This axonal injury, although once thought to involve a singular intraaxonal response to injury, is now known to be more complex, reflecting differential responses to injuries of varying severity. Moreover, it now appears that fiber size and type may also influence the axon's reaction to injury. In sum, this review explicates the complexity of the cellular and subcellular responses evoked by diffuse traumatic brain injury in both the neuronal somata and its axonal appendages. This review further illustrates that our once simplistic views framed by evidence based upon contusional and/or ischemic change do not fully explain the complex repertoire of change evoked by diffuse traumatic brain injury.

Published

2007

257. Perivascular nerve damage in the cerebral circulation following traumatic brain injury.

Author

Ueda Y, Walker SA, and Povlishock JT

Subjects

Animals, Brain metabolism, Brain pathology, Brain Injuries metabolism, Cerebral Arteries metabolism, Immunohistochemistry, Male, Proteins metabolism, Rats, Rats, Sprague-Dawley, Serotonin metabolism, Brain blood supply, Brain Injuries pathology, Cerebral Arteries innervation, Cerebral Arteries pathology, Cerebrovascular Circulation physiology

Abstract

Traumatic brain injury (TBI) causes cerebral vascular dysfunction. Most have assumed that it was the result of endothelial and/or smooth muscle alteration. No consideration, however, has been given to the possibility that the forces of injury may also damage the perivascular nerve network, thereby contributing to the observed abnormalities. To test this premise, we subjected rats to impact acceleration. At 6 h, 24 h and 7 days post-TBI, cerebral basal arteries were removed and processed with antibody targeting protein gene product 9.5 (PGP-9.5), with parallel assessments of 5-hydroxytryptamine (5-HT) accumulation in the perivascular nerves. Additionally, Fluoro-Jade was also used as a marker of axonal degeneration. The perivascular nerve network revealed no abnormality in sham animals. However, by 6 h post injury, Fluoro-Jade reactivity appeared in the perivascular regions, with the number of fibers increasing with time. By 24 h post injury, a significant reduction in the perivascular 5-HT accumulation occurred, together with a reduction in PGP-9.5 fiber staining. At 7 days, a recovery of the PGP-9.5 immunoreactivity occurred, however, it did not reach a control-like distribution. These studies suggest that neurogenic damage occurs following TBI and may be a contributor to some of the associated vascular abnormalities.

Published

2006

258. Postinjury administration of pituitary adenylate cyclase activating polypeptide (PACAP) attenuates traumatically induced axonal injury in rats.

Author

Tamás A, Zsombok A, Farkas O, Reglödi D, Pál J, Büki A, Lengvári I, Povlishock JT, and Dóczi T

Subjects

Amyloid beta-Protein Precursor drug effects, Amyloid beta-Protein Precursor metabolism, Animals, Axons pathology, Brain Injuries metabolism, Brain Injuries pathology, Image Processing, Computer-Assisted, Immunohistochemistry, Injections, Intraventricular, Male, Pyramidal Tracts drug effects, Pyramidal Tracts metabolism, Pyramidal Tracts pathology, Rats, Time Factors, Axons drug effects, Brain Injuries drug therapy, Neurotransmitter Agents administration & dosage, Pituitary Adenylate Cyclase-Activating Polypeptide administration & dosage

Abstract

Pituitary adenylate cyclase activating polypeptide (PACAP) has several different actions in the nervous system. Numerous studies have shown its neuroprotective effects both in vitro and in vivo. Previously, it has been demonstrated that PACAP reduces brain damage in rat models of global and focal cerebral ischemia. Based on the protective effects of PACAP in cerebral ischemia and the presence of common pathogenic mechanisms in cerebral ischemia and traumatic brain injury (TBI), the aim of the present study was to investigate the possible protective effect of PACAP administered 30 min or 1 h postinjury in a rat model of diffuse axonal injury. Adult Wistar male rats were subjected to impact acceleration, and PACAP was administered intracerebroventricularly 30 min (n = 4), and 1 h after the injury (n = 5). Control animals received the same volume of vehicle at both time-points (n = 5). Two hours after the injury, brains were processed for immunohistochemical localization of damaged axonal profiles displaying either beta-amyloid precursor protein (beta-APP) or RMO-14 immunoreactivity, both considered markers of specific features of traumatic axonal injury. Our results show that treatment with PACAP (100 microg) 30 min or 1 h after the induction of TBI resulted in a significant reduction of the density of beta-APP-immunopositive axon profiles in the corticospinal tract (CSpT). There was no significant difference between the density of beta-APP-immunopositive axons in the medial longitudinal fascicle (MLF). PACAP treatment did not result in significantly different number of RMO-14-immunopositive axonal profiles in either brain areas 2 hours post-injury compared to normal animals. While the results of this study highlighted the complexity of the pathogenesis and manifestation of diffuse axonal injury, they also indicate that PACAP should be considered a potential therapeutic agent in TBI.

