Frequent Links
Likelihood ratios in diagnostic testing
In evidencebased medicine, likelihood ratios are used for assessing the value of performing a diagnostic test. They use the sensitivity and specificity of the test to determine whether a test result usefully changes the probability that a condition (such as a disease state) exists.
Contents
Calculation
Two versions of the likelihood ratio exist, one for positive and one for negative test results. Respectively, they are known as the positive likelihood ratio (LR+, likelihood ratio positive, likelihood ratio for positive results) and negative likelihood ratio (LR–, likelihood ratio negative, likelihood ratio for negative results).
The positive likelihood ratio is calculated as
 <math> LR+ = \frac{\text{sensitivity}}{1  \text{specificity}} </math>
which is equivalent to
 <math> LR+ = \frac{\Pr({T+}D+)}{\Pr({T+}D)} </math>
or "the probability of a person who has the disease testing positive divided by the probability of a person who does not have the disease testing positive." Here "T+" or "T−" denote that the result of the test is positive or negative, respectively. Likewise, "D+" or "D−" denote that the disease is present or absent, respectively. So "true positives" are those that test positive (T+) and have the disease (D+), and "false positives" are those that test positive (T+) but do not have the disease (D−).
The negative likelihood ratio is calculated as^{[1]}
 <math> LR = \frac{1  \text{sensitivity}}{\text{specificity}} </math>
which is equivalent to^{[1]}
 <math> LR = \frac{\Pr({T}D+)}{\Pr({T}D)} </math>
or "the probability of a person who has the disease testing negative divided by the probability of a person who does not have the disease testing negative."
The calculation of likelihood ratios for tests with continuous values or more than two outcomes is similar to the calculation for dichotomous outcomes; a separate likelihood ratio is simply calculated for every level of test result and is called interval or stratum specific likelihood ratios.^{[2]}
The pretest odds of a particular diagnosis, multiplied by the likelihood ratio, determines the posttest odds. This calculation is based on Bayes' theorem. (Note that odds can be calculated from, and then converted to, probability.)
Application to medicine
A likelihood ratio of greater than 1 indicates the test result is associated with the disease. A likelihood ratio less than 1 indicates that the result is associated with absence of the disease. Tests where the likelihood ratios lie close to 1 have little practical significance as the posttest probability (odds) is little different from the pretest probability. In summary, the pretest probability refers to the chance that an individual has a disorder or condition prior to the use of a diagnostic test. It allows the clinician to better interpret the results of the diagnostic test and helps to predict the likelihood of a true positive (T+) result.^{[3]}
Research suggests that physicians rarely make these calculations in practice, however,^{[4]} and when they do, they often make errors.^{[5]} A randomized controlled trial compared how well physicians interpreted diagnostic tests that were presented as either sensitivity and specificity, a likelihood ratio, or an inexact graphic of the likelihood ratio, found no difference between the three modes in interpretation of test results.^{[6]}
Example
A medical example is the likelihood that a given test result would be expected in a patient with a certain disorder compared to the likelihood that same result would occur in a patient without the target disorder.
Some sources distinguish between LR+ and LR−.^{[7]} A worked example is shown below.
 A worked example
 A diagnostic test with sensitivity 67% and specificity 91% is applied to 2030 people to look for a disorder with a population prevalence of 1.48%
Patients with bowel cancer (as confirmed on endoscopy)  
Condition positive  Condition negative  
Fecal occult blood screen test outcome 
Test outcome positive 
True positive (TP) = 20 
False positive (FP) = 180 
Positive predictive value = TP / (TP + FP)
= 20 / (20 + 180) = 10% 
Test outcome negative 
False negative (FN) = 10 
True negative (TN) = 1820 
Negative predictive value = TN / (FN + TN)
= 1820 / (10 + 1820) ≈ 99.5%  
Sensitivity = TP / (TP + FN)
= 20 / (20 + 10) ≈ 67% 
Specificity = TN / (FP + TN)
= 1820 / (180 + 1820) = 91% 
Related calculations
 False positive rate (α) = type I error = 1 − specificity = FP / (FP + TN) = 180 / (180 + 1820) = 9%
 False negative rate (β) = type II error = 1 − sensitivity = FN / (TP + FN) = 10 / (20 + 10) = 33%
 Power = sensitivity = 1 − β
 Likelihood ratio positive = sensitivity / (1 − specificity) = 0.67 / (1 − 0.91) = 7.4
 Likelihood ratio negative = (1 − sensitivity) / specificity = (1 − 0.67) / 0.91 = 0.37
Hence with large numbers of false positives and few false negatives, a positive screen test is in itself poor at confirming the disorder (PPV = 10%) and further investigations must be undertaken; it did, however, correctly identify 66.7% of all cases (the sensitivity). However as a screening test, a negative result is very good at reassuring that a patient does not have the disorder (NPV = 99.5%) and at this initial screen correctly identifies 91% of those who do not have cancer (the specificity).
