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Related Experiment Video

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Prior guided deep difference meta-learner for fast adaptation to stylized segmentation.

Dan Nguyen1, Anjali Balagopal1, Ti Bai1

  • 1Medical Artificial Intelligence and Automation (MAIA) Laboratory and Department of Radiation Oncology, University of Texas Southwestern Medical Center, Dallas, TX, United States of America.

Machine Learning: Science and Technology
|April 18, 2025
PubMed
Summary
This summary is machine-generated.

A new deep learning model, the Prior-guided deep difference meta-learner (DDL), efficiently adapts radiotherapy auto-segmentation to local clinician styles. This improves segmentation accuracy with minimal patient data, streamlining clinical workflows.

Keywords:
artificial intelligencecancerclinician stylizationdeep learningmeta-learningoncologysegmentation

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Area of Science:

  • Medical imaging and radiotherapy
  • Artificial intelligence in healthcare
  • Computational anatomy

Background:

  • Radiotherapy treatment planning necessitates accurate segmentation of anatomical structures.
  • Deep learning auto-segmentation models often fail to match diverse clinical segmentation styles.
  • Adapting pre-trained models to new institutional styles is resource-intensive.

Purpose of the Study:

  • To develop a method for adapting pre-trained auto-segmentation models to new, unseen clinician segmentation styles.
  • To enable precise segmentation that aligns with local preferences without extensive retraining.
  • To improve the efficiency and accuracy of radiotherapy contouring.

Main Methods:

  • Proposed a Prior-guided deep difference meta-learner (DDL) to learn and adapt segmentation style differences.
  • Utilized a dataset of 440 patients for development and 30 for testing, including prostate CTV, parotid, and rectum contours.
  • Evaluated performance using Dice Similarity Coefficient (DSC) and Hausdorff distance, comparing with transfer learning.

Main Results:

  • The DDL model adapted to new styles with minimal prior patient data (as few as 3 patients).
  • Significant improvements in average DSC were observed across various structures (e.g., CTV, parotid, rectum).
  • The model achieved high accuracy, outperforming transfer learning in adapting to unseen styles.

Conclusions:

  • The Prior-guided DDL offers a fast and effortless solution for adapting segmentation models to new styles.
  • Improved segmentation accuracy can reduce manual contour editing time, enhancing clinical workflow efficiency.
  • This approach facilitates the deployment of auto-segmentation tools in diverse clinical settings.