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NBQX,AMPA /海藻酸盐拮抗剂

AMPA /海藻酸盐拮抗剂
COA COA
    级别和纯度:
  • ≥99%
有货

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货号 (SKU) 包装规格 是否现货 价格 数量
N274693-5mg
 5mg 现货 Stock Image
N274693-10mg
 10mg 现货 Stock Image
N274693-25mg
 25mg 现货 Stock Image
N274693-50mg
 50mg 现货 Stock Image
N274693-100mg
 100mg 现货 Stock Image
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查看相关系列
神经元信号传导 (3320) 离子型谷氨酸受体 (238) 离子通道 (4087) 膜转运器/离子通道 (1829)
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基本描述

别名 2,3-二氧-6-硝基-1,2,3,4-四氢苯并[f]喹喔啉-7-磺酰胺 | 二羟基喹酮
英文别名 2,3-Dihydroxy-6-nitro-benzo[f]quinoxaline-7-sulfonic acid amide | BPBio1_001312 | SR-01000597617-1 | NBQX hydrate | BRD-K11796549-001-02-9 | Tocris-0373 | BDBM50207594 | AC-36382 | 1,2,3,4-tetrahydro-6-nitro-2,3-dioxobenzo[f]quinoxaline-7-sulfonamide | GT
规格或纯度 ≥99%
英文名称 NBQX
生化机理 NBQX [2,3-二羟基-6-硝基-7-氨基磺酰基苯并(F)喹喔啉]是一种抗惊厥药,可防止脊髓挤压伤中的白质损伤,并在实验性自身免疫性脑脊髓炎(EAE)中保护少突胶质细胞。然而,其在预防EAE中炎症的作用尚不清楚。神经保护AMPA/红藻氨酸谷氨酸受体拮抗剂
储存温度 避光,-20°C储存,干燥
运输条件 超低温冰袋运输
备注 如果有可能,您尽量在使用的当天配置溶液,并在当天使用完它。但是,如果您需要预先配制储备溶液,我们建议您将溶液等份保存在-20°C的密封小瓶中。通常,它们最多可以使用一个月。在使用前和打开样品瓶之前,我们建议您让您的产品在室温下平衡至少1小时。需要更多关于溶解度,用法和处理的建议吗?请访问我们的常见问题(FAQ)页面以获取更多详细信息。
产品介绍

NBQX [2,3-二羟基-6-硝基-7-氨基磺酰基苯并(F)喹喔啉]是一种竞争性拮抗剂,其对2-氨基-3-羟基-5-甲基-4-异恶唑丙酸( AMPA)受体的亲和力要比钾盐镁矾受体高。
产品用途:
NBQX 水合物已用于:1、作为非NN-甲基-D-天冬氨酸受体 (NMDA)的 2-氨基-3-羟基-5-甲基-4-异恶唑丙酸(AMPA) 受体拮抗剂用于监测促性腺激素反应;2、α单核细胞中的-氨基-3-羟基-5-甲基-4-异恶唑丙酸受体 (AMPAR) 拮抗剂;3、在表达氯化钾共转运蛋白(shKCC2)的迁移中间神经元中的AMPA 和 N-甲基-D-天冬氨酸受体 (NMDA) 拮抗剂。
纯度 ≥99%

关联靶点(人)

