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Physics-Inspired Generative Models in Medical Imaging.

Dennis Hein1,2, Afshin Bozorgpour3, Dorit Merhof3

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Physics-inspired generative models, including diffusion and Poisson flow models, are revolutionizing medical imaging. This review highlights their applications in reconstruction, generation, and analysis, paving the way for future advancements.

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Area of Science:

  • Medical Imaging
  • Artificial Intelligence
  • Computational Physics

Background:

  • Generative models (GMs) are increasingly vital in medical imaging.
  • Physics-inspired GMs, such as diffusion and Poisson flow models, offer enhanced Bayesian methods.
  • These models show significant promise for improving various medical imaging tasks.

Purpose of the Study:

  • To review the role of physics-inspired generative models in medical imaging.
  • To examine the accuracy, robustness, and acceleration of these models.
  • To outline future research directions for generative methods in this field.

Main Methods:

  • Review of denoising diffusion probabilistic models, score-based diffusion models, and Poisson flow generative models (PFGM++).
  • Analysis of model performance focusing on accuracy, robustness, and acceleration.
  • Exploration of applications in medical image reconstruction, generation, and analysis.

Main Results:

  • Physics-inspired GMs demonstrate significant utility across medical imaging applications.
  • Key models like diffusion and Poisson flow models show promise for enhanced performance.
  • The review identifies current capabilities and limitations of these advanced GMs.

Conclusions:

  • Physics-inspired GMs are transformative for medical imaging, enhancing Bayesian methods.
  • Future research should focus on unifying these models, integrating them with vision-language models, and exploring novel applications.
  • This review provides a timely overview to leverage the potential of physics-driven GMs in medical imaging.