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Abstract

To enable targeted therapies and enhance medical decision-making, biomarkers are increasingly used as screening and diagnostic tests. When using quantitative biomarkers for classification purposes, this often implies that an appropriate cutoff for the biomarker has to be determined and its clinical utility must be assessed. In the context of drug development, it is of interest how the probability of response changes with increasing values of the biomarker. Unlike sensitivity and specificity, predictive values are functions of the accuracy of the test, depend on the prevalence of the disease and therefore are a useful tool in this setting. In this paper, we propose a Bayesian method to not only estimate the cutoff value using the negative and positive predictive values, but also estimate the uncertainty around this estimate. Using Bayesian inference allows us to incorporate prior information, and obtain posterior estimates and credible intervals for the cut-off and associated predictive values. The performance of the Bayesian approach is compared with alternative methods via simulation studies of bias, interval coverage and width and illustrations on real data with binary and time-to-event outcomes are provided.

Keywords

Bayesian model cutoff estimation predictive values step function diagnostic tests clinical utility response rates

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References

Colburn

. Biomarkers in drug discovery and development: from target identification through drug marketing. J Clin Pharmacol 2003; 43: 329–341.

Pepe MS. The statistical evaluation of medical tests for classification and prediction. Oxford: Oxford University Press, 2003.

Perkins

Schisterman

. The inconsistency of “optimal” cutpoints obtained using two criteria based on the receiver operating characteristic curve. Am J Epidemiol 2006; 163: 670–675.

Schisterman

Perkins

. Confidence intervals for the Youden index and corresponding optimal cut-point. Commun Stat Part B: Simul Computat 2007; 36: 549–563.

Lunceford

. Clinical utility estimation for assay cutoffs in early phase oncology enrichment trials. Pharmaceut Stat 2015; 14: 233–341.

Lever J, Krzywinski M and Altman N. Points of significance: logistic regression. Nat Methods 2016; 13: 541–542.

Huber PJ. The behaviour of maximum likelihood estimates under non?standard conditions. In: LeCam LM and Neyman J (eds) Proc. 5th Berkeley Symp. Mathematical Statistics and Probability vol. 1, 1967, pp. 221–233. Berkeley: University of California Press.

Bunke

Milhaud

. Asymptotic behavior of Bayes estimates under possibly incorrect models. Ann Stat 1998; 26: 617–644.

Kullback

Leibler

. On information and sufficiency. Ann Math Stat 1951; 22: 79–86.

10.

Schmidli

Gsteiger

Roychoudhury

, et al. Robust meta‐analytic‐predictive priors in clinical trials with historical control information. Biometrics 2014; 70: 1023–1032.

11.

Linn

Grunau

. New patient-oriented summary measure of net total gain in certainty for dichotomous diagnostic tests. Epidemiol Perspect Innovat 2006; 3: 11–11.

12.

Youden

. Index for rating diagnostic tests. Cancer 1950; 3: 32–35.

13.

Chu

Cole

. Estimation of risk ratios in cohort studies with common outcomes: a Bayesian approach. Epidemiology 2010; 21: 855–862.

14.

Wagenmakers EJ, Lee M, Lodewyckx T, et al. Bayesian versus frequentist inference. In: Hoijtink H, Klugkist I and Boelen PA (eds) Bayesian evaluation of informative hypotheses. New York, NY: Springer, 2008, pp.181-207.

15.

Team RC. R: a language and environment for statistical computing. R Foundation for Statistical Computing. R version 3.3.3 Vienna, Austria.

16.

Lopez-Raton

Rodriguez-Alvarez

Cadarso-Suarez

, et al. Optimal cutpoints: an R package for selecting optimal cut-points in diagnostic tests. J Stat Software 2014; 61: 1–35. http//www.jstatsoft.org .

17.

Bolker B. R Development Core Team. 2014. bbmle: Tools for general maximum likelihood estimation. R package version 1.0. 17. Computer program. 2011.

18.

Hastings

. Monte Carlo sampling methods using Markov chains and their applications. Biometrika 1970; 57: 97–109.

19.

Metropolis

Rosenbluth

, et al. Equation of state calculations by fast computing machines. J Chem Phys 1953; 21: 1087–1092.

20.

Ibrahim JG, Chen MH and Sinha D. Bayesian survival analysis. New York: Springer, 2001.

21.

Hartigan

. The dip test of unimodality. Ann Stat 1985; 3: 70–84.

22.

Etzioni

Pepe

Longton

, et al. Incorporating the time dimension in receiver operating characteristic curves: a case study of prostate cancer. Med Decis Making 1999; 19: 242–251.

23.

Broemeling LD. Advanced bayesian methods for medical test accuracy. Boca Raton, FL: Chapman & Hall/CRC Press, 2011.

24.

Martinussen

Scheike

. Dynamic regression models for survival analysis. Statistics for biology and health, NY: Springer, 2006.

25.

Chivers C. MHadaptive: general Markov Chain Monte Carlo for Bayesian inference using adaptive Metropolis-Hastings sampling. Retrieved from http://cran.r-project.org/web/packages/MHadaptive/MHadaptive.pdf (2012).

26.

Brier

. Verification of forecasts expressed in terms of probability. Mon Wea Rev 1950; 78: 1–3.

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A Bayesian model to estimate the cutoff and the clinical utility of a biomarker assay

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Supplementary Material