GRIA4 Tclin 谷氨酸受体 4(Glutamate receptor 4) (2 活性数据)
活性类型 活性值-log(M) 作用机制 期刊 参考文献(PubMed IDs)
GRIA2 Tclin 谷氨酸受体 2(Glutamate receptor 2) (4 活性数据)
活性类型 活性值-log(M) 作用机制 期刊 参考文献(PubMed IDs)
GRIA3 Tclin 谷氨酸受体 3(Glutamate receptor 3) (2 活性数据)
活性类型 活性值-log(M) 作用机制 期刊 参考文献(PubMed IDs)
GRIA1 Tclin 谷氨酸受体 1(Glutamate receptor 1) (2 活性数据)
活性类型 活性值-log(M) 作用机制 期刊 参考文献(PubMed IDs)
VDR Tclin Vitamin D receptor (26531 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
GRIN1 Tclin Glutamate (NMDA) receptor subunit zeta 1 (122 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
THRB Tclin Thyroid hormone receptor beta-1 (7926 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
GRIA3 Tclin Glutamate receptor ionotropic, AMPA 3 (127 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
GLA Tclin Alpha-galactosidase A (5444 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
ARSA Tbio Cerebroside-sulfatase (655 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
GRM6 Tchem Metabotropic glutamate receptor 6 (361 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
GRIA1 Tclin Glutamate receptor ionotropic, AMPA 1 (277 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
ALDH1A1 Tchem Aldehyde dehydrogenase 1A1 (77053 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
GRIA2 Tclin Glutamate receptor ionotropic, AMPA 2 (847 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
GRIK3 Tclin Glutamate receptor ionotropic kainate 3 (50 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
CYP2D6 Tclin Cytochrome P450 2D6 (33882 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
GRIK5 Tclin Glutamate receptor ionotropic kainate 5 (45 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
ALOX15 Tchem Arachidonate 15-lipoxygenase (7108 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
GRIK1 Tclin Glutamate receptor ionotropic kainate 1 (340 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
CYP1A2 Tchem Cytochrome P450 1A2 (26471 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
PIN1 Tchem Peptidyl-prolyl cis-trans isomerase NIMA-interacting 1 (36611 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
CYP2C9 Tchem Cytochrome P450 2C9 (32119 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
CYP2C19 Tchem Cytochrome P450 2C19 (29246 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
CYP3A4 Tclin Cytochrome P450 3A4 (53859 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
GRIN2C Tclin Glutamate [NMDA] receptor subunit epsilon 3 (47 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
SH-SY5Y (11521 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
HSD17B10 Tchem Endoplasmic reticulum-associated amyloid beta-peptide-binding protein (20669 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
POLK Tbio DNA polymerase kappa (8653 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
APEX1 Tchem DNA-(apurinic or apyrimidinic site) lyase (38016 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
EHMT2 Tchem Histone-lysine N-methyltransferase, H3 lysine-9 specific 3 (93046 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
TDP1 Tchem Tyrosyl-DNA phosphodiesterase 1 (345557 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
KDM4E Tchem Lysine-specific demethylase 4D-like (40243 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
RECQL Tbio ATP-dependent DNA helicase Q1 (5575 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
HPGD Tchem 15-hydroxyprostaglandin dehydrogenase [NAD+] (24926 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
CBX1 Tbio Chromobox protein homolog 1 (92434 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
ATXN2 Tbio Ataxin-2 (54410 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
USP1 Tchem Ubiquitin carboxyl-terminal hydrolase 1 (22556 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
RGS4 Tchem Regulator of G-protein signaling 4 (13867 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
MEN1 Tchem Menin/Histone-lysine N-methyltransferase MLL (48157 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
RUNX1 Tbio Runt-related transcription factor 1/Core-binding factor subunit beta (7867 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
GRIN1 Tclin Glutamate [NMDA] receptor (933 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
GRIA4 Tclin Glutamate receptor ionotropic AMPA (265 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
GRIK1 Tclin Glutamate receptor ionotropic kainate (68 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID

关联靶点(其它种属)

Hdac6 Histone deacetylase 6 (222 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
Gria4 Glutamate receptor ionotropic, AMPA 4 (112 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
Grik2 Glutamate receptor ionotropic kainate 2 (298 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
Gerbillinae (442 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
Mus musculus (284745 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
Rattus norvegicus (775804 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
lef Anthrax lethal factor (7585 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
GCN5 Histone acetyltransferase GCN5 (89 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
rep Replicase polyprotein 1ab (378 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
pfk 6-phospho-1-fructokinase (7870 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
Txnrd1 Thioredoxin reductase 1, cytoplasmic (45279 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
Mapt Microtubule-associated protein tau (6 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
fba Putative fructose-1,6-bisphosphate aldolase (15559 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
Impa1 Inositol monophosphatase 1 (16203 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
ffp 4'-phosphopantetheinyl transferase ffp (24982 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
Grin1 Glutamate NMDA receptor (6467 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
Gria2 Glutamate receptor ionotropic, AMPA (2103 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
Grik1 Glutamate receptor ionotropic, kainate (722 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
Grin1 Glutamate receptors; NMDA/AMPA (104 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
Gria2 Glutamate receptor AMPA 1/2 (4 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID
SARS-CoV-2 (38078 活性数据)
活性类型 Relation Activity value Units Action Type 期刊 PubMed Id doi Assay Aladdin ID

作用机制

作用机制 Action Type target ID Target Name Target Type Target Organism Binding Site Name 参考文献

名称和识别符

PubChem SID 488194341
分子类型 小分子
IIUPAC Name 6-nitro-2,3-dioxo-1,4-dihydrobenzo[f]quinoxaline-7-sulfonamide
INCHI 1S/C12H8N4O6S/c13-23(21,22)8-3-1-2-5-9(8)7(16(19)20)4-6-10(5)15-12(18)11(17)14-6/h1-4H,(H,14,17)(H,15,18)(H2,13,21,22)
InChi Key UQNAFPHGVPVTAL-UHFFFAOYSA-N
Smiles C1=CC2=C3C(=CC(=C2C(=C1)S(=O)(=O)N)[N+](=O)[O-])NC(=O)C(=O)N3
Isomeric SMILES C1=CC2=C3C(=CC(=C2C(=C1)S(=O)(=O)N)[N+](=O)[O-])NC(=O)C(=O)N3
分子量 336.28
Reaxy-Rn 5886510
Reaxys-RN link address https://www.reaxys.com/reaxys/secured/hopinto.do?context=S&query=IDE.XRN=5886510&ln=

化学和物理性质

溶解性 Soluble in DMSO to 100 mM
敏感性 对光线敏感
分子量 336.280 g/mol
XLogP3 0.100
氢键供体数Hydrogen Bond Donor Count 3
氢键受体数Hydrogen Bond Acceptor Count 7
可旋转键计数Rotatable Bond Count 1
精确质量Exact Mass 336.016 Da
单同位素质量Monoisotopic Mass 336.016 Da
拓扑极表面积Topological Polar Surface Area 173.000 Ų
重原子数Heavy Atom Count 23
形式电荷Formal Charge 0
复杂度Complexity 653.000
同位素原子数Isotope Atom Count 0
定义的原子立体中心计数Defined Atom Stereocenter Count 0
未定义的原子立体中心计数Undefined Atom Stereocenter Count 0
定义的键立体中心计数Defined Bond Stereocenter Count 0
未定义的键立体中心计数Undefined Bond Stereocenter Count 0
所有立体化学键的总数The total count of all stereochemical bonds 0
共价键合单元计数Covalently-Bonded Unit Count 1

