Comparison of Cost-Effectiveness and Utility of Exercise ECG, Single Photon Emission Computed Tomography, Positron Emission Tomography, and Coronary Angiography for Diagnosis of Coronary Artery Disease

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Circulation. 1995;91:54-65

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Comparison of Cost-Effectiveness and Utility of Exercise ECG, Single Photon Emission Computed Tomography, Positron Emission Tomography, and Coronary Angiography for Diagnosis of Coronary Artery Disease

Randolph E. Patterson, MD; Robert L. Eisner, PhD; Steven F. Horowitz, MD

From the Carlyle Fraser Heart Center, Emory:Crawford Long Hospital, Department of Medicine, Division of Cardiology and Department of Radiology, Emory University School of Medicine, Atlanta, Ga, and Thomas Killip Division of Cardiology, Department of Medicine, Beth Israel Medical Center, Albert Einstein College of Medicine, New York, NY (S.F.H.).

Correspondence to Randolph E. Patterson, MD, Professor of Medicine (Cardiology) and Radiology, Emory University School of Medicine, Carlyle Fraser Heart Center, Emory:Crawford Long Hospital, 550 Peachtree St, NE, Atlanta, GA 30365.

Background To compare cost-effectiveness and utility of fourclinical algorithms to diagnose obstructive coronary atheroscleroticheart disease (CAD), we compared exercise ECG (ExECG), stresssingle photon emission computed tomography (SPECT), positron emissiontomography (PET), and coronary angiography.

Methods and Results Published data and a straightforward mathematicalmodel based on Bayes' theorem were used to compare strategies.Effectiveness was defined as the number of patients with diagnosedCAD, and utility was defined as the clinical outcome, ie, the numberof quality-adjusted life years (QALY) extended by therapy after thediagnosis of CAD. Our model used published values for costs, accuracy,and complication rates of tests. Analysis of the model indicatesthe following results. (1) The direct cost (fee) for each testdiffers considerably from total cost per ${Delta}$ QALY. (2) As pretest likelihoodof CAD (pCAD) in the population increases, there is a linear increasein cost per patient tested but a hyperbolic decrease in cost pereffect and cost per utility unit, ie, increased cost-effectiveness anddecreased cost per utility unit. (3) At pCAD<0.70, analysisof the model indicates that stress PET is the most cost-effectivetest, with the lowest cost per utility, followed by SPECT, ExECG,and angiography, in that order. (4) Above a threshold valueof pCAD of 0.70 (for example, middle-aged men with typical angina),proceeding directly to angiography as the first test showedthe lowest cost per effect or utility. This quantitative modelhas the advantage of estimating a threshold value of pCAD (0.70)at which the rank order of cost-effectiveness and cost per utilityunit change. The model also allows substitution of differentvalues for any variable as a way to account for the uncertaintiesof clinical data, ie, changing costs, test accuracy and risk,etc. This procedure, called sensitivity analysis, showed thatthe rank order of cost-effectiveness did not change despitechanges in several variables.

Conclusions (1) Estimation of total costs of diagnostic testsfor CAD requires consideration not only of the direct cost ofthe test per se (eg, test fees) but also of the indirect andinduced costs of management algorithms based on the test (eg,cost/ ${Delta}$ QALY). (2) It is essential to consider the clinical history(pCAD) when selecting the clinical algorithm to make a diagnosiswith the lowest cost per effect or cost per utility unit. (3)Stress PET shows the lowest cost per effect or cost per utilityunit in patients with pCAD<0.70. (4) Angiography shows thelowest cost per effect or cost per utility unit in patientswith pCAD>0.70.

Key Words: cost-effectiveness • electrocardiography • imaging • angiography • coronary artery disease

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