4D 优化扫描碳离子束治疗肺癌中分次间变化的稳健性。

Robustness of 4D-optimized scanned carbon ion beam therapy against interfractional changes in lung cancer.

机构信息

GSI Helmholzzentrum für Schwerionenforschung GmbH, Darmstadt, Germany.

出版信息

Radiother Oncol. 2017 Mar;122(3):387-392. doi: 10.1016/j.radonc.2016.12.017. Epub 2017 Jan 7.

DOI:10.1016/j.radonc.2016.12.017

PMID:28073579

Abstract

BACKGROUND AND PURPOSE

Moving targets could be conformally treated with actively scanned carbon ion beams using 4D-optimization. As this heavily exploits 4D-CTs, an important question is whether the conformity also upholds in the context of interfractional changes, i.e. variable positioning, anatomy and breathing patterns.

MATERIALS AND METHODS

In 4 lung cancer patients, 6 weekly 4D-CTs were available. 4D-CTs and their phases were non-rigidly registered to propagate contours and 4D-doses. On the first 4D-CT, a 4D-optimized plan delivering a uniform dose to each motion phase (total dose 9.4Gy(RBE)) was simulated, as well as an ITV plan for comparison. On the five following 4D-CTs, 4D-dose was forward calculated and evaluated for target coverage and conformity. Variable uniform (3-7mm) and range margins (2mm/%) were investigated.

RESULTS

For all patients, target coverage (V95>95% accumulated over 5 fractions) could be achieved, but with variable margin size weakly depending on motion amplitude and range changes. The same margins were also necessary for ITV plans, which lead to lower conformity and higher integral doses.

CONCLUSION

4D-optimization appears feasible also under interfractional changes and maintains a dosimetric advantage over less conformal ITV irradiations. Further studies are needed to identify patients benefiting most from the technically more complex 4D-optimization.

摘要

背景与目的

使用 4D 优化，移动目标可以通过主动扫描碳离子束进行适形治疗。由于这大量利用了 4D-CT，一个重要的问题是，在分次间变化的情况下（即位置、解剖结构和呼吸模式的变化），适形性是否仍然存在。

材料与方法

在 4 例肺癌患者中，每周可获得 6 次 4D-CT。4D-CT 及其相位通过非刚性配准传递轮廓和 4D 剂量。在第一次 4D-CT 上，模拟了一个对每个运动相位均匀给药的 4D 优化计划（总剂量 9.4Gy(RBE)），以及一个 ITV 计划进行比较。在接下来的 5 次 4D-CT 中，对 4D 剂量进行了前向计算，并评估了靶区覆盖和适形性。研究了可变均匀（3-7mm）和范围边缘（2mm/％）。

结果

对于所有患者，都可以实现靶区覆盖（5 个分次累计超过 95%的 V95），但边缘大小随运动幅度和范围变化而变化。对于 ITV 计划也需要相同的边缘，这会导致适形性降低和积分剂量增加。

结论

4D 优化在分次间变化下也似乎是可行的，并且与不太适形的 ITV 照射相比具有剂量学优势。需要进一步的研究来确定最受益于技术上更复杂的 4D 优化的患者。

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4D 优化扫描碳离子束治疗肺癌中分次间变化的稳健性。

Robustness of 4D-optimized scanned carbon ion beam therapy against interfractional changes in lung cancer.

机构信息

出版信息

BACKGROUND AND PURPOSE

MATERIALS AND METHODS

RESULTS

CONCLUSION

背景与目的

材料与方法

结果

结论

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