安全和危险性(GHS)

象形图 GHS07
信号词 警告

质检证书(CoA,COO,BSE/TSE 和分析图谱)

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批号(Lot Number) 证书类型 货号
C2331751 分析证书 N274693
C2331786 分析证书 N274693
C2331670 分析证书 N274693
C2331749 分析证书 N274693
C2331777 分析证书 N274693
C2331769 分析证书 N274693
C2331758 分析证书 N274693
C2331750 分析证书 N274693
C2331745 分析证书 N274693
C2331665 分析证书 N274693
C2518289 分析证书 N274693

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引用文献

1. Wulff P, Schonewille M, Renzi M, Viltono L, Sassoè-Pognetto M, Badura A, Gao Z, Hoebeek FE, van Dorp S, Wisden W et al..  (2009)  Synaptic inhibition of Purkinje cells mediates consolidation of vestibulo-cerebellar motor learning..  Nat Neurosci,  12  (8): (1042-9).  [PMID:19578381]
2. Dunlop J et al..  (2009)  Old and new pharmacology: positive allosteric modulation of the alpha7 nicotinic acetylcholine receptor by the 5-hydroxytryptamine(2B/C) receptor antagonist SB-206553 (3,5-dihydro-5-methyl-N-3-pyridinylbenzo[1,2-b:4,5-b']di pyrrole-1(2H)-carboxamide)..  J Pharmacol Exp Ther,  328  (3): (766-76).  [PMID:19050173]
3. Kelamangalath L et al..  (2011)  ?-Opioid receptor inhibition of calcium oscillations in spinal cord neurons..  Mol Pharmacol,  79  (6): (1061-71).  [PMID:21422300]
4. Meunier CN et al..  (2013)  5-HT1A receptors direct the orientation of plasticity in layer 5 pyramidal neurons of the mouse prefrontal cortex..  Neuropharmacology,  71  (37-45).  [PMID:23523560]
5. Bouthour W et al..  (2012)  A human mutation in Gabrg2 associated with generalized epilepsy alters the membrane dynamics of GABAA receptors..  Cereb Cortex,  22  (7): (1542-53).  [PMID:21908847]
6. Di Angelantonio S et al..  (2014)  A role for intracellular zinc in glioma alteration of neuronal chloride equilibrium..  Cell Death Dis,  (e1501).  [PMID:25356870]
7. Holmes NM et al..  (2017)  a2-adrenoceptor-mediated inhibition in the central amygdala blocks fear-conditioning..  Sci Rep,  (11712).  [PMID:28916748]
8. Barker M et al..  (2012)  Acoustic overexposure increases the expression of VGLUT-2 mediated projections from the lateral vestibular nucleus to the dorsal cochlear nucleus..  PLoS One,  (5): (e35955).  [PMID:22570693]
9. Pugh JR & Jahr CE.  (2013)  Activation of axonal receptors by GABA spillover increases somatic firing..  J Neurosci,  33  (43): (16924-9).  [PMID:24155298]
10. Uwechue NM et al..  (2012)  Activation of glutamate transport evokes rapid glutamine release from perisynaptic astrocytes..  J Physiol,  590  (Pt 10): (2317-31).  [PMID:22411007]
11. Brown JT & Randall AD.  (2009)  Activity-dependent depression of the spike after-depolarization generates long-lasting intrinsic plasticity in hippocampal CA3 pyramidal neurons..  J Physiol,  587  (Pt 6): (1265-81).  [PMID:19171653]
12. Chamma I et al..  (2013)  Activity-dependent regulation of the K/Cl transporter KCC2 membrane diffusion, clustering, and function in hippocampal neurons..  J Neurosci,  33  (39): (15488-503).  [PMID:24068817]
13. Salesse C et al..  (2011)  Age-dependent remodelling of inhibitory synapses onto hippocampal CA1 oriens-lacunosum moleculare interneurons..  J Physiol,  589  (Pt 20): (4885-901).  [PMID:21825029]
14. Vilar B et al..  (2013)  Alleviating pain hypersensitivity through activation of type 4 metabotropic glutamate receptor..  J Neurosci,  33  (48): (18951-65).  [PMID:24285900]
15. Tovar KR & Westbrook GL.  (2012)  Amino-terminal ligands prolong NMDA Receptor-mediated EPSCs..  J Neurosci,  32  (23): (8065-73).  [PMID:22674281]
16. Ren L et al..  (2018)  Anesthetics alleviate learning and memory impairment induced by electroconvulsive shock by regulation of NMDA receptor-mediated metaplasticity in depressive rats..  Neurobiol Learn Mem,  155  (65-77).  [PMID:29953948]
17. Sasaki T et al..  (2012)  Application of an optogenetic byway for perturbing neuronal activity via glial photostimulation..  Proc Natl Acad Sci U S A,  109  (50): (20720-5).  [PMID:23185019]
18. Greenwood SM & Bushell TJ.  (2010)  Astrocytic activation and an inhibition of MAP kinases are required for proteinase-activated receptor-2-mediated protection from neurotoxicity..  J Neurochem,  113  (6): (1471-80).  [PMID:20402964]
19. Pugh JR & Jahr CE.  (2011)  Axonal GABAA receptors increase cerebellar granule cell excitability and synaptic activity..  J Neurosci,  31  (2): (565-74).  [PMID:21228165]
