Theorems on the Geometric Definition of the Positive Likelihood Ratio (LR+)

Abstract

From the fundamental theorem of screening (FTS) we obtain the following mathematical relationship relaying the pre-test probability of disease φ to the positive predictive value (φ) of a screening test: 2 ∫01(φ)dφ = 1 where is the screening coefficient - the sum of the sensitivity (a) and specificity (b) parameters of the test in question. However, given the invariant points on the screening plane, identical values of may yield different shapes of the screening curve since does not respect traditional commutative properties. In order to compare the performance between two screening curves with identical values, we derive two geometric definitions of the positive likelihood ratio (LR+), defined as the likelihood of a positive test result in patients with the disease divided by the likelihood of a positive test result in patients without the disease, which helps distinguish the performance of both screening tests. The first definition uses the angle β created on the vertical axis by the line between the origin invariant and the prevalence threshold φe such that LR+ = a1-b = cot2(β). The second definition projects two lines (y1,y2) from any point on the curve to the invariant points on the plane and defines the LR+ as the ratio of its derivatives dy1dx and dy2dx. Using the concepts of the prevalence threshold and the invariant points on the screening plane, the work herein presented provides a new geometric definition of the positive likelihood ratio (LR+) throughout the prevalence spectrum and describes a formal measure to compare the performance of two screening tests whose screening coefficients are equal.