Gene expression profiling of mouse bladder inflammatory responses to LPS, substance P, and antigen-stimulation.
about
Inhibition of the cation channel TRPV4 improves bladder function in mice and rats with cyclophosphamide-induced cystitisBeta-adrenergic receptor activation in immortalized human urothelial cells stimulates inflammatory responses by PKA-independent mechanisms.The inflammatory and normal transcriptome of mouse bladder detrusor and mucosaAngiogenic factors, bladder neuroplasticity and interstitial cystitis-new pathobiological insightsTransgenic Mice Expressing MCP-1 by the Urothelium Demonstrate Bladder Hypersensitivity, Pelvic Pain and Voiding Dysfunction: A Multidisciplinary Approach to the Study of Chronic Pelvic Pain Research Network Animal Model StudyUpregulation of macrophage migration inhibitory factor (MIF) and CD74, receptor for MIF, in rat bladder during persistent cyclophosphamide-induced inflammationCorticotropin-releasing factor (CRF) expression in postnatal and adult rat sacral parasympathetic nucleus (SPN).Regulatory network of inflammation downstream of proteinase-activated receptorsMandatory role of proteinase-activated receptor 1 in experimental bladder inflammationDiscriminators of mouse bladder response to intravesical Bacillus Calmette-Guerin (BCG).Bladder inflammatory transcriptome in response to tachykinins: neurokinin 1 receptor-dependent genes and transcription regulatory elementsTranscription factor network downstream of protease activated receptors (PARs) modulating mouse bladder inflammation.Repeated BCG treatment of mouse bladder selectively stimulates small GTPases and HLA antigens and inhibits single-spanning uroplakins.Molecular networks discriminating mouse bladder responses to intravesical bacillus Calmette-Guerin (BCG), LPS, and TNF-alpha.MicroRNAs may mediate the down-regulation of neurokinin-1 receptor in chronic bladder pain syndromePresenilin 2 is the predominant γ-secretase in microglia and modulates cytokine releaseCorticotropin-releasing factor family peptide signaling in feline bladder urothelial cells.Corticotropin-releasing hormone-receptor 2 is required for acute stress-induced bladder vascular permeability and release of vascular endothelial growth factor.Effect of Treadmill Exercise on Leak-point pressure and Neuronal Activation in Brain of Rats with Stress Urinary Incontinence.VEGF induces sensory and motor peripheral plasticity, alters bladder function, and promotes visceral sensitivity.Presenilin 2 influences miR146 level and activity in microglia.Expression of protease-activated receptor-1, -2, -3, and -4 in control and experimentally inflamed mouse bladder.Biology and chemistry of the inhibition of nitric oxide synthases by pteridine-derivatives as therapeutic agents.Linkage of cardiac gene expression profiles and ETS2 with lifespan variability in ratsChronic prostatitis and sensory urgency: whose pain is it?Cell type-specific analyses for identifying prostate cancer biomarkers.Protamine sulfate induced bladder injury protects from distention induced bladder painPostnatal expression of corticotropin releasing factor (CRF) in rat urinary bladderWhat's new in the diagnosis and management of painful bladder syndrome/interstitial cystitis?Chronic pelvic pain syndrome and the overactive bladder: the inflammatory link.Expressions of uroplakins in the mouse urinary bladder with cyclophosphamide-induced cystitis.A murine model of inflammatory bladder disease: cathelicidin peptide induced bladder inflammation and treatment with sulfated polysaccharidesThe relationship between sexual abuse and interstitial cystitis/painful bladder syndrome.Physiological relevance of LL-37 induced bladder inflammation and mast cells.Nerve growth factor in bladder dysfunction: contributing factor, biomarker, and therapeutic target.Functional annotation of a novel NFKB1 promoter polymorphism that increases risk for ulcerative colitis.Synergism between fibronectin and transforming growth factor-β1 in the production of substance P in monocytes of patients with myelofibrosis.Novel in vitro model for studying ureteric stent-induced cell injury.Afferent Pathway-Mediated Effect of α1 Adrenergic Antagonist, Tamsulosin, on the Neurogenic Bladder After Spinal Cord Injury.Neurokinin 1 receptors and neprilysin modulation of mouse bladder gene regulation.