20. Groth RD et al..  (2011)  Beta Ca2+/CaM-dependent kinase type II triggers upregulation of GluA1 to coordinate adaptation to synaptic inactivity in hippocampal neurons..  Proc Natl Acad Sci U S A,  108  (2): (828-33).  [PMID:21187407]
21. Su LD & Shen Y.  (2009)  Blockade of glutamate transporters facilitates cerebellar synaptic long-term depression..  Neuroreport,  20  (5): (502-7).  [PMID:19289926]
22. Goz RU et al..  (2020)  BRAFV600E expression in neural progenitors results in a hyperexcitable phenotype in neocortical pyramidal neurons..  J Neurophysiol,  123  (6): (2449-2464).  [PMID:32401131]
23. Wheeler DG et al..  (2012)  Ca(V)1 and Ca(V)2 channels engage distinct modes of Ca(2+) signaling to control CREB-dependent gene expression..  Cell,  149  (5): (1112-24).  [PMID:22632974]
24. Younts TJ et al..  (2013)  CA1 pyramidal cell theta-burst firing triggers endocannabinoid-mediated long-term depression at both somatic and dendritic inhibitory synapses..  J Neurosci,  33  (34): (13743-57).  [PMID:23966696]
25. Rock C & Apicella AJ.  (2015)  Callosal projections drive neuronal-specific responses in the mouse auditory cortex..  J Neurosci,  35  (17): (6703-13).  [PMID:25926449]
26. Ledgerwood CJ et al..  (2011)  Cannabidiol inhibits synaptic transmission in rat hippocampal cultures and slices via multiple receptor pathways..  Br J Pharmacol,  162  (286-94).  [PMID:20825410]
27. Evstratova A et al..  (2011)  Cell type-specific and activity-dependent dynamics of action potential-evoked Ca2+ signals in dendrites of hippocampal inhibitory interneurons..  J Physiol,  589  (Pt 8): (1957-77).  [PMID:21486769]
28. Nissen W et al..  (2010)  Cell type-specific long-term plasticity at glutamatergic synapses onto hippocampal interneurons expressing either parvalbumin or CB1 cannabinoid receptor..  J Neurosci,  30  (4): (1337-47).  [PMID:20107060]
29. Maroto M et al..  (2013)  Chondroitin sulfate, a major component of the perineuronal net, elicits inward currents, cell depolarization, and calcium transients by acting on AMPA and kainate receptors of hippocampal neurons..  J Neurochem,  [PMID:23350646]
30. Partridge JG et al..  (2014)  Contrasting actions of group I metabotropic glutamate receptors in distinct mouse striatal neurones..  J Physiol,  592  (13): (2721-33).  [PMID:24710062]
31. García-Junco-Clemente P et al..  (2010)  Cysteine string protein-alpha prevents activity-dependent degeneration in GABAergic synapses..  J Neurosci,  30  (21): (7377-91).  [PMID:20505105]
32. Tyan L et al..  (2014)  Dendritic inhibition provided by interneuron-specific cells controls the firing rate and timing of the hippocampal feedback inhibitory circuitry..  J Neurosci,  34  (13): (4534-47).  [PMID:24671999]
33. Mahler SV et al..  (2014)  Designer receptors show role for ventral pallidum input to ventral tegmental area in cocaine seeking..  Nat Neurosci,  17  (4): (577-85).  [PMID:24584054]
34. Rudolph S et al..  (2011)  Desynchronization of multivesicular release enhances Purkinje cell output..  Neuron,  70  (5): (991-1004).  [PMID:21658590]
35. Wills TA et al..  (2013)  Developmental changes in the acute ethanol sensitivity of glutamatergic and GABAergic transmission in the BNST..  Alcohol,  47  (7): (531-7).  [PMID:24103431]
36. Yang Y & Xu-Friedman MA.  (2015)  Different pools of glutamate receptors mediate sensitivity to ambient glutamate in the cochlear nucleus..  J Neurophysiol,  113  (10): (3634-45).  [PMID:25855696]
37. Husson Z et al..  (2014)  Differential GABAergic and glycinergic inputs of inhibitory interneurons and Purkinje cells to principal cells of the cerebellar nuclei..  J Neurosci,  34  (28): (9418-31).  [PMID:25009273]
38. Luo R et al..  (2013)  Direct and GABA-mediated indirect effects of nicotinic ACh receptor agonists on striatal neurones..  J Physiol,  591  (Pt 1): (203-17).  [PMID:23045343]
39. Chen N et al..  (2016)  Direct modulation of GFAP-expressing glia in the arcuate nucleus bi-directionally regulates feeding..  Elife,  [PMID:27751234]
40. Maher BJ & LoTurco JJ.  (2012)  Disrupted-in-schizophrenia (DISC1) functions presynaptically at glutamatergic synapses..  PLoS One,  (3): (e34053).  [PMID:22479520]
41. Han EB & Heinemann SF.  (2013)  Distal dendritic inputs control neuronal activity by heterosynaptic potentiation of proximal inputs..  J Neurosci,  33  (4): (1314-25).  [PMID:23345207]
