Automatic Skeleton Segmentation in CT Images Based on U-Net

Bone metastasis, emerging oncological therapies, and osteoporosis represent some of the distinct clinical contexts which can result in morphological alterations in bone structure. The visual assessment of these changes through anatomical images is considered suboptimal, emphasizing the importance of...

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Bibliographic Details
Published in:Journal of digital imaging 2024-10, Vol.37 (5), p.2390-2400
Main Authors: Milara, Eva, Gómez-Grande, Adolfo, Sarandeses, Pilar, Seiffert, Alexander P, Gómez, Enrique J, Sánchez-González, Patricia
Format: Article
Language:English
Subjects:
Computed tomography
Deep learning
Feature maps
Femur
Image acquisition
Image processing
Image segmentation
Medical imaging
Metastases
Neural networks
Osteoporosis
Segmentation
Skeleton
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Summary:Bone metastasis, emerging oncological therapies, and osteoporosis represent some of the distinct clinical contexts which can result in morphological alterations in bone structure. The visual assessment of these changes through anatomical images is considered suboptimal, emphasizing the importance of precise skeletal segmentation as a valuable aid for its evaluation. In the present study, a neural network model for automatic skeleton segmentation from bidimensional computerized tomography (CT) slices is proposed. A total of 77 CT images and their semimanual skeleton segmentation from two acquisition protocols (whole-body and femur-to-head) are used to form a training group and a testing group. Preprocessing of the images includes four main steps: stretcher removal, thresholding, image clipping, and normalization (with two different techniques: interpatient and intrapatient). Subsequently, five different sets are created and arranged in a randomized order for the training phase. A neural network model based on U-Net architecture is implemented with different values of the number of channels in each feature map and number of epochs. The model with the best performance obtains a Jaccard index (IoU) of 0.959 and a Dice index of 0.979. The resultant model demonstrates the potential of deep learning applied in medical images and proving its utility in bone segmentation.
ISSN:2948-2933
0897-1889
2948-2933
1618-727X
DOI:10.1007/s10278-024-01127-5