GFR Slope as a Surrogate End Point for Kidney Disease Progression in Clinical Trials: A Meta-Analysis of Treatment Effects of Randomized Controlled Trials

Surrogate end points are needed to assess whether treatments are effective in the early stages of CKD. GFR decline leads to kidney failure, but regulators have not approved using differences in the change in GFR from the beginning to the end of a randomized, controlled trial as an end point in CKD b...

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Published inJournal of the American Society of Nephrology Vol. 30; no. 9; pp. 1735 - 1745
Main Authors Inker, Lesley A., Heerspink, Hiddo J. L., Tighiouart, Hocine, Levey, Andrew S., Coresh, Josef, Gansevoort, Ron T., Simon, Andrew L., Ying, Jian, Beck, Gerald J., Wanner, Christoph, Floege, Jürgen, Li, Philip Kam-Tao, Perkovic, Vlado, Vonesh, Edward F., Greene, Tom
Format Journal Article
LanguageEnglish
Published United States American Society of Nephrology 01.09.2019
Subjects
Bayes Theorem
Biomarkers
Creatinine - blood
Disease Progression
Glomerular Filtration Rate
Humans
Kidney Failure, Chronic - etiology
Kidney Failure, Chronic - physiopathology
Meta-Analysis
Predictive Value of Tests
Randomized Controlled Trials as Topic
Renal Insufficiency, Chronic - complications
Renal Insufficiency, Chronic - physiopathology
Renal Insufficiency, Chronic - therapy
meta-analysis
GFR
chronic kidney disease
end stage kidney disease
randomized controlled trials
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Abstract Surrogate end points are needed to assess whether treatments are effective in the early stages of CKD. GFR decline leads to kidney failure, but regulators have not approved using differences in the change in GFR from the beginning to the end of a randomized, controlled trial as an end point in CKD because it is not clear whether small changes in the GFR slope will translate to clinical benefits. To assess the use of GFR slope as a surrogate end point for CKD progression, we performed a meta-analysis of 47 RCTs that tested 12 interventions in 60,620 subjects. We estimated treatment effects on GFR slope (mean difference in GFR slope between the randomized groups), for the total slope starting at baseline, chronic slope starting at 3 months after randomization, and on the clinical end point (doubling of serum creatinine, GFR<15 ml/min per 1.73 m , or ESKD) for each study. We used Bayesian mixed-effects analyses to describe the association of treatment effects on GFR slope with the clinical end point and to test how well the GFR slope predicts a treatment's effect on the clinical end point. Across all studies, the treatment effect on 3-year total GFR slope (median =0.97; 95% Bayesian credible interval [BCI], 0.78 to 1.00) and on the chronic slope ( 0.96; 95% BCI, 0.63 to 1.00) accurately predicted treatment effects on the clinical end point. With a sufficient sample size, a treatment effect of 0.75 ml/min per 1.73 m /yr or greater on total slope over 3 years or chronic slope predicts a clinical benefit on CKD progress with at least 96% probability. With large enough sample sizes, GFR slope may be a viable surrogate for clinical end points in CKD RCTs.
AbstractList Surrogate end points are needed to assess whether treatments are effective in the earlier stages of CKD. Measuring the effects of treatments on GFR decline, which leads to kidney failure, might be one way to identify early benefits of CKD treatments. So far regulators have not approved the use of GFR slope, the difference in the change in GFR between treatment groups over time, as an end point in CKD randomized, controlled trials because they are concerned that small treatment effects on GFR may not translate into meaningful clinical benefits. Using a Bayesian individual patient meta-analysis of 47 studies including 60,620 participants, the authors found, that for sufficiently large studies, treatment effects on GFR slope from baseline and from 3-month follow-up of 0.5–1.0 ml/min per 1.73 m 2 /yr strongly predict benefits on clinical end points such as doubling of serum creatinine, GFR<15 ml/min per 1.73 m 2 , or ESKD. GFR slope can play a useful role as a surrogate end point for CKD progression in clinical trials.
