Your search keyword '"I, Strauss"' showing total 7 results

1. Polyamine Catabolism Is Enhanced after Traumatic Brain Injury

Author

Robert A. Casero, Francis Huttinger, Kenneth I. Strauss, Kamyar Zahedi, Tracy Murray-Stewart, and Ryan Morrison

Subjects

medicine.medical_specialty, Time Factors, Spermine oxidase, Spermidine, Spermine, Biology, Hippocampus, Functional Laterality, Rats, Sprague-Dawley, chemistry.chemical_compound, Organ Culture Techniques, Acetyltransferases, Internal medicine, medicine, Animals, RNA, Messenger, Brain Chemistry, Cerebral Cortex, Neurons, Oxidoreductases Acting on CH-NH Group Donors, Catabolism, Biogenic Polyamines, Brain, Original Articles, Immunohistochemistry, Rats, Up-Regulation, Disease Models, Animal, Polyamine Catabolism, Metabolism, Endocrinology, chemistry, Biochemistry, Brain Injuries, Putrescine, Polyamine homeostasis, Neurology (clinical), Polyamine, Biomarkers

Abstract

Polyamines spermine and spermidine are highly regulated, ubiquitous aliphatic cations that maintain DNA structure and function as immunomodulators and as antioxidants. Polyamine homeostasis is disrupted after brain injuries, with concomitant generation of toxic metabolites that may contribute to secondary injuries. To test the hypothesis of increased brain polyamine catabolism after traumatic brain injury (TBI), we determined changes in catabolic enzymes and polyamine levels in the rat brain after lateral controlled cortical impact TBI. Spermine oxidase (SMO) catalyzes the degradation of spermine to spermidine, generating H2O2 and aminoaldehydes. Spermidine/spermine-N(1)-acetyltransferase (SSAT) catalyzes acetylation of these polyamines, and both are further oxidized in a reaction that generates putrescine, H2O2, and aminoaldehydes. In a rat cortical impact model of TBI, SSAT mRNA increased subacutely (6-24 h) after TBI in ipsilateral cortex and hippocampus. SMO mRNA levels were elevated late, from 3 to 7 days post-injury. Polyamine catabolism increased as well. Spermine levels were normal at 6 h and decreased slightly at 24 h, but were normal again by 72 h post-injury. Spermidine levels also decreased slightly (6-24 h), then increased by approximately 50% at 72 h post-injury. By contrast, normally low putrescine levels increased up to sixfold (6-72 h) after TBI. Moreover, N-acetylspermidine (but not N-acetylspermine) was detectable (24-72 h) near the site of injury, consistent with increased SSAT activity. None of these changes were seen in the contralateral hemisphere. Immunohistochemical confirmation indicated that SSAT and SMO were expressed throughout the brain. SSAT-immunoreactivity (SSAT-ir) increased in both neuronal and nonneuronal (likely glial) populations ipsilateral to injury. Interestingly, bilateral increases in cortical SSAT-ir neurons occurred at 72 h post-injury, whereas hippocampal changes occurred only ipsilaterally. Prolonged increases in brain polyamine catabolism are the likely cause of loss of homeostasis in this pathway. The potential for simple therapeutic interventions (e.g., polyamine supplementation or inhibition of polyamine oxidation) is an exciting implication of these studies.

Published

2010

2. A Novel Dehydroepiandrosterone Analog Improves Functional Recovery in a Rat Traumatic Brain Injury Model

Author

Kenneth I. Strauss, Laura L. Pashko, Russell W. Cole, Arthur G. Schwartz, Raj K. Narayan, Amir S. Malik, and Woodrow W. Wendling

Subjects

Male, Middle Cerebral Artery, medicine.medical_specialty, Time Factors, Neuroactive steroid, Traumatic brain injury, Morris water navigation task, Prostaglandin, Dehydroepiandrosterone, Dinoprostone, Muscle, Smooth, Vascular, Article, Rats, Sprague-Dawley, chemistry.chemical_compound, Organ Culture Techniques, Fluasterone, Internal medicine, Reflex, medicine, Animals, Hippocampus (mythology), Maze Learning, Cells, Cultured, business.industry, Brain, Recovery of Function, medicine.disease, Glomerular Mesangium, Rats, Isoenzymes, Neuroprotective Agents, Endocrinology, chemistry, Cyclooxygenase 2, Prostaglandin-Endoperoxide Synthases, Brain Injuries, Neurology (clinical), business, Ex vivo

