long-term prognostic value for patients with chronic heart failure of estimated glomerular...
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Long-Term Prognostic Value for Patients with Chronic Heart Failure of Estimated Glomerular Filtration Rate Calculated with the New CKD-EPI Equations Containing Cystatin C
E. Zamora, J. Lupón, M. de Antonio, J. Vila, J. Peñafiel, A. Galán, A. Urrutia, M. Domingo, and A. Bayes-Genis
March 2014
www.clinchem.org/content/60/3/481.full
© Copyright 2014 by the American Association for Clinical Chemistry
© Copyright 2009 by the American Association for Clinical Chemistry
IntroductionIntroduction Background
Correct estimation of renal function is crucial in assessing prognosis of patients with heart failure (HF).
Recently, two new equations have been proposed to calculate estimated glomerular filtration rate (eGFR) with cystatin C alone or both creatinine and cystatin C:
CKD-EPI-cystatin C CKD-EPI-creatinine-cystatin C
Aims
To assess the prognostic value of eGFR estimated by these new equations in outpatients with HF.
© Copyright 2009 by the American Association for Clinical Chemistry
Measurements of performanceMeasurements of performanceDiscrimination
The area under the ROC curve (AUC) summarized the diagnostic discrimination.
We used the index of rank correlation, Somers D, which incorporates information from censored data.
AUCs between models were compared with 10,000 bootstrapping replicates.
Calibration The D’Agostino–Nam version of the Hosmer–Lemeshow calibration
test was used to calculate 2 values. In addition, the Bayesian information criterion (BIC), the Akaike
information criterion (AIC), and the Brier score were calculated for each model.
Reclassification Two main statistics were used to assess reclassification. The
integrated discrimination improvement (IDI) and the net reclassification improvement (NRI).
© Copyright 2009 by the American Association for Clinical Chemistry
QUESTIONQUESTION
Is it important to assess in heart failure the prognostic value of eGFR calculated with the newer equations?
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Table 1. Patient demographics, baseline clinical data, and treatments.Data are n (%) or median (25th, 75th percentile) unless noted otherwise
© Copyright 2009 by the American Association for Clinical Chemistry
Figure 1. Long-term Kaplan–Meier survival curves according to National Kidney Foundation eGFR categories for all equations.(A) MDRD-4-IDMS. (B) CKD-EPI. (C) CKD-EPI-cystatin C. (D) CKD-EPI-creatinine- cystatin C.
© Copyright 2009 by the American Association for Clinical Chemistry© Copyright 2009 by the American Association for Clinical Chemistry
Table 2. Multivariable Cox regression analysis for risk of death based on eGFR National Kidney Foundation categoriesa from all equations. a Categories IV and V of the National Kidney Foundation have been merged into 1 category for reasons of sample size.b I–II vs III–IV.
© Copyright 2009 by the American Association for Clinical Chemistry© Copyright 2009 by the American Association for Clinical Chemistry
Figure 2. Hazard ratios for death from any cause according to eGFR as calculated with each of the 4 equations. The graphs show associations by plotting the hazard ratio versus a reference eGFR, which is indicated by diamond at 95 mL·min-1·(1.73 m2)-1. Coefficients per 1-mL·min-1·(1.73 m2)-1 eGFR increment have been calculated in each eGFR interval (i.e., 30, 30 to 60, 60 to 90, 90+), and then a coefficient resulting from the addition of these coefficients has been created for all eGFR values.
© Copyright 2009 by the American Association for Clinical Chemistry
QUESTIONQUESTION
What is the likely explanation for the large differences in HR (prognostic implication) found in the different equations to estimate a given eGFR?
© Copyright 2009 by the American Association for Clinical Chemistry© Copyright 2009 by the American Association for Clinical Chemistry
Table 3. Performance for risk of death prediction at 4 years of CKD-EPI-cystatin C and CKD-EPI-creatinine-cystatin C compared to MDRD-4-IDMS equation.
a P < 0.001; b P =0.51; c P =0.11; d P =0.76; e P =0.045
Table 3Table 3
© Copyright 2009 by the American Association for Clinical Chemistry© Copyright 2009 by the American Association for Clinical Chemistry
Table 4. Performance for risk of death prediction at 4 years of CKD-EPI-cystatin C and CKD-EPI-creatinine-cystatin C compared to CKD-EPI equation. a P < 0.001; b P =0.68; c P =0.11; d P =0.76; e P =0.003; f P =0.360
Table 4Table 4
© Copyright 2009 by the American Association for Clinical Chemistry© Copyright 2009 by the American Association for Clinical Chemistry
Figure 3. AUC for risk of death prediction at 4 years according to eGFR calculated with the 4 equations.The best AUC was obtained with CKD-EPI-cystatin C equation.
© Copyright 2009 by the American Association for Clinical Chemistry
QUESTIONQUESTION
Why do you think CKD-EPI-cystatin C was the best-performing prognostically, despite prior studies that found it is not the more accurate equation for estimating real eGFR (compared with isotopic GFR)?
© Copyright 2009 by the American Association for Clinical Chemistry
ConclusionsConclusions
The two new CKD-EPI equations containing cystatin C are
useful for HF risk stratification and show better prognostic
performance than creatinine-only based eGFR equations,
mostly in patients with intermediate eGFR.
These equations seem appropriate for assessing
prognosis of HF patients with moderate renal
insufficiency.
© Copyright 2009 by the American Association for Clinical Chemistry
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