42. Zhao Y et al..  (2009)  Distinct functional and anatomical architecture of the endocannabinoid system in the auditory brainstem..  J Neurophysiol,  101  (5): (2434-46).  [PMID:19279154]
43. Luo R et al..  (2013)  Distinct roles of synaptic and extrasynaptic GABAAreceptors in striatal inhibition dynamics..  Front Neural Circuits,  (186).  [PMID:24324406]
44. Marchionni I et al..  (2010)  Distinctive properties of CXC chemokine receptor 4-expressing Cajal-Retzius cells versus GABAergic interneurons of the postnatal hippocampus..  J Physiol,  588  (Pt 15): (2859-78).  [PMID:20547684]
45. Herman MA et al..  (2011)  Distribution of extracellular glutamate in the neuropil of hippocampus..  PLoS One,  (11): (e26501).  [PMID:22069455]
46. Chiu CQ et al..  (2010)  Dopaminergic modulation of endocannabinoid-mediated plasticity at GABAergic synapses in the prefrontal cortex..  J Neurosci,  30  (21): (7236-48).  [PMID:20505090]
47. Bard L et al..  (2010)  Dynamic and specific interaction between synaptic NR2-NMDA receptor and PDZ proteins..  Proc Natl Acad Sci U S A,  107  (45): (19561-6).  [PMID:20974938]
48. Neale SA et al..  (2014)  Effect of VGLUT inhibitors on glutamatergic synaptic transmission in the rodent hippocampus and prefrontal cortex..  Neurochem Int,  73  (159-65).  [PMID:24121008]
49. Povysheva NV & Johnson JW.  (2016)  Effects of memantine on the excitation-inhibition balance in prefrontal cortex..  Neurobiol Dis,  96  (75-83).  [PMID:27546057]
50. Zhang L & Alger BE.  (2010)  Enhanced endocannabinoid signaling elevates neuronal excitability in fragile X syndrome..  J Neurosci,  30  (16): (5724-9).  [PMID:20410124]
51. Ster J et al..  (2011)  Enhancement of CA3 hippocampal network activity by activation of group II metabotropic glutamate receptors..  Proc Natl Acad Sci U S A,  108  (24): (9993-7).  [PMID:21628565]
52. Trigo FF et al..  (2007)  Enhancement of GABA release through endogenous activation of axonal GABA(A) receptors in juvenile cerebellum..  J Neurosci,  27  (46): (12452-63).  [PMID:18003823]
53. Stepan J et al..  (2012)  Entorhinal theta-frequency input to the dentate gyrus trisynaptically evokes hippocampal CA1 LTP..  Front Neural Circuits,  (64).  [PMID:22988432]
54. Su LD et al..  (2010)  Ethanol acutely modulates mGluR1-dependent long-term depression in cerebellum..  Alcohol Clin Exp Res,  34  (7): (1140-5).  [PMID:20477778]
55. Cohen SM et al..  (2015)  Evolutionary and functional perspectives on signaling from neuronal surface to nucleus..  Biochem Biophys Res Commun,  460  (88-99).  [PMID:25998737]
56. De Saint Jan D et al..  (2009)  External tufted cells drive the output of olfactory bulb glomeruli..  J Neurosci,  29  (7): (2043-52).  [PMID:19228958]
57. Roberts MT et al..  (2008)  Fidelity of complex spike-mediated synaptic transmission between inhibitory interneurons..  J Neurosci,  28  (38): (9440-50).  [PMID:18799676]
58.  (1991)  From the Centers for Disease Control. AIDS Clinical Trials Information Service..  JAMA,  266  (13): (1756).  [PMID:1653860]
59. Doengi M et al..  (2009)  GABA uptake-dependent Ca(2+) signaling in developing olfactory bulb astrocytes..  Proc Natl Acad Sci U S A,  106  (41): (17570-5).  [PMID:19805126]
60. Li MH et al..  (2014)  GABAergic transmission and enhanced modulation by opioids and endocannabinoids in adult rat rostral ventromedial medulla..  J Physiol,  [PMID:25362151]
61. Wills TA et al..  (2012)  GluN2B subunit deletion reveals key role in acute and chronic ethanol sensitivity of glutamate synapses in bed nucleus of the stria terminalis..  Proc Natl Acad Sci U S A,  109  (5): (E278-87).  [PMID:22219357]
62. Anstötz M et al..  (2022)  Glutamate released by Cajal-Retzius cells impacts specific hippocampal circuits and behaviors..  Cell Rep,  39  (7): (110822).  [PMID:35584670]
63. Takazawa T & MacDermott AB.  (2010)  Glycinergic and GABAergic tonic inhibition fine tune inhibitory control in regionally distinct subpopulations of dorsal horn neurons..  J Physiol,  588  (Pt 14): (2571-87).  [PMID:20498232]
64. Baccini G et al..  (2012)  Impaired chemosensitivity of mouse dorsal raphe serotonergic neurons overexpressing serotonin 1A (Htr1a) receptors..  PLoS One,  (9): (e45072).  [PMID:23028768]
65. Lanore F et al..  (2010)  Impaired development of hippocampal mossy fibre synapses in mouse mutants for the presynaptic scaffold protein Bassoon..  J Physiol,  588  (Pt 12): (2133-45).  [PMID:20421286]