Abstract

The purpose of this study was to investigate the efficacy of a novel steroid, fluasterone (DHEF, a dehydroepiandrosterone (DHEA) analog), at improving functional recovery in a rat model of traumatic brain injury (TBI). The lateral cortical impact model was utilized in two studies of efficacy and therapeutic window. DHEF was given (25 mg/kg, intraperitoneally) at the initial time point and once a day for 2 more days. Study A included four groups: sham injury, vehicle treated (n = 22); injured, vehicle treated (n = 30); injured, pretreated (5-10 min prior to injury, n = 24); and injured, posttreated (initial dose 30 min postinjury, n = 15). Study B (therapeutic window) included five groups: sham injury, vehicle treated (n = 17); injured, vehicle treated (n = 26); and three posttreatment groups: initial dose at 30 min (n = 18), 2 h (n = 23), or 12 h (n = 16) postinjury. Three criteria were used to grade functional recovery. In study A, DHEF improved beam walk performance both with pretreatment (79%) and 30-min posttreatment group (54%; p0.01, Dunnett vs. injured vehicle). In study B, the 12-h posttreatment group showed a 97% improvement in beam walk performance (p0.01, Dunnett). The 30-min and 12-h posttreatment groups showed a decreased incidence of falls from the beam, which reached statistical significance (p0.05, Dunnett). Tests of memory (Morris water maze) and neurological reflexes both revealed significant improvements in all DHEF treatment groups. In cultured rat mesangial cells, DHEF (and DHEA) potently inhibited interleukin-1beta-induced cyclooxygenase-2 (COX2) mRNA and prostaglandin (PGE2) production. In contrast, DHEF treatment did not alter injury-induced COX2 mRNA levels in the cortex or hippocampus. However, DHEF (and DHEA) relaxed ex vivo bovine middle cerebral artery preparations by about 30%, with an IC(50) approximately 40 microM. This was a direct effect on the vascular smooth muscle, independent of the endothelial cell layer. Fluasterone (DHEF) treatments improved functional recovery in a rat TBI model. Possible mechanisms of action for this novel DHEA analog are discussed. These findings suggest an exciting potential use for this agent in the clinical treatment of traumatic brain injury.

Published

2003

3. Clinical Trials in Head Injury

Author

Gad Riesenfeld, Nancy Temkin, Edward D. Hall, Lorraine Yurkewicz, William M. Coplin, Beth Ansell, Alex Baethmann, Nachshon Knoller, Donald W. Marion, Patrick M. Kochanek, Tracy K. McIntosh, Michael D. Walker, Lawrence F. Marshall, Noel Mohberg, Andrew I R Maas, Graham M. Teasdale, John Whyte, Lawrence H. Pitts, Jack Jallo, Peter Quinn, Raj K. Narayan, Guy L. Clifton, Sean M. Grady, Kenneth I. Strauss, Charles E. Wade, Claudia S. Robertson, Ronald F. Tuma, Robert G. Grossman, A. Byron Young, Michael B. Bracken, J. Paul Muizelaar, Anat Biegon, Jack E. Wilberger, W. Dalton Dietrich, Sung C. Choi, Michael Weinrich, Jeannine Majde, Charles F. Contant, Jamshid Ghajar, David A. Hovda, William Heetderks, M. Ross Bullock, Russell L. Katz, A Marmarou, Mary Ellen Michel, and Emmy Miller

Subjects

Clinical Trials as Topic, medicine.medical_specialty, education.field_of_study, business.industry, Public health, Head injury, Population, medicine.disease, Article, Surgery, law.invention, Clinical trial, Penetrating head injury, Randomized controlled trial, Informed consent, law, Brain Injuries, Multicenter trial, medicine, Humans, Neurology (clinical), Intensive care medicine, education, business

Abstract

Traumatic brain injury (TBI) remains a major public health problem globally. In the United States the incidence of closed head injuries admitted to hospitals is conservatively estimated to be 200 per 100,000 population, and the incidence of penetrating head injury is estimated to be 12 per 100,000, the highest of any developed country in the world. This yields an approximate number of 500,000 new cases each year, a sizeable proportion of which demonstrate significant long-term disabilities. Unfortunately, there is a paucity of proven therapies for this disease. For a variety of reasons, clinical trials for this condition have been difficult to design and perform. Despite promising pre-clinical data, most of the trials that have been performed in recent years have failed to demonstrate any significant improvement in outcomes. The reasons for these failures have not always been apparent and any insights gained were not always shared. It was therefore feared that we were running the risk of repeating our mistakes. Recognizing the importance of TBI, the National Institute of Neurological Disorders and Stroke (NINDS) sponsored a workshop that brought together experts from clinical, research, and pharmaceutical backgrounds. This workshop proved to be very informative and yielded many insights into previous and future TBI trials. This paper is an attempt to summarize the key points made at the workshop. It is hoped that these lessons will enhance the planning and design of future efforts in this important field of research.

