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Accelerating direct material decomposition via diffusion probabilistic model for Sparse-view spectral computed

Jie Guo1, Ailong Cai1, Junru Ren1

  • 1Henan Key Laboratory of Imaging and Intelligent Processing, PLA Information Engineering University, Zhengzhou, China.

Journal of X-Ray Science and Technology
|October 28, 2025
PubMed
Summary
This summary is machine-generated.

This study introduces an unsupervised deep learning method for spectral computed tomography (Spectral CT) material decomposition. The novel approach enhances image quality and accuracy, even with sparse data and geometric inconsistencies.

Keywords:
diffusion probabilistic modelsmaterial decompositionspectral CTvirtual monochromatic image

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Area of Science:

  • Medical Imaging
  • Computational Imaging
  • Artificial Intelligence in Medicine

Background:

  • Accurate material decomposition is crucial for Spectral CT applications.
  • Conventional methods struggle with sparse-view artifacts, slow convergence, noise, and ill-posedness, especially in geometrically inconsistent imaging.

Purpose of the Study:

  • To develop an unsupervised deep learning framework for direct material decomposition in sparse-view Spectral CT.
  • To overcome limitations of conventional model-based methods using virtual monochromatic images (VMIs) and probabilistic diffusion models.

Main Methods:

  • Proposed an unsupervised deep learning framework optimizing VMIs via a probabilistic diffusion model for material decomposition.
  • Integrated VMIs to enhance differentiation of polychromatic projections and address iterative reconstruction convergence issues.
  • Employed dual constraints: data fidelity for measurement consistency and probabilistic regularization for anatomical plausibility.

Main Results:

  • Achieved a 10 dB improvement in peak-signal-to-noise ratio (PSNR) and a 4.31% increase in structural similarity (SSIM) for soft-tissue reconstructions compared to existing methods with 90 projections.
  • Demonstrated robustness and maintained reconstruction fidelity under sparse sampling and geometric inconsistency.
  • Validated effectiveness on preclinical data.

Conclusions:

  • The proposed deep learning framework significantly improves material decomposition in sparse-view Spectral CT.
  • The method offers enhanced accuracy and robustness, overcoming key challenges in current techniques.
  • This approach holds promise for advancing Spectral CT applications requiring high-fidelity material decomposition.