Diffusion Schrödinger bridge models for high-quality MR-to-CT synthesis for proton treatment planning

IF 3.2 2区医学 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

Medical physics Pub Date : 2025-05-21 DOI:10.1002/mp.17898

Muheng Li, Xia Li, Sairos Safai, Antony J. Lomax, Ye Zhang

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引用次数: 0

Abstract

Background

In recent advancements in proton therapy, magnetic resonance (MR)-based treatment planning is gaining momentum due to its excellent soft tissue contrast and high potential to minimize extra radiation exposure compared to traditional computed tomography (CT)-based methods. This transition underscores the critical need for accurate MR-to-CT image synthesis, which is essential for precise proton dose calculations.

Purpose

This study aims to introduce and evaluate the diffusion Schrödinger bridge models (DSBM), an innovative approach for high-quality and efficient MR-to-CT synthesis, in order to improve both the quality and speed of synthetic CT (sCT) image generation.

Methods

The DSBM learns the nonlinear diffusion processes between MR and CT data distributions. Unlike traditional diffusion models (DMs), which start synthesis from a Gaussian distribution, DSBM starts from the prior distribution, enabling more direct and efficient synthesis. The model was trained on 46 head-and-neck (HN) MR-CT pairs and 77 brain tumor MR-CT pairs, with 8 and 10 scans used for testing, respectively. Comprehensive evaluations were conducted at both image and dosimetric levels, using metrics such as mean absolute error (MAE), Dice score, voxel-wise proton dose differences, gamma pass rates of clinical plans, and typical dose indices.

Results

For the HN dataset, DSBM achieved a lower MAE of 72.42 $\pm$ 9.78 Hounsfield unit (HU) compared to 77.72 $\pm$ 9.11 HU with the best baseline approach, and a higher Dice score for bone of 83.32 $\pm$ 3.25% compared to 82.55 $\pm$ 3.62%, indicating superior anatomical accuracy. Dosimetric evaluations showed a 1%/1 mm gamma pass rate of 95.85 $\pm$ 2.99%, surpassing the 95.25 $\pm$ 3.09% achieved by the baseline model. For the brain tumor dataset, DSBM outperformed the baseline with an MAE of 91.73 $\pm$ 6.86 HU compared to 103.25 $\pm$ 9.58 HU, and a Dice score for bone of 82.85 $\pm$ 3.88% compared to 81.27 $\pm$ 4.59%. DSBM also demonstrated a higher 1%/1 mm gamma pass rate of 97.93 $\pm$ 1.82%, confirming its robustness across different anatomical regions. Notably, DSBM achieved these results with very few number of neural function evaluation steps, significantly improving computational efficiency compared to standard DMs.

Conclusions

The DSBM demonstrates superior performance over traditional image synthesis methods in MR-based proton treatment planning. Its ability to generate high-quality sCT images with enhanced speed and accuracy highlights its potential as a valuable and efficient tool in various radiotherapy clinical scenarios.

Abstract Image

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扩散Schrödinger桥模型高质量的磁共振到ct合成质子治疗计划。

背景：在质子治疗的最新进展中，基于磁共振（MR）的治疗计划正获得动力，因为与传统的基于计算机断层扫描（CT）的方法相比，磁共振（MR）具有出色的软组织对比和最大限度地减少额外辐射暴露的潜力。这种转变强调了对精确的MR-to-CT图像合成的迫切需要，这对于精确的质子剂量计算至关重要。目的：为了提高合成CT （sCT）图像生成的质量和速度，本研究旨在介绍和评估一种高质量、高效的mr -CT合成的创新方法——扩散Schrödinger桥模型（DSBM）。方法：DSBM学习MR和CT数据分布之间的非线性扩散过程。与从高斯分布开始合成的传统扩散模型（DMs）不同，DSBM从先验分布开始，可以实现更直接和有效的合成。该模型以46对头颈部（HN） MR-CT对和77对脑肿瘤MR-CT对进行训练，分别使用8次和10次扫描进行测试。使用平均绝对误差（MAE）、Dice评分、体素质子剂量差、临床计划的伽马通过率和典型剂量指数等指标，在图像和剂量学水平上进行综合评估。结果：对于HN数据集，DSBM获得了较低的MAE，为72.42±$ $\pm$ 9.78 Hounsfield单位（HU），而最佳基线方法为77.72±$ $\pm$ 9.11 HU，骨骼的Dice评分为83.32±$ $\pm$ 3.25%，而82.55±$ $\pm$ 3.62%，表明具有更高的解剖准确性。剂量学评估显示1%/1 mm伽马通过率为95.85±$\pm$ 2.99%，超过基线模型的95.25±$\pm$ 3.09%。对于脑肿瘤数据集，DSBM优于基线，MAE为91.73±$\pm$ 6.86 HU，而103.25±$\pm$ 9.58 HU；骨骼的Dice评分为82.85±$\pm$ 3.88%，而81.27±$\pm$ 4.59%。DSBM还显示出更高的1%/1 mm伽马通通率97.93±1.82%，证实了其在不同解剖区域的稳健性。值得注意的是，DSBM以很少的神经功能评估步骤实现了这些结果，与标准dm相比，显着提高了计算效率。结论：DSBM在基于核磁共振的质子治疗计划中表现出优于传统图像合成方法的性能。它能够以更高的速度和准确性生成高质量的sCT图像，这突出了它作为各种放射治疗临床场景中有价值和有效的工具的潜力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Medical physics 医学-核医学

CiteScore

6.80

自引率

15.80%

发文量

660

审稿时长

1.7 months

期刊介绍： Medical Physics publishes original, high impact physics, imaging science, and engineering research that advances patient diagnosis and therapy through contributions in 1) Basic science developments with high potential for clinical translation 2) Clinical applications of cutting edge engineering and physics innovations 3) Broadly applicable and innovative clinical physics developments Medical Physics is a journal of global scope and reach. By publishing in Medical Physics your research will reach an international, multidisciplinary audience including practicing medical physicists as well as physics- and engineering based translational scientists. We work closely with authors of promising articles to improve their quality.