Published

2006

259. Administration of the immunophilin ligand FK506 differentially attenuates neurofilament compaction and impaired axonal transport in injured axons following diffuse traumatic brain injury.

Author

Marmarou CR and Povlishock JT

Subjects

Amyloid beta-Protein Precursor metabolism, Animals, Diffuse Axonal Injury etiology, Diffuse Axonal Injury pathology, Disease Models, Animal, Immunohistochemistry methods, Male, Neurologic Examination, Pyramidal Tracts metabolism, Pyramidal Tracts pathology, Random Allocation, Rats, Rats, Sprague-Dawley, Time Factors, Axonal Transport drug effects, Brain Injuries complications, Diffuse Axonal Injury prevention & control, Immunosuppressive Agents administration & dosage, Neurofilament Proteins metabolism, Tacrolimus administration & dosage

Abstract

Traumatic axonal injury (TAI) following traumatic brain injury (TBI) remains a clinical problem for which no effective treatment exists. TAI was thought to involve intraaxonal changes that universally led to impaired axonal transport (IAT), disconnection and axonal bulb formation. However, recent, immunocytochemical studies employing antibodies to amyloid precursor protein (APP), a marker of IAT and antibodies to neurofilament compaction (NFC), RM014, demonstrated that NFC typically occurs independent of IAT, indicating the existence of different populations of damaged axons. FK506 administration has been shown to attenuate IAT. However, in light of the above, the ability of FK506 to attenuate axonal damage demonstrating NFC requires evaluation. The current study explored the potential of FK506 to attenuate both populations of damaged axons. Rats were administered FK506 (3 mg/kg) or vehicle 30 min preinjury. Three hours post-TBI, tissue was prepared for the visualization of TAI using antibodies targeting IAT (APP) or NFC (RMO14) or a combined labeling strategy. Confirming previous reports, FK506 treatment reduced the number of axons demonstrating IAT in the CSpT, from 411 +/- 54.70 to 91.00 +/- 33.87 (P

Published

2006

260. Myelinated and unmyelinated axons of the corpus callosum differ in vulnerability and functional recovery following traumatic brain injury.

Author

Reeves TM, Phillips LL, and Povlishock JT

Subjects

Action Potentials physiology, Animals, Brain Injuries physiopathology, Corpus Callosum physiology, Corpus Callosum ultrastructure, Electrophysiology, Male, Microscopy, Electron, Transmission, Nerve Fibers, Myelinated physiology, Nerve Fibers, Myelinated ultrastructure, Nerve Fibers, Unmyelinated physiology, Nerve Fibers, Unmyelinated ultrastructure, Organ Culture Techniques, Rats, Brain Injuries pathology, Corpus Callosum pathology, Nerve Fibers, Myelinated pathology, Nerve Fibers, Unmyelinated pathology, Nerve Regeneration physiology

Abstract

Traumatic axonal injury (TAI), a common feature of traumatic brain injury, is associated with postinjury morbidity and mortality. However, TAI is not uniformly expressed in all axonal populations, with fiber caliber and anatomical location influencing specific TAI pathology. To study differential axonal vulnerability to brain injury, axonal excitability and integrity were assessed in the corpus callosum following fluid percussion injury in the rat. In brain slice electrophysiological recordings, compound action potentials (CAPs) were evoked in the corpus callosum, and injury effects were quantified separately for CAP waveform components generated by myelinated axons (N1 wave) and by unmyelinated axons (N2 wave). Ultrastructural analyses were also conducted of TAI-induced morphological changes in these axonal populations. The two populations of axons differed in response to brain injury, and in their functional recovery, during the first week postinjury. Amplitudes of N1 and N2 were significantly depressed at 3 h, 1 day, and 3 days survival. N1 amplitudes exhibited a recovery to control levels by 7 days postinjury. In contrast, N2 amplitudes were persistently suppressed through 7 days postinjury. Strength-duration properties of evoked CAPs further differentiated the effects of injury in these axonal populations, with N2 exhibiting an elevated strength-duration time constant postinjury. Ultrastructural observations revealed degeneration of myelinated axons consistent with diffuse injury sequelae, as well as previously undocumented pathology within the unmyelinated fiber population. Collectively, these findings demonstrate differential vulnerabilities of axons to brain injury and suggest that damage to unmyelinated fibers may play a significant role in morbidity associated with brain injury.