66. Fekete CD et al..  (2017)  In vivo transgenic expression of collybistin in neurons of the rat cerebral cortex..  J Comp Neurol,  525  (5): (1291-1311).  [PMID:27804142]
67. Ermolyuk YS et al..  (2012)  Independent regulation of Basal neurotransmitter release efficacy by variable Ca²+ influx and bouton size at small central synapses..  PLoS Biol,  10  (9): (e1001396).  [PMID:23049481]
68. Gan J et al..  (2011)  Indirect modulation of neuronal excitability and synaptic transmission in the hippocampus by activation of proteinase-activated receptor-2..  Br J Pharmacol,  163  (5): (984-94).  [PMID:21366553]
69. Lalchandani RR & Vicini S.  (2013)  Inhibitory collaterals in genetically identified medium spiny neurons in mouse primary corticostriatal cultures..  Physiol Rep,  (6): (e00164).  [PMID:24400165]
70. Le Roux N et al..  (2013)  Input-specific learning rules at excitatory synapses onto hippocampal parvalbumin-expressing interneurons..  J Physiol,  591  (Pt 7): (1809-22).  [PMID:23339172]
71. Chiu CQ & Castillo PE.  (2008)  Input-specific plasticity at excitatory synapses mediated by endocannabinoids in the dentate gyrus..  Neuropharmacology,  54  (68-78).  [PMID:17706254]
72. Zurita H et al..  (2018)  Layer 5 Callosal Parvalbumin-Expressing Neurons: A Distinct Functional Group of GABAergic Neurons..  Front Cell Neurosci,  12  (53).  [PMID:29559891]
73. Colavita M et al..  (2016)  Layer-specific potentiation of network GABAergic inhibition in the CA1 area of the hippocampus..  Sci Rep,  (28454).  [PMID:27345695]
74. Chamberlain SE et al..  (2013)  Long-term depression of synaptic kainate receptors reduces excitability by relieving inhibition of the slow afterhyperpolarization..  J Neurosci,  33  (22): (9536-45).  [PMID:23719820]
75. Borisovska M et al..  (2011)  Loss of olfactory cell adhesion molecule reduces the synchrony of mitral cell activity in olfactory glomeruli..  J Physiol,  589  (Pt 8): (1927-41).  [PMID:21486802]
76. Mast TG & Fadool DA.  (2012)  Mature and precursor brain-derived neurotrophic factor have individual roles in the mouse olfactory bulb..  PLoS One,  (2): (e31978).  [PMID:22363780]
77. Trapani JG & Nicolson T.  (2011)  Mechanism of spontaneous activity in afferent neurons of the zebrafish lateral-line organ..  J Neurosci,  31  (5): (1614-23).  [PMID:21289170]
78. Zhao Y et al..  (2011)  Mechanisms underlying input-specific expression of endocannabinoid-mediated synaptic plasticity in the dorsal cochlear nucleus..  Hear Res,  279  (1-2): (67-73).  [PMID:21426926]
79. Kitko KE et al..  (2018)  Membrane cholesterol mediates the cellular effects of monolayer graphene substrates..  Nat Commun,  (796).  [PMID:29476054]
80. Cosgrove KE & Maccaferri G.  (2012)  mGlu1a-dependent recruitment of excitatory GABAergic input to neocortical Cajal-Retzius cells..  Neuropharmacology,  63  (3): (486-93).  [PMID:22579657]
81. Lu C et al..  (2015)  Micro-electrode array recordings reveal reductions in both excitation and inhibition in cultured cortical neuron networks lacking Shank3..  Mol Psychiatry,  [PMID:26598066]
82. Fadool DA et al..  (2011)  Mitral cells of the olfactory bulb perform metabolic sensing and are disrupted by obesity at the level of the Kv1.3 ion channel..  PLoS One,  (9): (e24921).  [PMID:21966386]
83. Roberts MT & Trussell LO.  (2010)  Molecular layer inhibitory interneurons provide feedforward and lateral inhibition in the dorsal cochlear nucleus..  J Neurophysiol,  104  (5): (2462-73).  [PMID:20719922]
84. Soto D et al..  (2014)  Molecular Mechanisms Contributing to TARP Regulation of Channel Conductance and Polyamine Block of Calcium-Permeable AMPA Receptors..  J Neurosci,  34  (35): (11673-83).  [PMID:25164663]
85. Najac M et al..  (2011)  Monosynaptic and polysynaptic feed-forward inputs to mitral cells from olfactory sensory neurons..  J Neurosci,  31  (24): (8722-9).  [PMID:21677156]
86. Jo J et al..  (2010)  Muscarinic receptors induce LTD of NMDAR EPSCs via a mechanism involving hippocalcin, AP2 and PSD-95..  Nat Neurosci,  13  (10): (1216-24).  [PMID:20852624]
87. Tang AH et al..  (2011)  Nerve terminal nicotinic acetylcholine receptors initiate quantal GABA release from perisomatic interneurons by activating axonal T-type (Cav3) Ca²? channels and Ca²? release from stores..  J Neurosci,  31  (38): (13546-61).  [PMID:21940446]
