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Progressive DeepSSM: Training Methodology for Image-To-Shape Deep Models.

Abu Zahid Bin Aziz1,2, Jadie Adams1,2, Shireen Elhabian1,2

  • 1Scientific Computing and Imaging Institute, University of Utah, Salt Lake City, Utah, USA.

Shape in Medical Imaging : International Workshop, Shapemi 2023, Held in Conjunction with MICCAI 2023, Vancouver, BC, Canada, October 8, 2023, Proceedings. Shapemi (Workshop) (2023 : Vancouver, B.C.)
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PubMed
Summary
This summary is machine-generated.

This study introduces progressive DeepSSM, a novel training strategy for deep learning models to create statistical shape models (SSMs) from medical images. This method enhances accuracy and stability in anatomical shape analysis.

Keywords:
Deep SupervisionMedical ImagingProgressive LearningStatistical Shape Modeling

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Area of Science:

  • Medical imaging analysis
  • Computational anatomy
  • Deep learning in healthcare

Background:

  • Statistical shape modeling (SSM) is crucial for quantitative analysis of anatomical shapes in medicine.
  • Directly using 3D medical images for SSM construction requires extensive preprocessing.
  • Current deep learning methods for direct SSM construction from images show suboptimal performance.

Purpose of the Study:

  • To propose a new training strategy, progressive DeepSSM, to improve deep learning models for image-to-shape analysis.
  • To enable learning of both coarse and fine anatomical shape features progressively.
  • To enhance the accuracy and stability of SSMs generated directly from unsegmented medical images.

Main Methods:

  • A multiscale training strategy named progressive DeepSSM is introduced.
  • The model training progresses through multiple scales, with each scale building upon the previous one.
  • Segmentation-guided multi-task learning and deep supervision loss are employed to incorporate shape priors and ensure learning at each scale.

Main Results:

  • Models trained with the progressive DeepSSM strategy demonstrate superior quantitative and qualitative performance.
  • The proposed strategy significantly improves the accuracy of statistical shape representations.
  • Enhanced training stability is observed for deep learning models using this methodology.

Conclusions:

  • Progressive DeepSSM is an effective training methodology for deep learning-based image-to-shape models.
  • This strategy can be broadly adopted to improve existing deep learning methods for anatomical shape analysis.
  • The approach facilitates more accurate and stable inference of statistical shape models directly from medical images.