Abstract
We investigated the frequency and extent of changes in heart position and geometry independent of body motion during stress single-photon emission tomography (SPET) thallium-201 myocardial perfusion imaging. Following an exercise treadmill test, patients had a 22.1-min SPET acquisition which was followed immediately by a static image acquisition for 1 min with the camera position identical to the first view of the SPET study. Point sources were placed on the body to monitor patient motion. Cardiac motion was assessed by an approach which mimicked a cross-correlation technique applied to cardiac count profiles along the horizontal and vertical directions from the first view of the SPET study and the static image. A large percentage (87.5%) of cases had some degree of horizontal or vertical motion. Pixel shifts in cardiac position of ≧2 pixels (12 mm) occurred in 60% of patients. In 37% of patients who moved the cardiac motion was consistent with simple translation of the heart and thus amenable to correction using proposed SPET motion-correction programs. The peak heart rate achieved during stress and the ratio of the heart rate immediately before SPET acquisition to the resting heart rate were determined to be independent predictors of patient motion during SPET acquisition. Cardiac motion changes were minimal at (13.3 ±2.2) min after cessation of exercise. The implications of these findings for the accuracy of SPET 201Tl require further investigation.
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Eisner RL, Churchwell A, Noever T, Nowak DJ, Cloninger KG, Dunn DW, Carlson W, Oates JA, Jones J, Morris DC, Liberman HA, Patterson RE. Quantitative analysis of the tomographic thallium-201 myocardial bullseye display: critical role of correcting for patient motion. J Nucl Med 1988; 29:91–97
Friedman J, Van Train K, Maddahi J, et al. “Upward creep” of the heart: a frequent source of false-positive reversible defects during thallium-201 stress-redistribution SPECT. J Nucl Med 1989; 30:1718–1722
Mester J, Weller R, Clausen M, Bitter F, Henze E, Lietzenmayer R, Adam W-E. Upward creep of the heart in exercise thallium-201 single photon emission tomography: clinical relevance and a simple correction method. Eur J Nucl Med 1991; 18:184–190
Geckle WJ, Frank TL, Links JM, Becker LC. Correction for patient and organ movement in SPECT: application to exercise thallium-201 cardiac imaging. J Nucl Med 1988; 29:441–450
Ross J Jr, Gault JH, Mason DT, Linhart JW, Braunwald E. Left ventricular performance during muscular exercise in patients with and without cardiac dysfunction. Circulation 1966; 34:597–606
Astrand PO, Rodahl K. Textbook of work Physiology. New York: McGraw-Hill, 1971
Shonkoff D, Eisner RL, Gober A, Tamas MJ, Oates J, Dunn D, Churchwell AL, Battey LL, Liberman HA, Morris DC, Patterson RE. What quantitative criteria sould be used to read defects on the SPECT T1–201 bullseye display in men? ROC analysis [abstract]. J Nucl Med 1987; 28:674
Cloninger KG, Eisner RL, Oates J, Noever T, Dunn D, Morris DC, Liberman HA, Churchwell AL, Patterson RE. Specificity of SPECT T1-201 myocardial imaging in women: improvement by adjusting for breast attenuation [abstract]. J Am Coll Cardiol 1987; 9(2):140A
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Eisner, R.L., Aaron, A.M., Worthy, M.R. et al. Apparent change in cardiac geometry during single-photon emission tomography thallium-201 acquisition: a complex phenomenon. Eur J Nucl Med 20, 324–329 (1993). https://doi.org/10.1007/BF00169808
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DOI: https://doi.org/10.1007/BF00169808