Bayesian Updating and Sequential Testing: Overcoming Inferential Limitations of Screening Tests

Abstract

Bayes' Theorem confers inherent limitations on the accuracy of screening tests as a function of disease prevalence. We have shown in previous work that a testing system can tolerate significant drops in prevalence, up until a certain well-defined point known as the prevalence threshold, below which the reliability of a positive screening test drops precipitously. Herein, we establish a mathematical model to determine whether sequential testing overcomes the aforementioned Bayesian limitations and thus improves the reliability of screening tests. We show that for a desired positive predictive value of that approaches k, the number of positive test iterations ni needed is: ni = kln[(φ-1)φ(-1)]ln[a1-b] where ni = number of testing iterations necessary to achieve , the desired positive predictive value, a = sensitivity, b = specificity, φ = disease prevalence and k = constant. Based on the aforementioned derivation, we provide reference tables for the number of test iterations needed to obtain a (φ) of 50, 75, 95 and 99\% as a function of various levels of sensitivity, specificity and disease prevalence.