Confidence intervals for all the predictive parameters involved can be calculated, giving the range of values within which the true value lies at a given confidence level (e.g. 95%).^{[8]}
Estimation of pre and posttest probability
The likelihood ratio of a test provides a way to estimate the pre and posttest probabilities of having a condition.
With pretest probability and likelihood ratio given, then, the posttest probabilities can be calculated by the following three steps:^{[9]}
 Pretest odds = (Pretest probability / (1  Pretest probability)
 Posttest odds = Pretest odds * Likelihood ratio
In equation above, positive posttest probability is calculated using the likelihood ratio positive, and the negative posttest probability is calculated using the likelihood ratio negative.
 Posttest probability = Posttest odds / (Posttest odds + 1)
Alternatively, posttest probability can be calculated directly from the pretest probability and the likelihood ratio using the equation:
 P' = P0*LR/(1P0+P0*LR), where P0 is the pretest probability, P' is the posttest probability, and LR is the likelihood ratio. This formula can be calculated algebraically by combining the steps in the preceding description.
In fact, posttest probability, as estimated from the likelihood ratio and pretest probability, is generally more accurate than if estimated from the positive predictive value of the test, if the tested individual has a different pretest probability than what is the prevalence of that condition in the population.
Example
Taking the medical example from above (20 true positives, 10 false negatives, and 2030 total patients), the positive pretest probability is calculated as:
 Pretest probability = (20 + 10) / 2030 = 0.0148
 Pretest odds = 0.0148 / (1  0.0148) =0.015
 Posttest odds = 0.015 * 7.4 = 0.111
 Posttest probability = 0.111 / (0.111 + 1) =0.1 or 10%
As demonstrated, the positive posttest probability is numerically equal to the positive predictive value; the negative posttest probability is numerically equal to (1  negative predictive value).
References
 ^ ^{a} ^{b} Gardner, M.; Altman, Douglas G. (2000). Statistics with confidence: confidence intervals and statistical guidelines. London: BMJ Books. ISBN 0727913751.
 ^ Brown MD, Reeves MJ. (2003). "Evidencebased emergency medicine/skills for evidencebased emergency care. Interval likelihood ratios: another advantage for the evidencebased diagnostician". Ann Emerg Med 42 (2): 292–297. PMID 12883521. doi:10.1067/mem.2003.274.
 ^ Harrell F, Califf R, Pryor D, Lee K, Rosati R (1982). "Evaluating the Yield of Medical Tests". JAMA 247 (18): 2543–2546. PMID 7069920. doi:10.1001/jama.247.18.2543.
 ^ Reid MC, Lane DA, Feinstein AR (1998). "Academic calculations versus clinical judgments: practicing physicians’ use of quantitative measures of test accuracy". Am. J. Med. 104 (4): 374–80. PMID 9576412. doi:10.1016/S00029343(98)000540.
 ^ Steurer J, Fischer JE, Bachmann LM, Koller M, ter Riet G (2002). "Communicating accuracy of tests to general practitioners: a controlled study". BMJ 324 (7341): 824–6. PMC 100792. PMID 11934776. doi:10.1136/bmj.324.7341.824.
 ^ Puhan MA, Steurer J, Bachmann LM, ter Riet G (2005). "A randomized trial of ways to describe test accuracy: the effect on physicians' posttest probability estimates". Ann. Intern. Med. 143 (3): 184–9. PMID 16061916. doi:10.7326/00034819143320050802000004.
 ^ "Likelihood ratios". Retrieved 20090404.
 ^ Online calculator of confidence intervals for predictive parameters
 ^ Likelihood Ratios, from CEBM (Centre for EvidenceBased Medicine). Page last edited: 1 February 2009

External links
 Medical Likelihood Ratio Repositories