| Literature DB >> 34280905 |
Yang Zuo1, Javier E López2, Thomas W Smith2, Cameron C Foster1, Richard E Carson3, Ramsey D Badawi1,4, Guobao Wang1.
Abstract
Myocardial blood flow (MBF) and flow reserve are usually quantified in the clinic with positron emission tomography (PET) using a perfusion-specific radiotracer (e.g.82Rb-chloride). However, the clinical accessibility of existing perfusion tracers remains limited. Meanwhile,18F-fluorodeoxyglucose (FDG) is a commonly used radiotracer for PET metabolic imaging without similar limitations. In this paper, we explore the potential of18F-FDG for myocardial perfusion imaging by comparing the myocardial FDG delivery rateK1with MBF as determined by dynamic82Rb PET in fourteen human subjects with heart disease. Two sets of FDGK1were derived from one-hour dynamic FDG scans. One was the original FDGK1estimates and the other was the correspondingK1values that were linearly normalized for blood glucose levels. A generalized Renkin-Crone model was used to fit FDGK1with Rb MBF, which then allowed for a nonlinear extraction fraction correction for converting FDGK1to MBF. The linear correlation between FDG-derived MBF and Rb MBF was moderate (r= 0.79) before the glucose normalization and became much improved (r> 0.9) after glucose normalization. The extraction fraction of FDG was also similar to that of Rb-chloride in the myocardium. The results from this pilot study suggest that dynamic cardiac FDG-PET with tracer kinetic modeling has the potential to provide MBF in addition to its conventional use for metabolic imaging.Entities:
Keywords: FDG delivery rate; dynamic PET; extraction fraction correction; glucose normalization; kinetic modeling; multiparametric imaging; myocardial blood flow
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Year: 2021 PMID: 34280905 DOI: 10.1088/1361-6560/ac15a6
Source DB: PubMed Journal: Phys Med Biol ISSN: 0031-9155 Impact factor: 3.609