Published

2005

261. Update of neuropathology and neurological recovery after traumatic brain injury.

Author

Povlishock JT and Katz DI

Subjects

Brain Injuries metabolism, Cell Death, Diffuse Axonal Injury diagnosis, Humans, Nerve Degeneration pathology, Neurons pathology, Terminology as Topic, Brain Injuries pathology, Brain Injuries physiopathology, Recovery of Function physiology

Abstract

This review focuses on the potential for traumatic brain injury to evoke both focal and diffuse changes within the brain parenchyma, while considering the cellular constituents involved and the subcellular perturbations that contribute to their dysfunction. New insight is provided on the pathobiology of traumatically induced cell body injury and diffuse axonal damage. The consequences of axonal damage in terms of subsequent deafferentation and any potential retrograde cell death and atrophy are addressed. The regional and global metabolic sequelae are also considered. This detailed presentation of the neuropathological consequences of traumatic brain injury is used to set the stage for better appreciating the neurological recovery occurring after traumatic injury. Although the pathological and clinical effects of focal and diffuse damage are usually intermingled, the different clinical manifestations of recovery patterns associated with focal versus diffuse injuries are presented. The recognizable patterns of recovery, involving unconsciousness, posttraumatic confusion/amnesia, and postconfusional restoration, that typically occur across the full spectrum of diffuse injury are described, recognizing that the patient's long-term recovery may involve more idiosyncratic combinations of dysfunction. The review highlights the relationship of focal lesions to localizing syndromes that may be embedded in the evolving natural history of diffuse pathology. It is noted that injuries with primarily focal pathology do not necessarily follow a comparable pattern of recovery with distinct phases. Potential linkages of these recovery patterns to the known neuropathological sequelae of injury and various reparative mechanisms are considered and it is proposed that potential biological markers and newer imaging technologies will better define these linkages.

Published

2005

262. Uncomplicated rapid posthypothermic rewarming alters cerebrovascular responsiveness.

Author

Ueda Y, Suehiro E, Wei EP, Kontos HA, and Povlishock JT

Subjects

Acetylcholine pharmacology, Animals, Carbon Dioxide pharmacology, Cerebrovascular Circulation drug effects, Disease Models, Animal, Hypercapnia physiopathology, Male, Nitroprusside pharmacology, Pinacidil pharmacology, Rats, Rats, Sprague-Dawley, Time Factors, Vascular Patency drug effects, Vascular Patency physiology, Vasodilation drug effects, Vasodilation physiology, Vasodilator Agents pharmacology, Vasomotor System drug effects, Cerebrovascular Circulation physiology, Hypothermia, Induced methods, Rewarming adverse effects, Rewarming methods, Vasomotor System physiology

Abstract

Background and Purpose: Recently, we focused on the cerebrovascular protective effects of moderate hypothermia after traumatic brain injury, noting that the efficacy of posttraumatic hypothermia is related to the rate of posthypothermic rewarming. In the current communication, we revisit the use of hypothermia with varying degrees of rewarming to ascertain whether, in the normal cerebral vasculature, varying rates of rewarming can differentially affect cerebrovascular responsiveness., Methods: Pentobarbital-anesthetized rats equipped with a cranial window were randomized to 3 groups. In 1 group, a 1-hour period of hypothermia (32 degrees C) followed by slow rewarming (over 90 minutes) was used. In the remaining 2 groups, either a 1- or 2-hour period of hypothermia was followed by rapid rewarming (within 30 minutes). Vasoreactivity to hypercapnia and acetylcholine was assessed before, during, and after hypothermia. Additionally, the vascular responses to sodium nitroprusside (SNP) and pinacidil, a K(ATP) channel opener, were also examined., Results: Hypothermia itself generated modest vasodilation and reduced vasoreactivity to all utilized agents. The slow rewarming group showed restoration of normal vascular responsivity. In contrast, hypothermia followed by rapid rewarming was associated with continued impaired responsiveness to acetylcholine and arterial hypercapnia. These abnormalities persisted even with the use of more prolonged (2-hour) hypothermia. Furthermore, posthypothermic rapid rewarming impaired the dilator responses of SNP and pinacidil., Conclusions: Posthypothermic rapid rewarming caused cerebral vascular abnormalities, including a diminished response to acetylcholine, hypercapnia, pinacidil, and SNP. Our data with acetylcholine and SNP suggest that rapid rewarming most likely causes abnormality at both the vascular smooth muscle and endothelial levels.

Published

2004

263. The effects of combined fluid percussion traumatic brain injury and unilateral entorhinal deafferentation on the juvenile rat brain.

