Abstract
Myocardial contrast echocardiography (MCE) is an imaging technique that assesses left ventricle function and myocardial perfusion for the detection of coronary artery diseases. Automatic MCE perfusion quantification is challenging and requires accurate segmentation of the myocardium from noisy and time-varying images. Random forests (RF) have been successfully applied to many medical image segmentation tasks. However, the pixel-wise RF classifier ignores contextual relationships between label outputs of individual pixels. RF which only utilizes local appearance features is also susceptible to data suffering from large intensity variations. In this paper, we demonstrate how to overcome the above limitations of classic RF by presenting a fully automatic segmentation pipeline for myocardial segmentation in full-cycle 2-D MCE data. Specifically, a statistical shape model is used to provide shape prior information that guide the RF segmentation in two ways. First, a novel shape model (SM) feature is incorporated into the RF framework to generate a more accurate RF probability map. Second, the shape model is fitted to the RF probability map to refine and constrain the final segmentation to plausible myocardial shapes. We further improve the performance by introducing a bounding box detection algorithm as a preprocessing step in the segmentation pipeline. Our approach on 2-D image is further extended to 2-D+t sequences which ensures temporal consistency in the final sequence segmentations. When evaluated on clinical MCE data sets, our proposed method achieves notable improvement in segmentation accuracy and outperforms other state-of-the-art methods, including the classic RF and its variants, active shape model and image registration.
Highlights
M YOCARDIAL contrast echocardiography (MCE) is a cardiac ultrasound imaging tool that utilizes microbubbles as contrast agents
The shape model allows only plausible myocardial shape which improves the segmentation accuracy by imposing shape constraints that correct for some of the misclassifications made by the Random forests (RF)
Bounding Box Detection In this experiment, we evaluate the accuracy of the convolutional neural network (CNN) bounding box detection algorithm against the manual ground truth
Summary
M YOCARDIAL contrast echocardiography (MCE) is a cardiac ultrasound imaging tool that utilizes microbubbles as contrast agents. MCE can assess myocardial perfusion through the controlled destruction and replenishment of microbubbles [2]. Such perfusion information is useful for the diagnosis of coronary artery diseases (CAD) [1]. The analysis of MCE has been restricted to human visual assessment Such qualitative assessment is time consuming and relies heavily on the experience of the clinician [3]. Quantification can involve the measurements of LV volumes, ejection fraction, myocardial volumes and thickness It can involve the assessment of myocardial perfusion by analyzing myocardial intensity changes over time. The resultant segmentation can be used as input for subsequent tasks such as initialization for tracking algorithms [4]
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