Published

2002

4. Prolonged Cyclooxygenase-2 Induction in Neurons and Glia Following Traumatic Brain Injury in the Rat

Author

Ramesh Raghupathi, Kenneth I. Strauss, Raj K. Narayan, Samir Mehta, Mary F. Barbe, and Renée M. Marshall

Subjects

Male, medicine.medical_specialty, Traumatic brain injury, Hippocampus, macromolecular substances, Hippocampal formation, Biology, Article, Rats, Sprague-Dawley, Piriform cortex, Cortex (anatomy), Internal medicine, medicine, Animals, RNA, Messenger, Cerebral Cortex, Neurons, food and beverages, medicine.disease, Granule cell, Rats, Isoenzymes, Endocrinology, medicine.anatomical_structure, Cyclooxygenase 2, Prostaglandin-Endoperoxide Synthases, Cerebral cortex, Brain Injuries, Enzyme Induction, Neurology (clinical), Pyramidal cell, Neuroglia, Neuroscience

Abstract

Cyclooxygenase-2 (COX2) is a primary inflammatory mediator that converts arachidonic acid into precursors of vasoactive prostaglandins, producing reactive oxygen species in the process. Under normal conditions COX2 is not detectable, except at low abundance in the brain. This study demonstrates a distinctive pattern of COX2 increases in the brain over time following traumatic brain injury (TBI). Quantitative lysate ribonuclease protection assays indicate acute and sustained increases in COX2 mRNA in two rat models of TBI. In the lateral fluid percussion model, COX2 mRNA is significantly elevated (>twofold, p < 0.05, Dunnett) at 1 day postinjury in the injured cortex and bilaterally in the hippocampus, compared to sham-injured controls. In the lateral cortical impact model (LCI), COX2 mRNA peaks around 6 h postinjury in the ipsilateral cerebral cortex (fivefold induction, p < 0.05, Dunnett) and in the ipsilateral and contralateral hippocampus (two- and six-fold induction, respectively, p < 0.05, Dunnett). Increases are sustained out to 3 days postinjury in the injured cortex in both models. Further analyses use the LCI model to evaluate COX2 induction. Immunoblot analyses confirm increased levels of COX2 protein in the cortex and hippocampus. Profound increases in COX2 protein are observed in the cortex at 1-3 days, that return to sham levels by 7 days postinjury (p < 0.05, Dunnett). The cellular pattern of COX2 induction following TBI has been characterized using immunohistochemistry. COX2-immunoreactivity (-ir) rises acutely (cell numbers and intensity) and remains elevated for several days following TBI. Increases in COX2-ir colocalize with neurons (MAP2-ir) and glia (GFAP-ir). Increases in COX2-ir are observed in cerebral cortex and hippocampus, ipsilateral and contralateral to injury as early as 2 h postinjury. Neurons in the ipsilateral parietal, perirhinal and piriform cortex become intensely COX2-ir from 2 h to at least 3 days postinjury. In agreement with the mRNA and immunoblot results, COX2-ir appears greatest in the contralateral hippocampus. Hippocampal COX2-ir progresses from the pyramidal cell layer of the CA1 and CA2 region at 2 h, to the CA3 pyramidal cells and dentate polymorphic and granule cell layers by 24 h postinjury. These increases are distinct from those observed following inflammatory challenge, and correspond to brain areas previously identified with the neurological and cognitive deficits associated with TBI. While COX2 induction following TBI may result in selective beneficial responses, chronic COX2 production may contribute to free radical mediated cellular damage, vascular dysfunction, and alterations in cellular metabolism. These may cause secondary injuries to the brain that promote neuropathology and worsen behavioral outcome.

Published

2000

5. Correction

Author

Kenneth I. Strauss

Subjects

Neurology (clinical)

Published

2000

6. A Novel Dehydroepiandrosterone Analog Improves Functional Recovery in a Rat Traumatic Brain Injury Model.

Author

Amir S. Malik, Raj K. Narayan, Woodrow W. Wendling, Russell W. Cole, Laura L. Pashko, Arthur G. Schwartz, and Kenneth I. Strauss

Published

2003

7. Temporal Alterations in Cellular Bax:Bcl-2 Ratio following Traumatic Brain Injury in the Rat.

Author

Ramesh Raghupathi, Kenneth I. Strauss, Chen Zhang, Stanislaw Krajewski, John C. Reed, and Tracy K. McIntosh

Published

2003