Evolution of post-traumatic neurodegeneration after controlled cortical impact traumatic brain injury in mice and rats as assessed by the de Olmos silver and fluorojade staining methods.
about
Therapeutic window analysis of the neuroprotective effects of cyclosporine A after traumatic brain injuryNear-infrared photonic energy penetration: can infrared phototherapy effectively reach the human brain?Bridge between neuroimmunity and traumatic brain injuryInsights into the metabolic response to traumatic brain injury as revealed by (13)C NMR spectroscopyInvolvement of aberrant cyclin-dependent kinase 5/p25 activity in experimental traumatic brain injuryNociceptive neuropeptide increases and periorbital allodynia in a model of traumatic brain injury.Minocycline synergizes with N-acetylcysteine and improves cognition and memory following traumatic brain injury in ratsThioredoxin-Mimetic-Peptides Protect Cognitive Function after Mild Traumatic Brain Injury (mTBI)Assessing neuro-systemic & behavioral components in the pathophysiology of blast-related brain injury.Reorganization of motor cortex after controlled cortical impact in rats and implications for functional recovery.Neurodegeneration in the somatosensory cortex after experimental diffuse brain injuryA novel mouse model of penetrating brain injuryEffects of genetic deficiency of cyclooxygenase-1 or cyclooxygenase-2 on functional and histological outcomes following traumatic brain injury in mice.Age-dependent regional mechanical properties of the rat hippocampus and cortex.Magnetic resonance imaging assessment of macrophage accumulation in mouse brain after experimental traumatic brain injuryConditional overexpression of insulin-like growth factor-1 enhances hippocampal neurogenesis and restores immature neuron dendritic processes after traumatic brain injuryExperimental traumatic brain injuryGenetic deletion and pharmacological inhibition of Nogo-66 receptor impairs cognitive outcome after traumatic brain injury in mice.Adenosine A1 receptor activation as a brake on the microglial response after experimental traumatic brain injury in miceA pharmacological analysis of the neuroprotective efficacy of the brain- and cell-permeable calpain inhibitor MDL-28170 in the mouse controlled cortical impact traumatic brain injury model.Reversible behavioral deficits in rats during a cycle of demyelination-remyelination of the fimbria.Heightening of the stress response during the first weeks after a mild traumatic brain injury.Neuroprotection by acetyl-L-carnitine after traumatic injury to the immature rat brain.Granulocyte-macrophage colony stimulating factor exerts protective and immunomodulatory effects in cortical traumaImipramine treatment improves cognitive outcome associated with enhanced hippocampal neurogenesis after traumatic brain injury in miceCognitive impairments accompanying rodent mild traumatic brain injury involve p53-dependent neuronal cell death and are ameliorated by the tetrahydrobenzothiazole PFT-α.Rate of neurodegeneration in the mouse controlled cortical impact model is influenced by impactor tip shape: implications for mechanistic and therapeutic studies.Preservation of the blood brain barrier and cortical neuronal tissue by liraglutide, a long acting glucagon-like-1 analogue, after experimental traumatic brain injury.Animal modelling of traumatic brain injury in preclinical drug development: where do we go from here?Mitochondrial bioenergetic alterations after focal traumatic brain injury in the immature brain.Decompressive craniectomy reduces white matter injury after controlled cortical impact in mice.Lithium ameliorates neurodegeneration, suppresses neuroinflammation, and improves behavioral performance