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肝脏立体定向放疗计划中整合基于呼吸门控PET的靶区勾画:一项初步研究

Integrating respiratory-gated PET-based target volume delineation in liver SBRT planning, a pilot study.

作者信息

Riou Olivier, Serrano Benjamin, Azria David, Paulmier Benoit, Villeneuve Remy, Fenoglietto Pascal, Artenie Antonella, Ortholan Cécile, Faraggi Marc, Thariat Juliette

机构信息

Radiotherapy Department, Montpellier Cancer Institute - Val d'Aurelle, 208 rue des Apothicaires, F-34298 Montpellier Cedex 5, France.

出版信息

Radiat Oncol. 2014 Jun 2;9:127. doi: 10.1186/1748-717X-9-127.

DOI:10.1186/1748-717X-9-127
PMID:24885897
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4050417/
Abstract

BACKGROUND

To assess the feasibility and benefit of integrating four-dimensional (4D) Positron Emission Tomography (PET) - computed tomography (CT) for liver stereotactic body radiation therapy (SBRT) planning.

METHODS

8 patients with 14 metastases were accrued in the study. They all underwent a non-gated PET and a 4D PET centered on the liver. The same CT scan was used for attenuation correction, registration, and considered the planning CT for SBRT planning. Six PET phases were reconstructed for each 4D PET. By applying an individualized threshold to the 4D PET, a Biological Internal Target Volume (BITV) was generated for each lesion. A gated Planning Target Volume (PTVg) was created by adding 3 mm to account for set-up margins. This volume was compared to a manual Planning Target Volume (PTV) delineated with the help of a semi-automatic Biological Target Volume (BTV) obtained from the non-gated exam. A 5 mm radial and a 10 mm craniocaudal margins were applied to account for tumor motion and set-up margins to create the PTV.

RESULTS

One undiagnosed liver metastasis was discovered thanks to the 4D PET. The semi-automatic BTV were significantly smaller than the BITV (p = 0.0031). However, after applying adapted margins, 4D PET allowed a statistically significant decrease in the PTVg as compared to the PTV (p = 0.0052).

CONCLUSIONS

In comparison to non-gated PET, 4D PET may better define the respiratory movements of liver targets and improve SBRT planning for liver metastases. Furthermore, non respiratory-gated PET exams can both misdiagnose liver metastases and underestimate the real internal target volumes.

摘要

背景

评估将四维(4D)正电子发射断层扫描(PET)与计算机断层扫描(CT)相结合用于肝脏立体定向体部放射治疗(SBRT)计划的可行性和益处。

方法

本研究纳入了8例有14处转移灶的患者。他们均接受了非门控PET检查以及以肝脏为中心的4D PET检查。使用相同的CT扫描进行衰减校正、配准,并将其视为SBRT计划的计划CT。对每个4D PET重建六个PET时相。通过对4D PET应用个体化阈值,为每个病灶生成生物内部靶区体积(BITV)。通过增加3 mm以考虑摆位边界来创建门控计划靶区体积(PTVg)。将该体积与借助从非门控检查获得的半自动生物靶区体积(BTV)勾勒出的手动计划靶区体积(PTV)进行比较。应用5 mm的径向边界和10 mm的头脚向边界以考虑肿瘤运动和摆位边界来创建PTV。

结果

通过4D PET发现了一处未被诊断出的肝转移灶。半自动BTV明显小于BITV(p = 0.0031)。然而,在应用适当的边界后,与PTV相比,4D PET使PTVg在统计学上有显著减小(p = 0.0052)。

结论

与非门控PET相比,4D PET可能能更好地定义肝脏靶区的呼吸运动,并改善肝转移灶的SBRT计划。此外,非呼吸门控PET检查可能会误诊肝转移灶并低估实际的内部靶区体积。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/8886/4050417/6c24a3b17abb/1748-717X-9-127-1.jpg

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