Abstract
Medical ultrasound (US) image segmentation and quantification can be challenging due to signal dropouts, missing boundaries, and presence of speckle, which gives images of similar objects quite different appearance. Typically, purely intensity-based methods do not lead to a good segmentation of the structures of interest. Prior work has shown that local phase and feature asymmetry, derived from the monogenic signal, extract structural information from US images. This paper proposes a new US segmentation approach based on the fuzzy connectedness framework. The approach uses local phase and feature asymmetry to define a novel affinity function, which drives the segmentation algorithm, incorporates a shape-based object completion step, and regularises the result by mean curvature flow. To appreciate the accuracy and robustness of the methodology across clinical data of varying appearance and quality, a novel entropy-based quantitative image quality assessment of the different regions of interest is introduced. The new method is applied to 81 US images of the fetal arm acquired at multiple gestational ages, as a means to define a new automated image-based biomarker of fetal nutrition. Quantitative and qualitative evaluation shows that the segmentation method is comparable to manual delineations and robust across image qualities that are typical of clinical practice.
Highlights
Organ and tissue delineation is essential for underpinning imagebased measurements of organ dimensions or tissue region properties
The proposed framework is directly compared to the original Absolute Fuzzy Connectedness method based on intensities and qualitatively and quantitatively against manual segmentations in Sections 3.2 and 3.3, respectively
This paper has presented three main technical contributions: a feature-based segmentation strategy adapted to US images, a gap completion method, and a novel quantitative image quality assessment approach to assess segmentation performance
Summary
Organ and tissue delineation is essential for underpinning imagebased measurements of organ dimensions or tissue region properties. We introduce an approach to quantify the image quality (which can vary considerably between US image acquisitions) of an ultrasound image segmentation validation dataset to appreciate the accuracy and robustness of the developed analysis methodology across clinical data of varying appearance and representative of potential real world applications. The latter is especially important for US image analysis methods, where results are normally linked to the quality of the images and general practice (with few exceptions) is to report findings on good acoustic window data.
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