Clinically viable myocardial CCTA segmentation for measuring vessel-specific myocardial blood flow from dynamic PET/CCTA hybrid fusion

Marina Piccinelli; Navdeep Dahiya; Jonathon A Nye; Russell Folks; C David Cooke; Daya Manatunga; Doyeon Hwang; Jin Chul Paeng; Sang-Geon Cho; Joo Myung Lee; Hee-Seung Bom; Bon-Kwon Koo; Anthony Yezzi; Ernest V Garcia

doi:10.1186/s41824-021-00122-1

Clinically viable myocardial CCTA segmentation for measuring vessel-specific myocardial blood flow from dynamic PET/CCTA hybrid fusion

Eur J Hybrid Imaging. 2022 Feb 15;6(1):4. doi: 10.1186/s41824-021-00122-1.

Authors

Affiliations

¹ Department of Radiology and Imaging Sciences, Emory University School of Medicine, 1364 Clifton Rd, NE, Atlanta, GA, 30322, USA. mpiccin@emory.edu.
² Department of Electrical Engineering, Georgia Institute of Technology, Atlanta, GA, USA.
³ Department of Radiology and Imaging Sciences, Emory University School of Medicine, 1364 Clifton Rd, NE, Atlanta, GA, 30322, USA.
⁴ Department of Internal Medicine and Cardiovascular Center, Seoul National University Hospital, Seoul, Korea.
⁵ Department of Nuclear Medicine, Seoul National University Hospital, Seoul, Korea.
⁶ Samsung Medical Center, Heart Vascular Stroke Institute, Seoul, Korea.
⁷ Department of Nuclear Medicine, Chonnam National University, Gwangju, Korea.

Abstract

Background: Positron emission tomography (PET)-derived LV MBF quantification is usually measured in standard anatomical vascular territories potentially averaging flow from normally perfused tissue with those from areas with abnormal flow supply. Previously we reported on an image-based tool to noninvasively measure absolute myocardial blood flow at locations just below individual epicardial vessel to help guide revascularization. The aim of this work is to determine the robustness of vessel-specific flow measurements (MBF^vs) extracted from the fusion of dynamic PET (dPET) with coronary computed tomography angiography (CCTA) myocardial segmentations, using flow measured from the fusion with CCTA manual segmentation as the reference standard.

Methods: Forty-three patients' ¹³NH₃ dPET, CCTA image datasets were used to measure the agreement of the MBF^vs profiles after the fusion of dPET data with three CCTA anatomical models: (1) a manual model, (2) a fully automated segmented model and (3) a corrected model, where major inaccuracies in the automated segmentation were briefly edited. Pairwise accuracy of the normality/abnormality agreement of flow values along differently extracted vessels was determined by comparing, on a point-by-point basis, each vessel's flow to corresponding vessels' normal limits using Dice coefficients (DC) as the metric.

Results: Of the 43 patients CCTA fully automated mask models, 27 patients' borders required manual correction before dPET/CCTA image fusion, but this editing process was brief (2-3 min) allowing a 100% success rate of extracting MBF^vs in clinically acceptable times. In total, 124 vessels were analyzed after dPET fusion with the manual and corrected CCTA mask models yielding 2225 stress and 2122 rest flow values. Forty-seven vessels were analyzed after fusion with the fully automatic masks producing 840 stress and 825 rest flow samples. All DC coefficients computed globally or by territory were ≥ 0.93. No statistical differences were found in the normal/abnormal flow classifications between manual and corrected or manual and fully automated CCTA masks.

Conclusion: Fully automated and manually corrected myocardial CCTA segmentation provides anatomical masks in clinically acceptable times for vessel-specific myocardial blood flow measurements using dynamic PET/CCTA image fusion which are not significantly different in flow accuracy and within clinically acceptable processing times compared to fully manually segmented CCTA myocardial masks.

Keywords: Absolute myocardial blood flow; Cardiac PET; Coronary CTA; Multimodality image fusion; Vessel-specific quantification.

Abstract

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