潜伏空间使复杂放疗计划中基于变压器的剂量预测成为可能

arXiv - PHYS - Medical Physics Pub Date : 2024-07-11 DOI:arxiv-2407.08650

Edward Wang, Ryan Au, Pencilla Lang, Sarah A. Mattonen

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引用次数: 0

摘要

越来越多的证据表明，使用立体定向烧蚀体外放射治疗（SABR）可以治疗肺部的多个癌症病灶。肺部多病灶 SABR 计划非常复杂，需要大量资源来创建。在这项工作中，我们提出了一种新颖的两阶段潜变框架（LDFormer），用于对不同病灶数量的肺部 SABR 计划进行剂量预测。在第一阶段，患者的解剖信息和剂量分布被编码到一个潜空间中。在第二阶段，转换器从解剖潜变量中学习预测剂量潜变量。对因果注意进行修改，以适应不同数量的病变。在病灶内和病灶周围的剂量一致性方面，LDFormer优于最先进的生成式对抗网络，当考虑到重叠病灶时，性能差距拉大。LDFormer 能在不到 30 秒的时间内生成三维剂量分布的预测结果，它有望帮助医生做出临床决策、降低资源成本并加快治疗计划的制定。

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Latent Spaces Enable Transformer-Based Dose Prediction in Complex Radiotherapy Plans

Evidence is accumulating in favour of using stereotactic ablative body radiotherapy (SABR) to treat multiple cancer lesions in the lung. Multi-lesion lung SABR plans are complex and require significant resources to create. In this work, we propose a novel two-stage latent transformer framework (LDFormer) for dose prediction of lung SABR plans with varying numbers of lesions. In the first stage, patient anatomical information and the dose distribution are encoded into a latent space. In the second stage, a transformer learns to predict the dose latent from the anatomical latents. Causal attention is modified to adapt to different numbers of lesions. LDFormer outperforms a state-of-the-art generative adversarial network on dose conformality in and around lesions, and the performance gap widens when considering overlapping lesions. LDFormer generates predictions of 3-D dose distributions in under 30s on consumer hardware, and has the potential to assist physicians with clinical decision making, reduce resource costs, and accelerate treatment planning.

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arXiv - PHYS - Medical Physics

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