Automatic thoracic body region localization

PeiRui Bai; Jayaram K. Udupa; YuBing Tong; ShiPeng Xie; Drew A. Torigian

doi:10.1117/12.2254862

3 March 2017 Automatic thoracic body region localization

PeiRui Bai, Jayaram K. Udupa, YuBing Tong, ShiPeng Xie, Drew A. Torigian

Proceedings Volume 10134, Medical Imaging 2017: Computer-Aided Diagnosis; 101343X (2017) https://doi.org/10.1117/12.2254862
Event: SPIE Medical Imaging, 2017, Orlando, Florida, United States

Abstract

Radiological imaging and image interpretation for clinical decision making are mostly specific to each body region such as head & neck, thorax, abdomen, pelvis, and extremities. For automating image analysis and consistency of results, standardizing definitions of body regions and the various anatomic objects, tissue regions, and zones in them becomes essential. Assuming that a standardized definition of body regions is available, a fundamental early step needed in automated image and object analytics is to automatically trim the given image stack into image volumes exactly satisfying the body region definition. This paper presents a solution to this problem based on the concept of virtual landmarks and evaluates it on whole-body positron emission tomography/computed tomography (PET/CT) scans. The method first selects a (set of) reference object(s), segments it (them) roughly, and identifies virtual landmarks for the object(s). The geometric relationship between these landmarks and the boundary locations of body regions in the craniocaudal direction is then learned through a neural network regressor, and the locations are predicted. Based on low-dose unenhanced CT images of 180 near whole-body PET/CT scans (which includes 34 whole-body PET/CT scans), the mean localization error for the boundaries of superior of thorax (TS) and inferior of thorax (TI), expressed as number of slices (slice spacing ≈ 4mm)), and using either the skeleton or the pleural spaces as reference objects, is found to be 3,2 (using skeleton) and 3, 5 (using pleural spaces) respectively, or in mm 13, 10 mm (using skeleton) and 10.5, 20 mm (using pleural spaces), respectively. Improvements of this performance via optimal selection of objects and virtual landmarks and other object analytics applications are currently being pursued.

and the skeleton and pleural spaces used as a reference objects

Citation Download Citation

PeiRui Bai, Jayaram K. Udupa, YuBing Tong, ShiPeng Xie, and Drew A. Torigian "Automatic thoracic body region localization", Proc. SPIE 10134, Medical Imaging 2017: Computer-Aided Diagnosis, 101343X (3 March 2017); https://doi.org/10.1117/12.2254862

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