Molecular correlates of renal function in kidney transplant biopsies
about
What is the best way to measure renal fibrosis?: A pathologist’s perspectiveDendritic cells and macrophages in the kidney: a spectrum of good and evilAssessing the human immune system through blood transcriptomics.Gene Expression in Biopsies of Acute Rejection and Interstitial Fibrosis/Tubular Atrophy Reveals Highly Shared Mechanisms That Correlate With Worse Long-Term Outcomes.Recent advances in renal interstitial fibrosis and tubular atrophy after kidney transplantation.Fibrosis with inflammation at one year predicts transplant functional decline.Novel diagnostics in renal transplantation.A randomized 2×2 factorial trial, part 1: single-dose rabbit antithymocyte globulin induction may improve renal transplantation outcomes.Gene expression profiling in acute allograft rejection: challenging the immunologic constant of rejection hypothesis.Phosphoinositide binding differentially regulates NHE1 Na+/H+ exchanger-dependent proximal tubule cell survivalIdentification of human epididymis protein-4 as a fibroblast-derived mediator of fibrosisMolecular Markers of Tubulointerstitial Fibrosis and Tubular Cell Damage in Patients with Chronic Kidney DiseaseDetecting adaptive immunity: applications in transplantation monitoring.Molecular pathways involved in loss of graft function in kidney transplant recipients.Contribution of epithelial plasticity to renal transplantation-associated fibrosis.Assessment of kidney organ quality and prediction of outcome at time of transplantation.Toxicity spectrum of inhibitors of mammalian target of rapamycin in organ transplantation: etiology, pathogenesis and treatment.Tubular atrophy in the pathogenesis of chronic kidney disease progression.Physiopathological factors affecting the diagnostic value of serum HE4-test for gynecologic malignancies.Molecular phenotypes of acute kidney injury in kidney transplants.The molecular phenotype of 6-week protocol biopsies from human renal allografts: reflections of prior injury but not future course.A molecular classifier for predicting future graft loss in late kidney transplant biopsiesPrecision Subtypes of T Cell-Mediated Rejection Identified by Molecular Profiles.Single-dose rATG induction at renal transplantation: superior renal function and glucoregulation with less hypomagnesemia.Genetics of acute rejection after kidney transplantation.Early introduction of oral paricalcitol in renal transplant recipients. An open-label randomized study.Polyomavirus BK Nephropathy-Associated Transcriptomic Signatures: A Critical Reevaluation.Early Macrophage Infiltration and Sustained Inflammation in Kidneys From Deceased Donors Are Associated With Long-Term Renal Function.Validation of systems biology derived molecular markers of renal donor organ status associated with long term allograft function.
P2860
Q26796641-1241F0C7-48EA-4B65-875A-439489051D3DQ27023506-2ED52FE4-F09F-40A0-AAE3-501560AC86B9Q33629522-3037C508-2EFF-441D-8ACA-91881BD2EC84Q33885388-87CD83F3-22AC-4B46-B010-9D7C4AD960A0Q34289498-128C9BEA-2AD0-4063-A033-CD129ED445F0Q34457101-80B5554C-7116-488E-BAA1-2919FF1491A5Q34503698-9F9E48AC-3749-40B0-B958-CC50A2AA177DQ34796915-E0489D05-6A12-4436-BC02-012BDCFDF0B6Q35541507-A55041A2-F1CE-4877-9771-DAE5C5DC49C0Q35604890-371B2460-CAC4-4721-8F74-8836DEC83F99Q35688448-CBA24BD5-AF1C-40E9-B2F4-9EAB64ACF4A5Q35759059-E0D65D62-02EA-4886-BDE6-CACE22A10219Q37685073-12E445EA-FA44-4D88-AA33-5B6BE3080C36Q37724869-8D31373A-C002-49C8-85DA-0A5EF6972882Q37811517-4B2C361D-B7C9-4579-85D7-7723619A4BC1Q37832966-976E1A00-E7F0-43E2-8817-41F62133A34DQ37873950-2C894838-9C1D-4420-8160-66AB7CDF63FDQ38553671-D6D5F774-A3DF-4AD3-9359-1252E75CFDDEQ38991579-1C5B707D-4556-44AA-B648-45BE29990390Q39651276-AA6610A5-A9BD-498B-AF90-00476730B6B9Q39812222-463734E5-61CF-40B0-9B7D-55DAC4C512C1Q39869686-183E101B-EE60-491A-9F67-985F2C3284A4Q40289674-C151051D-259A-447F-BB07-DEDA384B53ECQ43485090-389EDFBB-62EC-4310-8268-54265895549EQ47898148-E8016FDE-ECE7-4607-B9AA-B00508B628B9Q48242270-5B4B19EF-84E0-4A36-8F4A-FAFA55FA10BDQ49724104-27ABF1F1-3825-4064-BFD9-6078B20E4CB9Q53055638-C9237A5A-448E-462C-8C86-68589B61923FQ55080066-4777B435-DE9B-453D-BA23-5C6A9AE25788
P2860
Molecular correlates of renal function in kidney transplant biopsies
description
2009 nî lūn-bûn
@nan
2009年の論文
@ja
2009年学术文章
@wuu
2009年学术文章
@zh-cn
2009年学术文章
@zh-hans
2009年学术文章
@zh-my
2009年学术文章
@zh-sg
2009年學術文章
@yue
2009年學術文章
@zh
2009年學術文章
@zh-hant
name
Molecular correlates of renal function in kidney transplant biopsies
@en
Molecular correlates of renal function in kidney transplant biopsies
@nl
type
label
Molecular correlates of renal function in kidney transplant biopsies
@en
Molecular correlates of renal function in kidney transplant biopsies
@nl
prefLabel
Molecular correlates of renal function in kidney transplant biopsies
@en
Molecular correlates of renal function in kidney transplant biopsies
@nl
P2093
P2860
P356
P1476
Molecular correlates of renal function in kidney transplant biopsies
@en
P2093
Bruce Kaplan
Daniel Kayser
Gian S Jhangri
Gunilla Einecke
Jeff Reeve
Luis G Hidalgo
Michael Mengel
Sakarn Bunnag
Thomas F Mueller
P2860
P304
P356
10.1681/ASN.2008080863
P577
2009-04-23T00:00:00Z