通过结合CT、FDG PET和动态对比增强CT预测非小细胞肺癌中的肿瘤缺氧情况。
Predicting tumor hypoxia in non-small cell lung cancer by combining CT, FDG PET and dynamic contrast-enhanced CT.
作者信息
Even Aniek J G, Reymen Bart, La Fontaine Matthew D, Das Marco, Jochems Arthur, Mottaghy Felix M, Belderbos José S A, De Ruysscher Dirk, Lambin Philippe, van Elmpt Wouter
机构信息
a Department of Radiation Oncology (MAASTRO), GROW-School for Oncology and Developmental Biology , Maastricht University Medical Center , Maastricht , The Netherlands.
b Department of Radiation Oncology , The Netherlands Cancer Institute , Amsterdam , The Netherlands.
出版信息
Acta Oncol. 2017 Nov;56(11):1591-1596. doi: 10.1080/0284186X.2017.1349332. Epub 2017 Aug 25.
BACKGROUND
Most solid tumors contain inadequately oxygenated (i.e., hypoxic) regions, which tend to be more aggressive and treatment resistant. Hypoxia PET allows visualization of hypoxia and may enable treatment adaptation. However, hypoxia PET imaging is expensive, time-consuming and not widely available. We aimed to predict hypoxia levels in non-small cell lung cancer (NSCLC) using more easily available imaging modalities: FDG-PET/CT and dynamic contrast-enhanced CT (DCE-CT).
MATERIAL AND METHODS
For 34 NSCLC patients, included in two clinical trials, hypoxia HX4-PET/CT, planning FDG-PET/CT and DCE-CT scans were acquired before radiotherapy. Scans were non-rigidly registered to the planning CT. Tumor blood flow (BF) and blood volume (BV) were calculated by kinetic analysis of DCE-CT images. Within the gross tumor volume, independent clusters, i.e., supervoxels, were created based on FDG-PET/CT. For each supervoxel, tumor-to-background ratios (TBR) were calculated (median SUV/aorta SUV) for HX4-PET/CT and supervoxel features (median, SD, entropy) for the other modalities. Two random forest models (cross-validated: 10 folds, five repeats) were trained to predict the hypoxia TBR; one based on CT, FDG, BF and BV, and one with only CT and FDG features. Patients were split in a training (trial NCT01024829) and independent test set (trial NCT01210378). For each patient, predicted, and observed hypoxic volumes (HV) (TBR > 1.2) were compared.
RESULTS
Fifteen patients (3291 supervoxels) were used for training and 19 patients (1502 supervoxels) for testing. The model with all features (RMSE training: 0.19 ± 0.01, test: 0.27) outperformed the model with only CT and FDG-PET features (RMSE training: 0.20 ± 0.01, test: 0.29). All tumors of the test set were correctly classified as normoxic or hypoxic (HV > 1 cm) by the best performing model.
CONCLUSIONS
We created a data-driven methodology to predict hypoxia levels and hypoxia spatial patterns using CT, FDG-PET and DCE-CT features in NSCLC. The model correctly classifies all tumors, and could therefore, aid tumor hypoxia classification and patient stratification.
背景
大多数实体瘤都包含氧合不足(即缺氧)区域,这些区域往往更具侵袭性且对治疗有抗性。缺氧正电子发射断层扫描(PET)可实现缺氧情况的可视化,并可能有助于调整治疗方案。然而,缺氧PET成像成本高昂、耗时且未广泛应用。我们旨在使用更容易获得的成像方式:氟代脱氧葡萄糖正电子发射断层扫描/计算机断层扫描(FDG-PET/CT)和动态对比增强计算机断层扫描(DCE-CT)来预测非小细胞肺癌(NSCLC)中的缺氧水平。
材料与方法
对于纳入两项临床试验的34例NSCLC患者,在放疗前进行缺氧HX4-PET/CT、计划FDG-PET/CT和DCE-CT扫描。扫描图像与计划CT进行非刚性配准。通过对DCE-CT图像进行动力学分析计算肿瘤血流(BF)和血容量(BV)。在大体肿瘤体积内,基于FDG-PET/CT创建独立的聚类,即超体素。对于每个超体素,计算HX4-PET/CT的肿瘤与背景比值(TBR)(中位标准摄取值/主动脉标准摄取值)以及其他成像方式的超体素特征(中位数、标准差、熵)。训练两个随机森林模型(交叉验证:10折,重复5次)来预测缺氧TBR;一个基于CT、FDG、BF和BV,另一个仅基于CT和FDG特征。将患者分为训练集(试验NCT01024829)和独立测试集(试验NCT01210378)。对于每位患者,比较预测的和观察到的缺氧体积(HV)(TBR>1.2)。
结果
15例患者(3291个超体素)用于训练,19例患者(1502个超体素)用于测试。具有所有特征的模型(训练集均方根误差:0.19±0.01,测试集:0.27)优于仅具有CT和FDG-PET特征的模型(训练集均方根误差:0.20±0.01,测试集:0.29)。表现最佳的模型将测试集中所有肿瘤正确分类为正常氧合或缺氧(HV>1 cm)。
结论
我们创建了一种数据驱动的方法,利用NSCLC中的CT、FDG-PET和DCE-CT特征预测缺氧水平和缺氧空间模式。该模型能正确分类所有肿瘤,因此有助于肿瘤缺氧分类和患者分层。
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