Surrogate end points are needed to assess whether treatments are effective in the early stages of CKD. GFR decline leads to kidney failure, but regulators have not approved using differences in the change in GFR from the beginning to the end of a randomized, controlled trial as an end point in CKD because it is not clear whether small changes in the GFR slope will translate to clinical benefits.BACKGROUNDSurrogate end points are needed to assess whether treatments are effective in the early stages of CKD. GFR decline leads to kidney failure, but regulators have not approved using differences in the change in GFR from the beginning to the end of a randomized, controlled trial as an end point in CKD because it is not clear whether small changes in the GFR slope will translate to clinical benefits.To assess the use of GFR slope as a surrogate end point for CKD progression, we performed a meta-analysis of 47 RCTs that tested 12 interventions in 60,620 subjects. We estimated treatment effects on GFR slope (mean difference in GFR slope between the randomized groups), for the total slope starting at baseline, chronic slope starting at 3 months after randomization, and on the clinical end point (doubling of serum creatinine, GFR<15 ml/min per 1.73 m2, or ESKD) for each study. We used Bayesian mixed-effects analyses to describe the association of treatment effects on GFR slope with the clinical end point and to test how well the GFR slope predicts a treatment's effect on the clinical end point.METHODSTo assess the use of GFR slope as a surrogate end point for CKD progression, we performed a meta-analysis of 47 RCTs that tested 12 interventions in 60,620 subjects. We estimated treatment effects on GFR slope (mean difference in GFR slope between the randomized groups), for the total slope starting at baseline, chronic slope starting at 3 months after randomization, and on the clinical end point (doubling of serum creatinine, GFR<15 ml/min per 1.73 m2, or ESKD) for each study. We used Bayesian mixed-effects analyses to describe the association of treatment effects on GFR slope with the clinical end point and to test how well the GFR slope predicts a treatment's effect on the clinical end point.Across all studies, the treatment effect on 3-year total GFR slope (median R2=0.97; 95% Bayesian credible interval [BCI], 0.78 to 1.00) and on the chronic slope (R2 0.96; 95% BCI, 0.63 to 1.00) accurately predicted treatment effects on the clinical end point. With a sufficient sample size, a treatment effect of 0.75 ml/min per 1.73 m2/yr or greater on total slope over 3 years or chronic slope predicts a clinical benefit on CKD progress with at least 96% probability.RESULTSAcross all studies, the treatment effect on 3-year total GFR slope (median R2=0.97; 95% Bayesian credible interval [BCI], 0.78 to 1.00) and on the chronic slope (R2 0.96; 95% BCI, 0.63 to 1.00) accurately predicted treatment effects on the clinical end point. With a sufficient sample size, a treatment effect of 0.75 ml/min per 1.73 m2/yr or greater on total slope over 3 years or chronic slope predicts a clinical benefit on CKD progress with at least 96% probability.With large enough sample sizes, GFR slope may be a viable surrogate for clinical end points in CKD RCTs.CONCLUSIONSWith large enough sample sizes, GFR slope may be a viable surrogate for clinical end points in CKD RCTs.
Surrogate end points are needed to assess whether treatments are effective in the early stages of CKD. GFR decline leads to kidney failure, but regulators have not approved using differences in the change in GFR from the beginning to the end of a randomized, controlled trial as an end point in CKD because it is not clear whether small changes in the GFR slope will translate to clinical benefits. To assess the use of GFR slope as a surrogate end point for CKD progression, we performed a meta-analysis of 47 RCTs that tested 12 interventions in 60,620 subjects. We estimated treatment effects on GFR slope (mean difference in GFR slope between the randomized groups), for the total slope starting at baseline, chronic slope starting at 3 months after randomization, and on the clinical end point (doubling of serum creatinine, GFR<15 ml/min per 1.73 m , or ESKD) for each study. We used Bayesian mixed-effects analyses to describe the association of treatment effects on GFR slope with the clinical end point and to test how well the GFR slope predicts a treatment's effect on the clinical end point. Across all studies, the treatment effect on 3-year total GFR slope (median =0.97; 95% Bayesian credible interval [BCI], 0.78 to 1.00) and on the chronic slope ( 0.96; 95% BCI, 0.63 to 1.00) accurately predicted treatment effects on the clinical end point. With a sufficient sample size, a treatment effect of 0.75 ml/min per 1.73 m /yr or greater on total slope over 3 years or chronic slope predicts a clinical benefit on CKD progress with at least 96% probability. With large enough sample sizes, GFR slope may be a viable surrogate for clinical end points in CKD RCTs.
Author Wanner, Christoph
Inker, Lesley A.
Perkovic, Vlado
Greene, Tom
Coresh, Josef
Ying, Jian
Floege, Jürgen
Simon, Andrew L.
Heerspink, Hiddo J. L.
Tighiouart, Hocine
Levey, Andrew S.
