利用统计过程控制技术对1.5T MR-Linac进行长期性能评价。

IF 3.3 2区医学 Q2 ONCOLOGY

Radiation Oncology Pub Date : 2025-06-07 DOI:10.1186/s13014-025-02670-3

Qing Xiao, Mengdie Shen, Guangjun Li, Shipai Zhu, Jinrong He, Qiang Wang, Guyu Dai, Hang Yu, Jialu Lai, Renming Zhong, Sen Bai

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引用次数: 0

摘要

背景：磁共振成像与线性加速器（Linacs）的集成通过提供实时成像来提高治疗精度，从而增强了自适应放疗。然而，MR-Linac系统的长期性能，特别是在临床环境中，仍然没有得到充分的研究。传统的质量保证（QA）方法依赖于二元合格/不合格标准，可能会忽略关键的系统变化。本研究应用统计过程控制（SPC）技术来评估1.5T MR- linac的长期性能，重点关注波束质量、MR- mv对准、MR成像和几何畸变的优化。方法：双阶段SPC框架应用于Elekta Unity MR-Linac的1年每日和每周QA数据。第一阶段建立了性能基准，第二阶段在线监测偏差。评估参数包括光束输出、对称性、mr - mv对准、信噪比（SNR）、空间线性度、切片轮廓和球面体积（dsv）的几何畸变。稳定性和可变性采用控制图和过程性能指标（Ppk）进行量化。结果：光束质量总体稳定（Ppk≥1.33），但输出剂量和横向对称在II期变异性增加，剂量Ppk从3.13下降到1.33。mr - mv对准是一致的，但Phi旋转和Z平移偏移量在系统升级后表现出变化。成像指标，包括信噪比和空间线性度，在II期达到A +性能（Ppk≥1.67），而垂直空间分辨率较低（Ppk 1.04-1.10）。几何畸变得到很好的控制，但较大的dsv（≥500 mm）与RL （1.37 mm）和FH （0.93 mm）相比，ap轴畸变增加（2.44 mm）。结论：SPC技术动态识别稳定的参数和需要改进的领域。主要建议包括增强光束质量和mr - mv偏移的对准协议，以及解决更大体积和沿AP轴的几何畸变的有针对性的策略。

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Long-term performance evaluation of a 1.5T MR-Linac using statistical process control techniques.

Background: The integration of magnetic resonance imaging with linear accelerators (Linacs) enhances adaptive radiotherapy by providing real-time imaging for improved treatment precision. However, the long-term performance of MR-Linac systems, particularly in clinical settings, remains insufficiently studied. Traditional quality assurance (QA) methods, relying on binary pass/fail criteria, may overlook critical system variations. This study applies statistical process control (SPC) techniques to evaluate the long-term performance of a 1.5T MR-Linac, focusing on optimization in beam quality, MR-to-MV alignment, MR imaging, and geometric distortion.

Methods: A dual-phase SPC framework was applied to 1 year of daily and weekly QA data from an Elekta Unity MR-Linac. Phase I established performance benchmarks, while Phase II monitored deviations online. Evaluated parameters included beam output, symmetry, MR-to-MV alignment, signal-to-noise ratio (SNR), spatial linearity, slice profile, and geometric distortion across spherical volumes (DSVs). Stability and variability were quantified using control charts and process performance indices (Ppk).

Results: Beam quality was stable overall (Ppk ≥ 1.33), though output dose and transverse symmetry showed increased variability in Phase II, with dose Ppk declining from 3.13 to 1.33. MR-to-MV alignment was consistent, but Phi rotational and Z translational offsets showed variability after system upgrades. Imaging metrics, including SNR and spatial linearity, achieved A + performance (Ppk ≥ 1.67) in Phase II, while vertical spatial resolution was lower (Ppk 1.04-1.10). Geometric distortion was well-controlled, though larger DSVs (≥ 500 mm) showed increased AP-axis distortion (2.44 mm) compared to RL (1.37 mm) and FH (0.93 mm).

Conclusions: SPC techniques dynamically identified stable parameters and areas for improvement. Key recommendations include enhanced alignment protocols for beam quality and MR-to-MV offsets, as well as targeted strategies to address geometric distortion in larger volumes and along the AP axis.

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来源期刊

Radiation Oncology ONCOLOGY-RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

CiteScore

6.50

自引率

2.80%

发文量

181

审稿时长

3-6 weeks

期刊介绍： Radiation Oncology encompasses all aspects of research that impacts on the treatment of cancer using radiation. It publishes findings in molecular and cellular radiation biology, radiation physics, radiation technology, and clinical oncology.