The role of monoamine metabolism in oxidative glutamate toxicity.
about
Equine estrogens differentially inhibit DNA fragmentation induced by glutamate in neuronal cells by modulation of regulatory proteins involved in programmed cell deathAntidepressive, anxiolytic, and antiaddictive effects of ayahuasca, psilocybin and lysergic acid diethylamide (LSD): a systematic review of clinical trials published in the last 25 yearsParallels between major depressive disorder and Alzheimer's disease: role of oxidative stress and genetic vulnerabilityInhibition of a constitutive translation initiation factor 2alpha phosphatase, CReP, promotes survival of stressed cellsCalcium-sensitive regulation of monoamine oxidase-A contributes to the production of peroxyradicals in hippocampal cultures: implications for Alzheimer disease-related pathology.Differential mechanisms underlying neuroprotection of hydrogen sulfide donors against oxidative stress.Mitochondrial superoxide dismutase SOD2, but not cytosolic SOD1, plays a critical role in protection against glutamate-induced oxidative stress and cell death in HT22 neuronal cellsMechanism for the protective effect of resveratrol against oxidative stress-induced neuronal death.Delayed treatment with a novel neurotrophic compound reduces behavioral deficits in rabbit ischemic strokeFerulic acid attenuates the injury-induced decrease of protein phosphatase 2A subunit B in ischemic brain injuryPirlindole and dehydropirlindole protect rat cultured neuronal cells against oxidative stress-induced cell death through a mechanism unrelated to MAO-A inhibition.Modulation of voltage-gated channel currents by harmaline and harmane.Focal Cerebral Ischemia Reduces Protein Phosphatase 2A Subunit B Expression in Brain Tissue and HT22 CellsCellular protection using Flt3 and PI3Kα inhibitors demonstrates multiple mechanisms of oxidative glutamate toxicity.The alteration of components in the fermented Hwangryunhaedok-tang and its neuroprotective activityTraditional reactive carbonyl scavengers do not prevent the carbonylation of brain proteins induced by acute glutathione depletion.Dieckol Attenuates Microglia-mediated Neuronal Cell Death via ERK, Akt and NADPH Oxidase-mediated PathwaysDeciphering the regulatory logic of an ancient, ultraconserved nuclear receptor enhancer moduleNeuroprotection and spatial memory enhancement of four herbal mixture extract in HT22 hippocampal cells and a mouse model of focal cerebral ischemia.Involvement of Heme Oxygenase-1 Induction in the Cytoprotective and Immunomodulatory Activities of Viola patrinii in Murine Hippocampal and Microglia Cells.Ketone bodies protection against HIV-1 Tat-induced neurotoxicity.The regulation of reactive oxygen species production during programmed cell death.Gingko biloba extract (EGb 761) attenuates ischemic brain injury-induced reduction in Ca(2+) sensor protein hippocalcin.Molecular basis for glucocorticoid induction of the Kruppel-like factor 9 gene in hippocampal neurons.Phosphatidylcholine-specific phospholipase C regulates glutamate-induced nerve cell death.Structure-activity relationship study of vitamin k derivatives yields highly potent neuroprotective agentsMitochondrial small conductance SK2 channels prevent glutamate-induced oxytosis and mitochondrial dysfunction.Drug-like property profiling of novel neuroprotective compounds to treat acute ischemic stroke: guidelines to develop pleiotropic moleculesAnti-Inflammatory and Cytoprotective Effects of TMC-256C1 from Marine-Derived Fungus Aspergillus sp. SF-6354 via up-Regulation of Heme Oxygenase-1 in Murine Hippocampal and Microglial Cell Lines.Transcranial magnetic stimulation and amyotrophic lateral sclerosis: pathophysiological insights.Focal cerebral ischemic injury decreases calbindin expression in brain tissue and HT22 cells.The Association Between Oxidative Stress and Depressive Symptom Scores in Elderly Population: A Repeated Panel Study.Ischemic brain injury decreases dynamin-like protein 1 expression in a middle cerebral artery occlusion animal model and glutamate-exposed HT22 cells.Dynamic NHERF interaction with TRPC4/5 proteins is required for channel gating by diacylglycerol.Neuroprotective action of N-acetyl serotonin in oxidative stress-induced apoptosis through the activation of both TrkB/CREB/BDNF pathway and Akt/Nrf2/Antioxidant enzyme in neuronal cellsMitochondrial function and energy metabolism in neuronal HT22 cells resistant to oxidative stress.The puzzling case of hyperexcitability in amyotrophic lateral sclerosis.De-Risking of Stilbazulenyl Nitrone (STAZN), a Lipophilic Nitrone to Treat Stroke Using a Unique Panel of In Vitro Assays.Transcranial Magnetic Stimulation for the Assessment of Neurodegenerative Disease.Activation of SK2 channels preserves ER Ca²⁺ homeostasis and protects against ER stress-induced cell death.