Author

Prins ML, Povlishock JT, and Phillips LL

Subjects

Animals, Brain pathology, Brain physiopathology, Brain Injuries physiopathology, Disease Models, Animal, Entorhinal Cortex physiopathology, Entorhinal Cortex ultrastructure, Functional Laterality, Hippocampus pathology, Immunohistochemistry, Male, Neuronal Plasticity, Rats, Rats, Sprague-Dawley, Synaptophysin analysis, Brain Injuries pathology, Entorhinal Cortex pathology, Maze Learning physiology

Abstract

The current study was designed to address the effects of traumatic brain injury (TBI) on plasticity and reorganization in the juvenile brain. Given that two of the major pathological sequelae of TBI involve a generalized neuroexcitation insult and diffuse axonal injury, we have employed models of these pathologies, delivered either independently or in combination, to examine their effects on injury-induced synaptic reorganization of the dentate gyrus in the developing rat. Postnatal day 28 rats received either sham, central fluid percussion traumatic brain injury (TBI), unilateral entorhinal cortical lesion (UEC), or TBI+UEC (TUEC) injury. Cognitive performance was assessed in the Morris water maze (MWM) between 11 and 15 days post-injury and the brains were processed for synaptophysin immunohistochemistry and routine electron microscopy. The MWM results revealed that TBI or UEC lesions delivered independently do not produce significant morbidity in P28 rats. However, when these injuries are combined, they reveal significant deficits in the MWM, accompanied by measurable changes in the distribution of presynaptic synaptophysin immunoreactivity over the deafferented dentate molecular layer. These observations are further supported by qualitative ultrastructural alterations in synaptic architecture in the same subregions of the dentate neuropil. The present findings show that the resilience of the immature brain following TBI is reduced when neuroexcitatory insult is combined with deafferentation. Moreover, when deafferented tissue is assessed morphologically, evidence exists for aberrant plasticity and abnormal synaptic reorganization in the juvenile brain.

Published

2003

264. Caspase-3-mediated cleavage of amyloid precursor protein and formation of amyloid Beta peptide in traumatic axonal injury.

Author

Stone JR, Okonkwo DO, Singleton RH, Mutlu LK, Helm GA, and Povlishock JT

Subjects

Alzheimer Disease metabolism, Alzheimer Disease pathology, Amyloid beta-Peptides analysis, Amyloid beta-Peptides immunology, Amyloid beta-Protein Precursor analysis, Amyloid beta-Protein Precursor immunology, Animals, Antibody Specificity, Apoptosis physiology, Axons pathology, Brain Injuries pathology, Caspase 3, Fluorescent Antibody Technique, Male, Rats, Rats, Sprague-Dawley, Amyloid beta-Peptides metabolism, Amyloid beta-Protein Precursor metabolism, Axons enzymology, Brain Injuries metabolism, Caspases metabolism

Abstract

Immunohistochemical studies demonstrate accumulation of the beta-amyloid precursor protein (APP) within injured axons following traumatic brain injury (TBI). Despite such descriptions, little is known about the ultimate fate of accumulating APP at sites of traumatic axonal injury (TAI). Recently, caspase-3-mediated cleavage of APP and subsequent Abeta deposition was linked to apoptotic neuronal death pathways in hippocampal neurons following ischemic and excitotoxic brain injury. Given that (1) APP is known to accumulate within traumatically injured axons, (2) caspase-3 activation has been demonstrated in traumatic axonal injury (TAI), and (3) recent studies have identified a caspase-3 cleavage site within APP, we initiated the current investigation to determine whether caspase-3-mediated cleavage of APP occurs in TAI. We further assessed whether these events were found in relation to Abeta peptide formation. To this end, we employed antibodies targeting APP, the caspase-3-mediated breakdown product of APP proteolysis, and the Abeta peptide. Rats were subjected to impact acceleration TBI (6 h to 10 days survival), and their brains were processed for single-label bright field and multiple double-label immunofluorescent paradigms using the above antibodies. By 12 h postinjury, caspase-3-mediated APP proteolysis (CMAP) was demonstrated within the medial lemniscus (ML) and medial longitudinal fasciculus (MLF) in axons undergoing TAI, identified by their concomitant APP accumulation. Immunoreactivity for CMAP persisted up to 48 h postinjury in the ML and MLF, but was notably reduced by 10 days following injury. Further, CMAP was colocalized with Abeta formation in foci of TAI. The current study demonstrates that caspase-3 cleavage of APP occurs in TAI and is associated with formation of Abeta peptide. These findings are of interest given recent epidemiological studies supporting an association between TBI and later risk for AD development.

Published

2002