P2860
Q24614844-EFC50B1B-FDA8-49D4-AFBC-A2C356235B5BQ24810781-A40345F1-6213-42A7-974D-96FB7B31DC60Q25257408-9F7373EB-A63D-471D-BEA4-BE036E5A4F4DQ26773577-39AEE599-798D-4376-9778-0BC2A1A74C0AQ28554395-06D02647-FA63-439B-B4DA-A3E89A0CFEEDQ28564410-C89C2320-42D5-4BDC-A1BD-A2ED6A1759B4Q33218366-57EBD069-BB88-4906-8342-99EA9B7E39FAQ33280659-86AF1098-B45B-47A1-B61A-3FE9A61DDC24Q33280660-8F3A56C2-8CFD-48C5-B565-A924EA8CA749Q33284823-E5A41636-9B7C-412F-A855-193830EC5376Q33285436-53B3340A-5BAA-4285-A5E5-6D66BC89A2F8Q33294523-0B66BE3E-67F1-4D43-993C-646F4CF7A001Q33304879-63EAB2B6-F6C4-4D0B-B585-E3B33D60DA4CQ33319305-733F0353-CEC0-49B2-9EB9-B212E92B8FB8Q33556343-7C854FB1-5D0E-4080-A554-768FA9F3F776Q33785755-852422C6-FFC9-4CC3-85EA-55FE1F2B1D8BQ34065104-5782C21A-DCC5-413B-9D7D-D5B7065C4CF8Q34101997-2BAC79D6-9E6A-4243-872D-529E52C78D58Q34387401-C9B2EB44-93F4-42E7-A30B-8534D8FCEEDAQ34515175-8756B5ED-CD98-41DC-B541-D789B1F35332Q35137238-758D087C-F18E-498E-BA97-15ECDD3655E1Q35791283-6F7879DA-DDC5-4A03-8F1B-308C4C65A39EQ35821459-ED6AFDA7-5D50-44D6-A2BC-8F4A6DA04CEFQ35836377-F49AA1F9-7CAC-4131-BA41-1C7040DF6BE2Q35947432-2695B9AC-80A7-466C-8A30-DBD75890C23EQ36397442-A414317D-2A36-479F-8EFD-33E2EE7F5E19Q36870724-E8AEC7B4-B4E7-4694-B023-56F096E796DAQ36942368-83680FDC-8F7F-4A87-8735-90CB8AADACD3Q37243393-021A0B31-6181-4643-A120-8E80D41843DEQ37258893-C7214ED8-E90D-4B80-902C-2ED5A9D9BA0FQ37284704-D761801F-1249-4CFD-B507-B85C7FFD01DAQ37458645-C948E0B6-CDCB-4617-AFDF-7D7596B06970Q37623089-150590A4-B4B9-44FE-BCF8-8FD186062887Q37627413-782DC8FF-057F-4937-BA17-4BF11774DDFCQ37869049-13914479-5B04-4E4F-B217-7052F05BDACDQ38348120-849AE3F6-AFD6-4F1D-8CD2-FD87D8E8EF4EQ39294566-1ED539E9-8ED5-4C69-B8EA-DFEA84BF1663Q39779114-B5AD6835-CB43-4319-A70A-59457B69F2A7Q42261494-1AFCB3EC-9FB0-4D79-B32F-EE3A0366D42FQ44260498-93C51D62-390D-4C89-AD66-B3DE455C3A66
P2860
Gene expression profiling of mouse bladder inflammatory responses to LPS, substance P, and antigen-stimulation.
description
2002 nî lūn-bûn
@nan
2002年の論文
@ja
2002年論文
@yue
2002年論文
@zh-hant
2002年論文
@zh-hk
2002年論文
@zh-mo
2002年論文
@zh-tw
2002年论文
@wuu
2002年论文
@zh
2002年论文
@zh-cn
name
Gene expression profiling of m ...... ce P, and antigen-stimulation.
@ast
Gene expression profiling of m ...... ce P, and antigen-stimulation.
@en
type
label
Gene expression profiling of m ...... ce P, and antigen-stimulation.
@ast
Gene expression profiling of m ...... ce P, and antigen-stimulation.
@en
prefLabel
Gene expression profiling of m ...... ce P, and antigen-stimulation.
@ast
Gene expression profiling of m ...... ce P, and antigen-stimulation.
@en
P2093
P2860
P1476
Gene expression profiling of m ...... ce P, and antigen-stimulation.
@en
P2093
Marcia R Saban
Ngoc-Bich Nguyen
Ricardo Saban
Timothy G Hammond
P2860
P304
P356
10.1016/S0002-9440(10)61159-5
P407
P577
2002-06-01T00:00:00Z