Vonesh, Edward F.
Beck, Gerald J.
Gansevoort, Ron T.
Li, Philip Kam-Tao
Author_xml – sequence: 1
  givenname: Lesley A.
  surname: Inker
  fullname: Inker, Lesley A.
  organization: Division of Nephrology and
– sequence: 2
  givenname: Hiddo J. L.
  surname: Heerspink
  fullname: Heerspink, Hiddo J. L.
  organization: Clinical Pharmacy and Pharmacology and
– sequence: 3
  givenname: Hocine
  surname: Tighiouart
  fullname: Tighiouart, Hocine
  organization: The Institute for Clinical Research and Health Policy Studies, Tufts Medical Center, Boston, Massachusetts;, Tufts Clinical and Translational Science Institute, Tufts University, Boston, Massachusetts
– sequence: 4
  givenname: Andrew S.
  surname: Levey
  fullname: Levey, Andrew S.
  organization: Division of Nephrology and
– sequence: 5
  givenname: Josef
  surname: Coresh
  fullname: Coresh, Josef
  organization: Department of Epidemiology, Johns Hopkins Bloomberg School of Public Health, Baltimore, Maryland
– sequence: 6
  givenname: Ron T.
  surname: Gansevoort
  fullname: Gansevoort, Ron T.
  organization: Nephrology, University Medical Center Groningen, University of Groningen, Groningen, The Netherlands
– sequence: 7
  givenname: Andrew L.
  surname: Simon
  fullname: Simon, Andrew L.
  organization: Division of Nephrology and
– sequence: 8
  givenname: Jian
  surname: Ying
  fullname: Ying, Jian
  organization: Division of Epidemiology, Department of Internal Medicine, University of Utah, Salt Lake City, Utah
– sequence: 9
  givenname: Gerald J.
  surname: Beck
  fullname: Beck, Gerald J.
  organization: Department of Quantitative Health Sciences, Cleveland Clinic, Cleveland, Ohio
– sequence: 10
  givenname: Christoph
  surname: Wanner
  fullname: Wanner, Christoph
  organization: Division of Nephrology, University Hospital of Würzburg, Würzburg, Germany
– sequence: 11
  givenname: Jürgen
  surname: Floege
  fullname: Floege, Jürgen
  organization: Division of Nephrology, RWTH Aachen University, Aachen, Germany
– sequence: 12
  givenname: Philip Kam-Tao
  surname: Li
  fullname: Li, Philip Kam-Tao
  organization: Division of Nephrology, Prince of Wales Hospital, Chinese University of Hong Kong, Shatin, Hong Kong
– sequence: 13
  givenname: Vlado
  surname: Perkovic
  fullname: Perkovic, Vlado
  organization: George Institute for Global Health, University of New South Wales, Sydney, Australia; and
– sequence: 14
  givenname: Edward F.
  surname: Vonesh
  fullname: Vonesh, Edward F.
  organization: Department of Preventive Medicine, Division of Biostatistics, Northwestern University, Chicago, Illinois
– sequence: 15
  givenname: Tom
  surname: Greene
  fullname: Greene, Tom
  organization: Division of Epidemiology, Department of Internal Medicine, University of Utah, Salt Lake City, Utah
BackLink https://www.ncbi.nlm.nih.gov/pubmed/31292197$$D View this record in MEDLINE/PubMed
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Copyright Copyright © 2019 by the American Society of Nephrology.
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Keywords meta-analysis
GFR
chronic kidney disease
end stage kidney disease
randomized controlled trials
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Snippet Surrogate end points are needed to assess whether treatments are effective in the early stages of CKD. GFR decline leads to kidney failure, but regulators have...
Surrogate end points are needed to assess whether treatments are effective in the earlier stages of CKD. Measuring the effects of treatments on GFR decline,...
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SubjectTerms Bayes Theorem
Biomarkers
Creatinine - blood
Disease Progression
Glomerular Filtration Rate
Humans
Kidney Failure, Chronic - etiology
Kidney Failure, Chronic - physiopathology
Meta-Analysis
Predictive Value of Tests
Randomized Controlled Trials as Topic
Renal Insufficiency, Chronic - complications
Renal Insufficiency, Chronic - physiopathology
Renal Insufficiency, Chronic - therapy
Title GFR Slope as a Surrogate End Point for Kidney Disease Progression in Clinical Trials: A Meta-Analysis of Treatment Effects of Randomized Controlled Trials
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