Positron emission tomography using fluorine-18 deoxyglucose in evaluation of coronary artery bypass grafting☆
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Viability assessment by <sup>18</sup>F-FDG PET in a patient with a large left ventricular aneurysm and obstructive coronary artery disease
2020, Journal of Nuclear CardiologyStatus of F-18 fluorodeoxyglucose uptake in normal and hibernating myocardium after glucose and insulin loading
2018, Journal of the Saudi Heart AssociationCitation Excerpt :FDG-6-phosphate does not undergo subsequent metabolism (glycogen synthesis or aerobic glycolysis) but only minimal dephosphorylation [3]. In the region of the fixed perfusion defect, FDG uptake (perfusion–metabolism mismatch) usually indicates viability, whereas lack of FDG uptake usually indicates nonviability, although false-negative or false-positive results have been reported [3–10]. Inflammatory reaction following recent myocardial infarction can cause false-positive FDG uptake, providing misleading information about the viability of the myocardium [8].
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2011, PET ClinicsCitation Excerpt :Although there are several techniques for the assessment of myocardial viability, Tillisch and colleagues22 were the first to successfully predict functional reversibility of myocardium on the basis on FDG-PET imaging in 1986. Several investigators have since extensively validated FDG-PET metabolism imaging to assess myocardial viability in an array of clinical scenarios.23–30 When dysfunctional myocardium with an intermediate decline in blood flow is encountered, the presence of myocardial viability cannot be adequately assessed with regional myocardial blood flow alone.
Use of Cardiac Magnetic Resonance Imaging and Positron Emission Tomography in Assessment of Cardiovascular Disease Risk and Atherosclerosis Progression
2011, Preventive Cardiology: Companion to Braunwald's Heart Disease Expert Consult - Online and PrintPrinciples of Myocardial Metabolism as They Relate to Imaging
2010, Clinical Nuclear Cardiology: State of the Art and Future Directions
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This study was supported in part by the 1988 Research Grant from the Japan Heart Foundation, Tokyo.