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Swin-PSAxialNet: An Efficient Multi-Organ Segmentation Technique
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Improving Splenomegaly Segmentation by Learning from Heterogeneous Multi-Source Labels.

Yucheng Tang1, Yuankai Huo2, Yunxi Xiong2

  • 1Electrical Engineering, Vanderbilt University, Nashville, TN, USA 37235.

Proceedings of Spie--The International Society for Optical Engineering
|November 26, 2019
PubMed
Summary
This summary is machine-generated.

This study introduces a novel deep learning method for spleen segmentation in CT scans, effectively utilizing diverse datasets with varying labels. The approach significantly improves accuracy in identifying splenomegaly, aiding in liver and spleen disease assessment.

Keywords:
computed tomographydeep convolutional neural networksmulti-organ segmentationspleen segmentationweakly supervised learning

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Area of Science:

  • Medical Imaging Analysis
  • Deep Learning in Radiology
  • Computational Anatomy

Background:

  • Accurate splenomegaly segmentation in CT scans is crucial for diagnosing liver and spleen diseases.
  • Manual annotation of medical imaging data is labor-intensive, leading to scarcity of labeled datasets.
  • Existing deep learning models struggle with multi-source datasets containing heterogeneous labels.

Purpose of the Study:

  • To develop a deep convolutional neural network (DCNN) method for splenomegaly segmentation using heterogeneous multi-resource labeled cohorts.
  • To introduce a novel loss function that adaptively learns from multi-organ information across different datasets.
  • To evaluate the proposed method's performance against established segmentation techniques.

Main Methods:

  • A novel DCNN architecture integrating data from multiple sources with varying label sets.
  • Introduction of a Dice similarity coefficient-based loss function for adaptive multi-organ learning.
  • Experimental validation using three distinct CT scan cohorts with different labeling schemes.

Main Results:

  • The proposed method achieved a median Dice similarity coefficient of 0.94 on the independent testing cohort.
  • This performance was statistically superior (p-value<0.01) to multi-atlas segmentation (0.86), SS-Net (0.90), and U-Net (0.91).
  • The adaptive loss function effectively leveraged heterogeneous labels for improved segmentation accuracy.

Conclusions:

  • The developed co-learning strategy effectively integrates multi-source, heterogeneously labeled data for robust splenomegaly segmentation.
  • The novel adaptive loss function demonstrates significant potential for training deep networks on diverse medical imaging datasets.
  • This approach offers a promising solution for overcoming data scarcity in medical image analysis and is applicable beyond abdominal imaging.