about
Melatonin and Ischemic Stroke: Mechanistic Roles and ActionMotor System Reorganization After Stroke: Stimulating and Training Toward PerfectionFunctional real-time optoacoustic imaging of middle cerebral artery occlusion in mice.Stroke-induced brain parenchymal injury drives blood-brain barrier early leakage kinetics: a combined in vivo/in vitro study.Mapping remote subcortical ramifications of injury after ischemic strokesAstrocytic transforming growth factor-beta signaling reduces subacute neuroinflammation after stroke in miceBlood cells and endothelial barrier function.Growth Differentiation Factor 15 Expression in Astrocytes After Excitotoxic Lesion in the Mouse HippocampusPressure modulation algorithm to separate cerebral hemodynamic signals from extracerebral artifactsEffects of Tetramethylpyrazine on Functional Recovery and Neuronal Dendritic Plasticity after Experimental Stroke.Characterization of Lactate Sensors Based on Lactate Oxidase and Palladium Benzoporphyrin Immobilized in Hydrogels.Prefrontal Ischemia in the Rat Leads to Secondary Damage and Inflammation in Remote Gray and White Matter Regions.Artery reopening is required for the neurorestorative effects of angiotensin modulation after experimental strokeNeurological disorders in a murine model of chronic renal failureGLP-1R activation for the treatment of stroke: updating and future perspectives.Spreading depolarization in the ischemic brain: does aging have an impact?The 3 Rs of Stroke Biology: Radial, Relayed, and Regenerative.Microglia-blood vessel interactions: a double-edged sword in brain pathologies.Perivascular microglia promote blood vessel disintegration in the ischemic penumbra.Activated microglia in ischemic stroke penumbra upregulate MCP-1 and CCR2 expression in response to lysophosphatidylcholine derived from adjacent neurons and astrocytes.Single-cell resolution mapping of neuronal damage in acute focal cerebral ischemia using thallium autometallography.Mapping of cerebral metabolic rate of oxygen using dynamic susceptibility contrast and blood oxygen level dependent MR imaging in acute ischemic stroke.Nonthermal ablation in the rat brain using focused ultrasound and an ultrasound contrast agent: long-term effects.Dynamic changes in sleep-related breathing abnormalities in bilateral paramedian mesencephalon and thalamus stroke: a follow-up case study.PET imaging of the neurovascular interface in cerebrovascular disease.Endotoxemia induces lung-brain coupling and multi-organ injury following cerebral ischemia-reperfusion.Are Major Dementias Triggered by Poor Blood Flow to the Brain? Theoretical Considerations.Understanding Spreading Depression from Headache to Sudden Unexpected Death.Monitoring Pressure Augmentation in Patients With Ischemic Penumbra Using Continuous Electroencephalogram: Three Cases and a Review of the Literature.Effect of Routine Low-Dose Oxygen Supplementation on Death and Disability in Adults With Acute Stroke: The Stroke Oxygen Study Randomized Clinical Trial.Carbon monoxide poisoning in the 21st century.Paradigm Shift to Neuroimmunomodulation for Translational Neuroprotection in Stroke.
P2860
Q26782228-064160B8-1CF5-4A1D-B1E0-2DE42F2BBC24Q26795480-7989B0A5-CAAD-4CBE-97C1-99166F33698BQ30438996-1917E03D-E41F-4C7B-8040-2211D58910EBQ30670996-DA2AEE7B-72AB-498A-8E50-33A908A089D5Q33598053-EC3F9BA8-ECD9-4BA2-A7EF-EC10A1AD2E44Q33769818-CE7A6F16-E722-4FDC-8909-7DA62C11C604Q35212839-88D1B390-2B31-4814-A30E-48010F48606BQ35778076-B14B4A45-3458-4550-8110-96F64614FF80Q35915627-829765EF-0F4C-4958-84D8-48B21B450FB4Q36038352-A445CAF5-5C76-4FCD-9646-F04483752656Q36143771-6F2DC7FC-6357-47CF-8113-7F21F5992E57Q36637202-497CFA74-937C-4F9D-B2F4-88554B59A119Q36846675-A8027168-4ED8-4398-9AC8-AD78B05EEC2FQ37576183-E5A3090C-EB36-4D42-A243-93708E2E9FA1Q38207948-601EB001-9A43-47DF-90EB-8AF32466E38DQ38210235-7CDAFAAF-87AE-4E9D-A23A-C86298115B9BQ38646400-F0C1A18F-A5CE-41E8-8EB5-24E83B821DCBQ38681675-10116ABF-583E-4033-9ECE-BD9D3217315FQ38929347-B93F351B-AFAA-4F42-939F-BAC6B1FB0F10Q38936183-E362D870-DA52-4EE3-94DF-1BBF11B4EAACQ41863668-D5EE18E0-7A53-4DAA-825B-189132F31E17Q46723636-6B1FC8C0-EA7F-42C6-B69B-5C1DA4B9A32CQ47316139-8FFC4E29-915F-4FDB-B9B6-362522B90849Q47965608-14CE5622-E3AD-455F-96C2-8A9356EBBCF9Q48031424-EBCED97D-FD20-4A39-A445-B8B67FF6B24CQ48173637-9BB70CC2-6806-4B39-873B-AC8406233694Q48304352-FDB4E8BE-4EE4-4CBF-8EEA-16C9A2D43969Q49528803-C47C5FFA-44BC-4E59-86AF-72C61F093BE6Q49634794-DC74E2D4-BE9B-4F1D-BAF2-85EDA941DACCQ49649607-FB501731-EB9D-4B5A-B5C5-8A27A2E5C314Q50319978-B9EB699C-3CB9-4A1F-866C-2609035AF8F0Q52564678-B65470A1-4CA4-4295-A2CC-DF9898AD90E7
P2860
description
article científic
@ca
article scientifique
@fr
articol științific
@ro
articolo scientifico
@it
artigo científico
@gl
artigo científico
@pt
artigo científico
@pt-br
artikel ilmiah
@id
artikull shkencor
@sq
artículo científico
@es
name
The ischemic penumbra: how does tissue injury evolve?
@en
type
label
The ischemic penumbra: how does tissue injury evolve?
@en
prefLabel
The ischemic penumbra: how does tissue injury evolve?
@en
P2860
P1476
The ischemic penumbra: how does tissue injury evolve?
@en
P2093
Wolf-Dieter Heiss
P2860
P356
10.1111/J.1749-6632.2012.06668.X
P407
P577
2012-09-01T00:00:00Z