in a mouse model of traumatic brain injury.Mild hyperthermia worsens the neuropathological damage associated with mild traumatic brain injury in ratsSubstantia nigra vulnerability after a single moderate diffuse brain injury in the rat.Targeted gene inactivation of calpain-1 suppresses cortical degeneration due to traumatic brain injury and neuronal apoptosis induced by oxidative stress.Effects of acute restraint-induced stress on glucocorticoid receptors and brain-derived neurotrophic factor after mild traumatic brain injuryImatinib treatment reduces brain injury in a murine model of traumatic brain injurySevere brief pressure-controlled hemorrhagic shock after traumatic brain injury exacerbates functional deficits and long-term neuropathological damage in miceLong-Term Consequences of Traumatic Brain Injury: Current Status of Potential Mechanisms of Injury and Neurological OutcomesRelationship of nitric oxide synthase induction to peroxynitrite-mediated oxidative damage during the first week after experimental traumatic brain injury
P2860
Q24626804-CBB1129D-7A8C-4A71-8203-7E9075FEE16BQ26783174-A008A9DD-B358-4DEE-8B28-568EA29E931FQ26827612-C4CAE5D5-689E-4423-BC63-AC44C173C1E3Q26991838-6971F71A-6B4E-486F-8412-A34DBCA61BFAQ28383558-7F99FD58-764F-44FD-B855-40BB95C977D1Q28390601-929F592A-54C2-4208-B271-B04284A4DCACQ28475361-17108371-42D9-45B2-B22E-D92BBC22601FQ28550207-71BF8DE3-535D-45F7-9D25-FD92399D6CAFQ30446201-D94C45B1-59BC-4B8F-B619-27FF0578D072Q30497570-5D9EAE57-79FB-4C82-A40C-15DA765CA939Q30531301-AF30D4AF-AADF-46AD-8647-43E30FC08D10Q30594925-DB52F0A2-70F5-4195-892C-E54EFFD4F94AQ33498649-C9FBD7E9-9481-4BFF-9AAA-C5F7887D3FE9Q33594740-E86F0FBF-5063-478A-9BF1-A88D9B259118Q33657758-F47FAF69-9187-490E-B04F-5C0CEC930AF6Q33917872-696851A9-27F4-4FF6-9A98-0BA06CAC5D18Q34093983-5ECE2AD2-6EE3-4CC2-A6B9-D6B1366AEA9BQ34142373-EB1C09F4-8818-4482-908A-EE7DC8B47EDEQ34147890-5EB33A5A-F584-4B0A-8171-45365829C1EBQ34378362-21AD7957-8CC9-4F5A-8F3B-5A3EF831A312Q34562339-FBE22F5C-7DC2-4F3C-8550-6FBB93B1AD45Q34625284-7ECD79AA-54C2-4AA0-97DC-80E558043CABQ34777969-87AE84F1-0246-471B-B494-DEDE93D8DAE2Q34980223-56BF8156-3A85-4DDE-99E1-99CEE709C147Q35040415-27A31847-5843-4455-A6AF-B328F8E1F668Q35060204-BD890E72-098F-4609-9EB5-6CB7329A9A41Q35556472-039192BA-8C4F-464E-99EA-CF1F9331DFC8Q35589875-30549E52-5985-4069-8F40-01413B7CFC46Q35589949-B12CEF66-349A-4C7A-80BA-3D5C14FF1E0DQ35647382-198BF1D5-5D64-4ECC-B13C-359F29837E51Q35667043-7A27A58C-8659-4BFB-BBEC-9050E2567080Q35682342-32118B54-A6A7-4927-A71F-BD25E3E98F51Q35682354-16B7CEC0-95F8-4485-AAE9-C641749C080AQ35803795-9000B47F-87FC-450E-A466-7BDCFE7FA8E2Q35921561-24DA8C93-15BE-4A3D-B75F-EB8085D254D5Q35980803-E8C4BC78-EA75-4EAD-A011-EFAD16341DF6Q36129940-F439783D-232F-457A-B920-1F70662BBD77Q36321621-931C665C-EDE0-4FB8-A1F2-BB4D71DF16C6Q36366723-D839046E-6317-4907-8747-EE35E41F7399Q36399993-9A3478F0-11D1-4B1B-A02D-5DAE75144FFE
P2860
Evolution of post-traumatic neurodegeneration after controlled cortical impact traumatic brain injury in mice and rats as assessed by the de Olmos silver and fluorojade staining methods.
description
2008 nî lūn-bûn
@nan
2008年の論文
@ja
2008年学术文章
@wuu
2008年学术文章
@zh-cn
2008年学术文章
@zh-hans
2008年学术文章
@zh-my
2008年学术文章
@zh-sg
2008年學術文章
@yue
2008年學術文章
@zh
2008年學術文章
@zh-hant
name
Evolution of post-traumatic ne ...... d fluorojade staining methods.
@en
type
label
Evolution of post-traumatic ne ...... d fluorojade staining methods.
@en
prefLabel
Evolution of post-traumatic ne ...... d fluorojade staining methods.
@en
P2093
P356
P1476
Evolution of post-traumatic ne ...... d fluorojade staining methods.
@en
P2093
Edward D Hall
Patrick G Sullivan
Wongil Cho
Ying Deng Bryant
P304
P356
10.1089/NEU.2007.0383
P577
2008-03-01T00:00:00Z