Abstract

Patient motion during dynamic PET imaging can induce errors in myocardial blood flow (MBF) estimation. Motion correction for dynamic cardiac PET is challenging because the rapid tracer kinetics of 82Rb leads to substantial tracer distribution change across different dynamic frames over time, which can cause difficulties for image registration-based motion correction, particularly for early dynamic frames. In this paper, we developed an automatic deep learning-based motion correction (DeepMC) method for dynamic cardiac PET. In this study we focused on the detection and correction of inter-frame rigid translational motion caused by voluntary body movement and pattern change of respiratory motion. A bidirectional-3D LSTM network was developed to fully utilize both local and nonlocal temporal information in the 4D dynamic image data for motion detection. The network was trained and evaluated over motion-free patient scans with simulated motion so that the motion ground-truths are available, where one million samples based on 65 patient scans were used in training, and 600 samples based on 20 patient scans were used in evaluation. The proposed method was also evaluated using additional 10 patient datasets with real motion. We demonstrated that the proposed DeepMC obtained superior performance compared to conventional registration-based methods and other convolutional neural networks (CNN), in terms of motion estimation and MBF quantification accuracy. Once trained, DeepMC is much faster than the registration-based methods and can be easily integrated into the clinical workflow. In the future work, additional investigation is needed to evaluate this approach in a clinical context with realistic patient motion.

Highlights

  • P OSITRON emission tomography (PET) myocardial perfusion imaging has been shown to improve the diagnostic accuracy of coronary artery disease (CAD) as compared to other non-invasive imaging modalities [1]

  • We developed automatic motion correction for dynamic cardiac PET using deep learning (DeepMC) for the first time, to the best of our knowledge

  • We focus on detection and correction of the inter-frame rigid translational motion caused by body motion and change in the pattern of respiratory motion

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Summary

Introduction

P OSITRON emission tomography (PET) myocardial perfusion imaging has been shown to improve the diagnostic accuracy of coronary artery disease (CAD) as compared to other non-invasive imaging modalities [1]. Absolute quantification of myocardial blood flow (MBF) and myocardial flow reserve (MFR) using dynamic PET has shown superior diagnostic and prognostic value as compared to the conventional relative myocardial perfusion imaging [2]. Regions of interest are usually defined on the reconstructed dynamic images to sample the time-activity curves (TAC) in the myocardium tissue and left ventricle (LV) cavity. These TACs can be further processed via kinetic modeling to quantify MBF. Patient motion during dynamic imaging, which typically includes respiratory motion, cardiac motion and voluntary body motion, can induce errors in MBF estimation [3], [4]. Additional errors could be introduced by the mismatch between PET and CT-based attenuation map caused by patient motion [5]

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