88. Du H et al..  (2013)  Neuregulin-1 impairs the long-term depression of hippocampal inhibitory synapses by facilitating the degradation of endocannabinoid 2-AG..  J Neurosci,  33  (38): (15022-31).  [PMID:24048832]
89. Doengi M et al..  (2008)  New evidence for purinergic signaling in the olfactory bulb: A2A and P2Y1 receptors mediate intracellular calcium release in astrocytes..  FASEB J,  22  (7): (2368-78).  [PMID:18310463]
90. Pugh JR & Jahr CE.  (2011)  NMDA receptor agonists fail to alter release from cerebellar basket cells..  J Neurosci,  31  (46): (16550-5).  [PMID:22090481]
91. Quattrocolo G & Maccaferri G.  (2013)  Novel GABAergic circuits mediating excitation/inhibition of Cajal-Retzius cells in the developing hippocampus..  J Neurosci,  33  (13): (5486-98).  [PMID:23536064]
92. Lafourcade CA et al..  (2009)  Novel mGluR- and CB1R-independent suppression of GABA release caused by a contaminant of the group I metabotropic glutamate receptor agonist, DHPG..  PLoS One,  (7): (e6122).  [PMID:19568435]
93. Barker GR & Warburton EC.  (2013)  Object-in-Place Associative Recognition Memory Depends on Glutamate Receptor Neurotransmission Within Two Defined Hippocampal-Cortical Circuits: A Critical Role for AMPA and NMDA Receptors in the Hippocampus, Perirhinal, and Prefrontal Cortices..  Cereb Cortex,  [PMID:24035904]
94. Kaplan JS et al..  (2013)  Opposite actions of alcohol on tonic GABAA receptor currents mediated by nNOS and PKC activity..  Nat Neurosci,  16  (12): (1783-93).  [PMID:24162656]
95. Nagode DA et al..  (2011)  Optogenetic release of ACh induces rhythmic bursts of perisomatic IPSCs in hippocampus..  PLoS One,  (11): (e27691).  [PMID:22110723]
96. Lu C et al..  (2019)  Overexpression of NEUROG2 and NEUROG1 in human embryonic stem cells produces a network of excitatory and inhibitory neurons..  FASEB J,  33  (4): (5287-5299).  [PMID:30698461]
97. Owen SF et al..  (2013)  Oxytocin enhances hippocampal spike transmission by modulating fast-spiking interneurons..  Nature,  500  (7463): (458-62).  [PMID:23913275]
98. Fischer T et al..  (2012)  P2Y1 receptor activation by photolysis of caged ATP enhances neuronal network activity in the developing olfactory bulb..  Purinergic Signal,  (2): (191-8).  [PMID:22187118]
99. Vaden RJ et al..  (2020)  Parvalbumin interneurons provide spillover to newborn and mature dentate granule cells..  Elife,  [PMID:32602839]
100. Li S et al..  (2013)  Pathogenic plasticity of Kv7.2/3 channel activity is essential for the induction of tinnitus..  Proc Natl Acad Sci U S A,  110  (24): (9980-5).  [PMID:23716673]
101. Montalbano A et al..  (2015)  Pharmacological Characterization of 5-HT1A Autoreceptor-Coupled GIRK Channels in Rat Dorsal Raphe 5-HT Neurons..  PLoS One,  10  (10): (e0140369).  [PMID:26460748]
102. Balia M et al..  (2015)  Postnatal down-regulation of the GABAA receptor ?2 subunit in neocortical NG2 cells accompanies synaptic-to-extrasynaptic switch in the GABAergic transmission mode..  Cereb Cortex,  25  (4): (1114-23).  [PMID:24217990]
103. Leroy F et al..  (2015)  Potassium currents dynamically set the recruitment and firing properties of F-type motoneurons in neonatal mice..  J Neurophysiol,  114  (3): (1963-73).  [PMID:26269551]
104. Habbas S et al..  (2011)  Purinergic signaling in the cerebellum: Bergmann glial cells express functional ionotropic P2X7 receptors..  Glia,  59  (12): (1800-12).  [PMID:21830236]
105. Apostolides PF & Trussell LO.  (2013)  Rapid, activity-independent turnover of vesicular transmitter content at a mixed glycine/GABA synapse..  J Neurosci,  33  (11): (4768-81).  [PMID:23486948]
106. Avrabos C et al..  (2013)  Real-time imaging of amygdalar network dynamics in vitro reveals a neurophysiological link to behavior in a mouse model of extremes in trait anxiety..  J Neurosci,  33  (41): (16262-7).  [PMID:24107957]
107. McLeod F et al..  (2013)  Reduced seizure threshold and altered network oscillatory properties in a mouse model of Rett syndrome..  Neuroscience,  231  (195-205).  [PMID:23238573]
108. Kim J & Alger BE.  (2010)  Reduction in endocannabinoid tone is a homeostatic mechanism for specific inhibitory synapses..  Nat Neurosci,  13  (5): (592-600).  [PMID:20348918]
109. Khubieh A et al..  (2016)  Regulation of Cortical Dynamic Range by Background Synaptic Noise and Feedforward Inhibition..  Cereb Cortex,  26  (8): (3357-69).  [PMID:26209846]
