about
Prevention of LPS-induced microglia activation, cytokine production and sickness behavior with TLR4 receptor interfering peptidesExpression of voltage-gated Ca2+ channel subtypes in cultured astrocytesGlial and neuronal control of brain blood flowMicroglia: Dynamic Mediators of Synapse Development and Plasticity.Cognitive flexibility and long-term depression (LTD) are impaired following β-catenin stabilization in vivo.Mapping synaptic glutamate transporter dysfunction in vivo to regions surrounding Aβ plaques by iGluSnFR two-photon imaging.Development of Ca2+ hotspots between Lymnaea neurons during synaptogenesis.Microglia processes block the spread of damage in the brain and require functional chloride channels.A practical guide to the synthesis and use of membrane-permeant acetoxymethyl esters of caged inositol polyphosphates.Pannexin1 knockout and blockade reduces ischemic stroke injury in female, but not in male mice.Glutathione restores the mechanism of synaptic plasticity in aged mice to that of the adult.Metabolic communication between astrocytes and neurons via bicarbonate-responsive soluble adenylyl cyclaseIncreased 20-HETE synthesis explains reduced cerebral blood flow but not impaired neurovascular coupling after cortical spreading depression in rat cerebral cortex.Astrocyte control of the cerebrovasculature.Activation of neuronal NMDA receptors triggers transient ATP-mediated microglial process outgrowth.Astrocyte regulation of blood flow in the brainAnion channels in astrocytes: biophysics, pharmacology, and function.GABAA/benzodiazepine receptors in acutely isolated hippocampal astrocytes.Pannexin channels are not gap junction hemichannels.Regenerative glutamate release by presynaptic NMDA receptors contributes to spreading depression.Connexin and pannexin hemichannels of neurons and astrocytes.In vivo imaging reveals that pregabalin inhibits cortical spreading depression and propagation to subcortical brain structures.A Critical Role for Astrocytes in Hypercapnic Vasodilation in Brain.Recording, analysis, and interpretation of spreading depolarizations in neurointensive care: Review and recommendations of the COSBID research group.Bidirectional Control of Blood Flow by Astrocytes: A Role for Tissue Oxygen and Other Metabolic Factors.Astrocytes Provide Metabolic Support for Neuronal Synaptic Function in Response to Extracellular K().Tumor-suppressive effects of pannexin 1 in C6 glioma cells.Neurone-glia interactions in the hypothalamus and pituitary.Disinhibition and brain rhythms.Lipid Nanoparticle Delivery of siRNA to Silence Neuronal Gene Expression in the BrainMicroglia in neuronal circuits.Astrocyte-mediated distributed plasticity at hypothalamic glutamate synapses.Brain metabolism dictates the polarity of astrocyte control over arteriolesLow-threshold transient calcium current in rat hippocampal lacunosum-moleculare interneurons: kinetics and modulation by neurotransmitters.The cost of communication in the brainIn vitro ischemia promotes calcium influx and intracellular calcium release in hippocampal astrocytes.Nitric oxide promotes intracellular calcium release from mitochondria in striatal neurons.Serine/threonine protein phosphatases and synaptic inhibition regulate the expression of cholinergic-dependent plateau potentials.Ca(2+)- and voltage-dependent inactivation of Ca2+ currents in rat intermediate pituitary.P2X7-like receptor activation in astrocytes increases chemokine monocyte chemoattractant protein-1 expression via mitogen-activated protein kinase.
P50
Q27330317-F8FCE78F-0F7C-4C44-A5BF-C04644D1AACBQ28580537-DDED6601-B7D9-42D2-811B-01388F90E3B0Q29620058-447B8A64-12A7-4904-B3C6-C227CB7F9DF4Q30373424-50029C6D-6AAE-4ADA-AD58-15C7A1EA57B4Q30580933-587B8156-DB47-4FBA-9E30-9FC7ADD7333DQ30829062-5FAC5161-AD89-4D55-AC9C-2E5893E89F2FQ31039016-228C2FF5-E63A-4F1E-8E45-2D72E16340B3Q33433015-E0FF448E-725A-46CE-A6A0-5C9B2CEAF213Q33836704-DBE8D53F-A28D-443C-9F42-3E0C7D313763Q33913803-EBF279D6-DB71-4AAF-A188-DCCF71ECFCEAQ33926940-86BA7FCF-ECAB-4AAD-B31C-57D1796E8DF0Q34301133-55A14C6B-ADD3-44A8-AD42-1BE8C7D2FD52Q34580712-EA38208A-B6D2-4DDE-BAA9-BA96E9D10BF5Q34656875-05AF8268-7F45-4A2B-9047-798A31819AAFQ35220649-745375BF-1560-4D10-B361-5AE207204329Q35663954-93BF4E6F-9EB1-46F3-B943-54BAC7BB7492Q36606132-99001792-D2D9-4247-9352-4BFA2942BB48Q36700926-5BB526C9-B064-4C32-956B-3C87582EB49BQ36992413-80C4C6F0-9737-439B-9DEA-C1F1F4F8EC2FQ37216115-EE61DCAC-03AB-4A64-BE56-1D9FBD47415CQ37292232-EF47FDB7-5ACA-4C1B-AA1A-759E6916376DQ37682393-2D004C75-E4BE-47BE-ACF9-16EA55FA7EBAQ37705488-203C9B99-FECA-475E-9E9A-B1CFC16A2376Q38851444-7DA233CE-B34E-4720-9228-D978606437CDQ38876577-04683D00-E0B6-4FA3-8C84-1ACC96770FB9Q39406334-5647A298-6890-47BA-8B97-F5F3BF850E0BQ40169694-814701EC-EF3F-49D0-9625-79C6ABABE5CEQ41141080-7CB18B56-5483-4A4E-953F-CFCBCE6D34D4Q41468073-91C8B7C7-0991-42CD-99C0-5A50BE5798F9Q41810449-4A656E76-6197-4D4C-951C-34D4C2870D93Q41811720-E816CBDB-EDC0-4B1B-9109-7EF7953FBDD2Q42025298-01EE463D-DF24-458E-BAAB-65516DF61A74Q42089441-38717C57-E13A-4A9F-A9EB-0F3AD0A241C8Q42124247-D06BC932-BC77-4C0D-BD55-44D3114A12C3Q42249169-9587E0F5-0C08-4126-BDD7-9992005F65CDQ42516612-62004AE3-20B5-41AB-8F4C-B88892C937CFQ42526805-1AA62FD6-0B50-4AA1-8CDF-BE91DE7F6A7CQ43541827-F3CB0243-A9F1-4367-9780-B6C3BA5A593CQ43563467-7DC48AAE-CA60-470D-8D88-BE12F5C850FAQ43732527-83FB94DC-F548-421D-9E77-99341389951A
P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Brian A. MacVicar
@ast
Brian A. MacVicar
@en
Brian A. MacVicar
@es
Brian A. MacVicar
@sl
type
label
Brian A. MacVicar
@ast
Brian A. MacVicar
@en
Brian A. MacVicar
@es
Brian A. MacVicar
@sl
prefLabel
Brian A. MacVicar
@ast
Brian A. MacVicar
@en
Brian A. MacVicar
@es
Brian A. MacVicar
@sl
P1053
P-1553-2015
P106
P1153
7006717711
P21
P31
P3829
P496
0000-0003-4596-4623