Feasibility and potential clinical benefit of dose de-escalation in stereotactic ablative radiotherapy for lung cancer lesions with ground glass opacities.

IF 3.4 Q2 ONCOLOGY

Physics and Imaging in Radiation Oncology Pub Date : 2024-11-29 eCollection Date: 2024-10-01 DOI:10.1016/j.phro.2024.100681

Carla Cases, Meritxell Mollà, Marcelo Sánchez, Mariana Benegas, Marc Ballestero, Sergi Serrano-Rueda, Gabriela Antelo, Carles Gomà

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Abstract

Introduction: Treatment of neoplasic lung nodules with ground glass opacities (GGO) faces two primary challenges. First, the standard practice of treating GGOs as solid nodules, which effectively controls the tumor locally, but might increase associated toxicities. The second is the potential for dose calculation errors related to increased heterogeneity. This study addresses the optimization of a dose de-escalation regime for stereotactic ablative radiotherapy (SABR) for GGO lesions.

Materials and methods: We used the CT scans of 35 patients (40 lesions) with some degree of GGO component treated at our institution between 2017 and 2021. We first assessed the dose calculation accuracy as a function of the GGO component of the lesion. We then analysed the advantages of a dose de-escalation regime in terms of lung dose reduction (Dmean, V20Gy and V300GyBED3) and plan robustness.

Results: We found a positive correlation between the presence of GGO and the dose calculation errors in a phantom scenario. These differences are reduced for patient data and in the presence of breathing motion. When using a de-escalation regime, significant reductions were achieved in mean lung dose, V20Gy and V300GyBED3. This study also revealed that lower doses in GGO areas lead to more stable fluence patterns, increasing treatment robustness.

Conclusions: The study lays the foundation for an eventual use of dose de-escalation in SABR for treating lung lesions with GGO, potentially leading to equivalent local control while reducing associated toxicities. These findings lay the groundwork for future clinical trials.

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立体定向消融放疗剂量递减治疗肺癌磨玻璃混浊的可行性及潜在临床效益。

治疗伴有磨玻璃混浊（GGO）的肿瘤性肺结节面临两个主要挑战。首先，将ggo作为实性结节治疗的标准做法，可以有效地局部控制肿瘤，但可能增加相关的毒性。第二是与异质性增加有关的剂量计算误差的可能性。本研究旨在优化立体定向消融放疗（SABR）治疗GGO病变的剂量递减方案。材料和方法：我们使用了2017年至2021年间在我院治疗的35例不同程度GGO成分患者（40个病变）的CT扫描。我们首先评估了剂量计算准确性作为病变GGO成分的函数。然后，我们分析了剂量递减方案在肺剂量减少（Dmean， V20Gy和v300r00bed3）和计划稳健性方面的优势。结果：我们发现幻像情景中GGO的存在与剂量计算误差呈正相关。这些差异在患者数据和呼吸运动的存在下减少。当使用降级方案时，平均肺剂量、V20Gy和v300r00bed3显著降低。该研究还表明，GGO区域的较低剂量导致更稳定的影响模式，增加了治疗的稳健性。结论：该研究为最终使用剂量递减法在SABR中使用GGO治疗肺部病变奠定了基础，可能导致等效的局部控制，同时减少相关毒性。这些发现为未来的临床试验奠定了基础。

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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