P2860
Q24795759-26CD97FF-CFEF-4E7F-A6EE-E55672E7586DQ26746137-614CF61C-9E49-42A5-9E4E-92B3A001C649Q27000066-5915D966-CE44-4F27-B0B5-90F2356C9832Q28513964-E1621ADD-C5A1-4986-A247-5AFD1400EB95Q33299033-1F086223-7059-4DFE-9815-EE8B6D7EB284Q33692977-9173EA4D-2B9B-4BAA-B732-65FA9704E9DBQ33819712-0EBF4505-7A04-42BB-A6B7-E4A74241FA6CQ34121946-232811C5-7F10-46B6-BE78-59E7210E47F6Q34417300-8D67D43B-940E-4F6A-8506-48336F06F4DEQ34562794-B921F8F6-1485-4CB8-B96E-3E786A4F1F14Q35044098-B1CA6146-984A-41B3-95C8-E82FA3509402Q35048502-9253F3E9-94D0-4D34-AEBB-C6E3FB9B60ECQ35134895-616044CA-74C3-4F7F-AC14-6B0F0F950562Q35150284-F8891363-CBD8-4DE5-B24B-C6D9DADB76F2Q35215210-650099CB-7C81-48C1-B28D-9E0CE12775E9Q35514192-CEAB7A6B-3E04-4099-A790-3A750276E4DAQ35578603-77D409FD-F622-405A-916A-CE0A332353DEQ35600094-935DF9A5-D90D-46A2-AD72-F2A3D88A7D29Q35677723-1BD728C6-3347-4DC0-B653-D7A1CD37807FQ35872370-1F42E775-CE6A-4B68-B553-D139E9651F48Q36166231-24E38B61-5965-496E-A8ED-B5D6A0F7B0D9Q36255441-53F383FD-8E9C-4403-A51D-F737E11E22D7Q36313238-3F589951-355B-4302-B9EF-F7C920C9E890Q36323153-8BFE7663-F8BC-4874-AF25-4252889D2C66Q36508125-79BD218D-077E-4D34-A1BE-C0D55126264EQ36672143-947E0473-E206-4661-92D5-70B02DC60EECQ36760412-5C11806D-1205-4D08-8E3E-01261EFD1DAEQ36841904-F9F397C2-CD46-4AD5-B0F1-B73C44B1743DQ36847122-71131588-6D98-4F1B-971D-40B69EA2EBAAQ37206683-30317535-F578-4FBA-BC81-4059D0DD61FAQ37217334-6B974902-66C5-4CF7-BB03-33C622A9FCEDQ37343390-9FBE3FB1-B853-458B-A76C-B49797BC4125Q37549004-CE98A54C-7357-428D-AAFA-68A2A626F8B5Q37577232-818B751C-2872-4849-9977-C940535E42A7Q37595140-BDADCDD7-AB0D-4FAB-A670-0927311CF553Q37686291-4D3F29E5-9D93-40EC-8BBF-0968D3A0A00EQ38102695-EC60A7C6-7881-42ED-846E-1DA96040F59AQ38681976-E81F890A-6DA2-4A77-89A7-1CE047C916C0Q38796845-AA1FBF8F-48D7-4010-81FA-57FE21F04BE2Q38818195-BAEBAFF3-BF23-42C5-89B3-E0F868CECEC7
P2860
The role of monoamine metabolism in oxidative glutamate toxicity.
description
1996 nî lūn-bûn
@nan
1996年の論文
@ja
1996年論文
@yue
1996年論文
@zh-hant
1996年論文
@zh-hk
1996年論文
@zh-mo
1996年論文
@zh-tw
1996年论文
@wuu
1996年论文
@zh
1996年论文
@zh-cn
name
The role of monoamine metabolism in oxidative glutamate toxicity.
@en
type
label
The role of monoamine metabolism in oxidative glutamate toxicity.
@en
prefLabel
The role of monoamine metabolism in oxidative glutamate toxicity.
@en
P1476
The role of monoamine metabolism in oxidative glutamate toxicity
@en
P2093
P304
P356
10.1523/JNEUROSCI.16-20-06394.1996
P407
P577
1996-10-01T00:00:00Z