Predicting tumor hypoxia in non-small cell lung cancer by combining CT, FDG PET and dynamic contrast-enhanced CT

Aniek J. G. Even; Bart Reymen; Matthew D. La Fontaine; Marco Das; Arthur Jochems; Felix M. Mottaghy; Jose S. A. Belderbos; Dirk De Ruysscher; Philippe Lambin; Wouter van Elmpt

doi:10.1080/0284186X.2017.1349332

Predicting tumor hypoxia in non-small cell lung cancer by combining CT, FDG PET and dynamic contrast-enhanced CT

Aniek J. G. Even^*, Bart Reymen, Matthew D. La Fontaine, Marco Das, Arthur Jochems, Felix M. Mottaghy, Jose S. A. Belderbos, Dirk De Ruysscher, Philippe Lambin, Wouter van Elmpt

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

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 SUVmean) 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> 1cm(3)) 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.

Original language	English
Pages (from-to)	1591-1596
Number of pages	6
Journal	Acta Oncologica
Volume	56
Issue number	11
DOIs	https://doi.org/10.1080/0284186X.2017.1349332
Publication status	Published - 2017
Event	15th Acta Oncologica Conference on Biology-Guided Adaptive Radiotherapy - The Helnan Marselis Hotel, Aarhus, Denmark Duration: 13 Jun 2017 → 16 Jun 2017

Keywords

IMPROVE RADIOTHERAPY
TARGETING HYPOXIA
DOSE-ESCALATION
MODEL
QUANTIFICATION
PATIENT
METABOLISM
THERAPY
NSCLC
TRIAL

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10.1080/0284186X.2017.1349332Licence: CC BY-NC-ND

Cite this

@article{3f4d3922cc2b403b94092742cd7362b7,

title = "Predicting tumor hypoxia in non-small cell lung cancer by combining CT, FDG PET and dynamic contrast-enhanced CT",

abstract = "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 SUVmean) 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> 1cm(3)) 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.",

keywords = "IMPROVE RADIOTHERAPY, TARGETING HYPOXIA, DOSE-ESCALATION, MODEL, QUANTIFICATION, PATIENT, METABOLISM, THERAPY, NSCLC, TRIAL",

author = "Even, {Aniek J. G.} and Bart Reymen and {La Fontaine}, {Matthew D.} and Marco Das and Arthur Jochems and Mottaghy, {Felix M.} and Belderbos, {Jose S. A.} and {De Ruysscher}, Dirk and Philippe Lambin and {van Elmpt}, Wouter",

year = "2017",

doi = "10.1080/0284186X.2017.1349332",

language = "English",

volume = "56",

pages = "1591--1596",

journal = "Acta Oncologica",

issn = "0284-186X",

publisher = "Routledge/Taylor & Francis Group",

number = "11",

note = "15th Acta Oncologica Conference on Biology-Guided Adaptive Radiotherapy, BiGART2017 ; Conference date: 13-06-2017 Through 16-06-2017",

}

TY - JOUR

T1 - Predicting tumor hypoxia in non-small cell lung cancer by combining CT, FDG PET and dynamic contrast-enhanced CT

AU - Even, Aniek J. G.

AU - Reymen, Bart

AU - La Fontaine, Matthew D.

AU - Das, Marco

AU - Jochems, Arthur

AU - Mottaghy, Felix M.

AU - Belderbos, Jose S. A.

AU - De Ruysscher, Dirk

AU - Lambin, Philippe

AU - van Elmpt, Wouter

PY - 2017

Y1 - 2017

N2 - 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 SUVmean) 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> 1cm(3)) 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.

AB - 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 SUVmean) 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> 1cm(3)) 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.

KW - IMPROVE RADIOTHERAPY

KW - TARGETING HYPOXIA

KW - DOSE-ESCALATION

KW - MODEL

KW - QUANTIFICATION

KW - PATIENT

KW - METABOLISM

KW - THERAPY

KW - NSCLC

KW - TRIAL

U2 - 10.1080/0284186X.2017.1349332

DO - 10.1080/0284186X.2017.1349332

M3 - Article

C2 - 28840770

SN - 0284-186X

VL - 56

SP - 1591

EP - 1596

JO - Acta Oncologica

JF - Acta Oncologica

IS - 11

T2 - 15th Acta Oncologica Conference on Biology-Guided Adaptive Radiotherapy

Y2 - 13 June 2017 through 16 June 2017

ER -