110. Yekhlef L et al..  (2015)  Selective activation of parvalbumin- or somatostatin-expressing interneurons triggers epileptic seizurelike activity in mouse medial entorhinal cortex..  J Neurophysiol,  113  (5): (1616-30).  [PMID:25505119]
111. Tang ZQ & Trussell LO.  (2015)  Serotonergic regulation of excitability of principal cells of the dorsal cochlear nucleus..  J Neurosci,  35  (11): (4540-51).  [PMID:25788672]
112. Andrade AL & Rossi DJ.  (2010)  Simulated ischaemia induces Ca2+-independent glutamatergic vesicle release through actin filament depolymerization in area CA1 of the hippocampus..  J Physiol,  588  (Pt 9): (1499-514).  [PMID:20211977]
113. Balakrishnan V et al..  (2009)  Slow glycinergic transmission mediated by transmitter pooling..  Nat Neurosci,  12  (3): (286-94).  [PMID:19198604]
114. Tonini R et al..  (2013)  Small-conductance Ca2+-activated K+ channels modulate action potential-induced Ca2+ transients in hippocampal neurons..  J Neurophysiol,  109  (6): (1514-24).  [PMID:23255726]
115. Weigel S & Luksch H.  (2012)  Spatiotemporal analysis of electrically evoked activity in the chicken optic tectum: a VSDI study..  J Neurophysiol,  107  (2): (640-8).  [PMID:22031774]
116. Kuo SP & Trussell LO.  (2011)  Spontaneous spiking and synaptic depression underlie noradrenergic control of feed-forward inhibition..  Neuron,  71  (2): (306-18).  [PMID:21791289]
117. Bock R et al..  (2013)  Strengthening the accumbal indirect pathway promotes resilience to compulsive cocaine use..  Nat Neurosci,  16  (5): (632-8).  [PMID:23542690]
118. Apostolides PF & Trussell LO.  (2014)  Superficial stellate cells of the dorsal cochlear nucleus..  Front Neural Circuits,  (63).  [PMID:24959121]
119. Chamberland S et al..  (2010)  Synapse-specific inhibitory control of hippocampal feedback inhibitory circuit..  Front Cell Neurosci,  (130).  [PMID:21060720]
120. Brown JT et al..  (2011)  Synaptic activation of mGluR1 generates persistent depression of a fast after-depolarizing potential in CA3 pyramidal neurons..  Eur J Neurosci,  33  (5): (879-89).  [PMID:21269340]
121. Kaeser-Woo YJ et al..  (2013)  Synaptotagmin-12 phosphorylation by cAMP-dependent protein kinase is essential for hippocampal mossy fiber LTP..  J Neurosci,  33  (23): (9769-80).  [PMID:23739973]
122. Lenda F et al..  (2011)  Synthesis of C5-tetrazole derivatives of 2-amino-adipic acid displaying NMDA glutamate receptor antagonism..  Amino Acids,  40  (3): (913-22).  [PMID:20706748]
123. Beckley JT & Woodward JJ.  (2011)  The abused inhalant toluene differentially modulates excitatory and inhibitory synaptic transmission in deep-layer neurons of the medial prefrontal cortex..  Neuropsychopharmacology,  36  (7): (1531-42).  [PMID:21430649]
124. Marchionni I et al..  (2012)  The chemokine CXCL12 and the HIV-1 envelope protein gp120 regulate spontaneous activity of Cajal-Retzius cells in opposite directions..  J Physiol,  590  (13): (3185-202).  [PMID:22473778]
125. Che A et al..  (2013)  The Dyslexia-Associated Gene Dcdc2 Is Required for Spike-Timing Precision in Mouse Neocortex..  Biol Psychiatry,  [PMID:24094509]
126. Vaden JH et al..  (2019)  The readily-releasable pool dynamically regulates multivesicular release..  Elife,  [PMID:31364987]
127. Bertollini C et al..  (2012)  Transient increase in neuronal chloride concentration by neuroactive aminoacids released from glioma cells..  Front Mol Neurosci,  (100).  [PMID:23189038]
128. Tovar KR et al..  (2013)  Triheteromeric NMDA receptors at hippocampal synapses..  J Neurosci,  33  (21): (9150-60).  [PMID:23699525]
129. Garden DL et al..  (2008)  Tuning of synaptic integration in the medial entorhinal cortex to the organization of grid cell firing fields..  Neuron,  60  (5): (875-89).  [PMID:19081381]
130. Bazelot M et al..  (2010)  Unitary inhibitory field potentials in the CA3 region of rat hippocampus..  J Physiol,  588  (Pt 12): (2077-90).  [PMID:20403979]
131. Brady JD et al..  (2010)  Vesicular GABA release delays the onset of the Purkinje cell terminal depolarization without affecting tissue swelling in cerebellar slices during simulated ischemia..  Neuroscience,  168  (108-17).  [PMID:20226232]
132. Mohr C et al..  (2010)  Young age and low temperature, but not female gender delay ATP loss and glutamate release, and protect Purkinje cells during simulated ischemia in cerebellar slices..  Neuropharmacology,  58  (2): (392-403).  [PMID:19825379]

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