What does AI see? Deep segmentation networks discover biomarkers for lung cancer survival

Non-small-cell lung cancer (NSCLC) represents approximately 80-85% of lung cancer diagnoses and is the leading cause of cancer-related death worldwide. Recent studies indicate that image-based radiomics features from positron emission tomography-computed tomography (PET/CT) images have predictive power on NSCLC outcomes. To this end, easily calculated functional features such as the maximum and the mean of standard uptake value (SUV) and total lesion glycolysis (TLG) are most commonly used for NSCLC prognostication, but their prognostic value remains controversial. Meanwhile, convolutional neural networks (CNN) are rapidly emerging as a new premise for cancer image analysis, with significantly enhanced predictive power compared to other hand-crafted radiomics features. Here we show that CNN trained to perform the tumor segmentation task, with no other information than physician contours, identify a rich set of survival-related image features with remarkable prognostic value. In a retrospective study on 96 NSCLC patients before stereotactic-body radiotherapy (SBRT), we found that the CNN segmentation algorithm (U-Net) trained for tumor segmentation in PET/CT images, contained features having strong correlation with 2- and 5-year overall and disease-specific survivals. The U-net algorithm has not seen any other clinical information (e.g. survival, age, smoking history) than the images and the corresponding tumor contours provided by physicians. Furthermore, through visualization of the U-Net, we also found convincing evidence that the regions of progression appear to match with the regions where the U-Net features identified patterns that predicted higher likelihood of death. We anticipate our findings will be a starting point for more sophisticated non-intrusive patient specific cancer prognosis determination.

[1]  Guangtao Zhai,et al.  A Deep Learning-Based Radiomics Model for Prediction of Survival in Glioblastoma Multiforme , 2017, Scientific Reports.

[2]  Osama Mawlawi,et al.  Stage III Non-Small Cell Lung Cancer: Prognostic Value of FDG PET Quantitative Imaging Features Combined with Clinical Prognostic Factors. , 2016, Radiology.

[3]  Johannes A. Langendijk,et al.  Clinical Investigation : Thoracic Cancer Residual 18 F-FDG-PET Uptake 12 Weeks After Stereotactic Ablative Radiotherapy for Stage I Non-Small-Cell Lung Cancer Predicts Local Control , 2012 .

[4]  Philippe Lambin,et al.  F-fluorodeoxyglucose positron-emission tomography (FDG-PET)-Radiomics of metastatic lymph nodes and primary tumor in non-small cell lung cancer (NSCLC) – A prospective externally validated study , 2018 .

[5]  David M Jablons,et al.  Lung Cancer Staging and Prognosis. , 2016, Cancer treatment and research.

[6]  Matthias Bethge,et al.  ImageNet-trained CNNs are biased towards texture; increasing shape bias improves accuracy and robustness , 2018, ICLR.

[7]  Satoshi Hattori,et al.  Prognostic significance of total lesion glycolysis in patients with advanced non-small cell lung cancer receiving chemotherapy. , 2012, European journal of radiology.

[8]  Hae-Sang Park,et al.  A simple and fast algorithm for K-medoids clustering , 2009, Expert Syst. Appl..

[9]  J. Seuntjens,et al.  Deep learning in head & neck cancer outcome prediction , 2019, Scientific Reports.

[10]  Marianne Paesmans,et al.  Prognosis of Small Cell Lung Cancer , 2004 .

[11]  Samuel H. Hawkins,et al.  Deep Feature Transfer Learning in Combination with Traditional Features Predicts Survival Among Patients with Lung Adenocarcinoma , 2016, Tomography.

[12]  P. Rousseeuw Silhouettes: a graphical aid to the interpretation and validation of cluster analysis , 1987 .

[13]  Masoom A. Haider,et al.  Radiomics-based Prognosis Analysis for Non-Small Cell Lung Cancer , 2017, Scientific Reports.

[14]  B. C. Penney,et al.  Prognostic value of metabolic tumor burden from (18)F-FDG PET in surgical patients with non-small-cell lung cancer. , 2013, Academic radiology.

[15]  E. V. van Beek,et al.  Radiomics and its emerging role in lung cancer research, imaging biomarkers and clinical management: State of the art. , 2017, European journal of radiology.

[16]  B. C. Penney,et al.  Prognostic value of metabolic tumor burden on 18F-FDG PET in nonsurgical patients with non-small cell lung cancer , 2011, European Journal of Nuclear Medicine and Molecular Imaging.

[17]  M. Agarwal,et al.  Revisiting the prognostic value of preoperative 18F-fluoro-2-deoxyglucose (18F-FDG) positron emission tomography (PET) in early-stage (I & II) non-small cell lung cancers (NSCLC) , 2009, European Journal of Nuclear Medicine and Molecular Imaging.

[18]  Esther G.C. Troost,et al.  Applicability of a prognostic CT-based radiomic signature model trained on stage I-III non-small cell lung cancer in stage IV non-small cell lung cancer. , 2018, Lung cancer.

[19]  Vicky Goh,et al.  Quantifying tumour heterogeneity in 18F-FDG PET/CT imaging by texture analysis , 2012, European Journal of Nuclear Medicine and Molecular Imaging.

[20]  R. Tibshirani Regression Shrinkage and Selection via the Lasso , 1996 .

[21]  Farzad Khalvati,et al.  Radiomics analysis at PET/CT contributes to prognosis of recurrence and survival in lung cancer treated with stereotactic body radiotherapy , 2018, Scientific Reports.

[22]  Hod Lipson,et al.  Understanding Neural Networks Through Deep Visualization , 2015, ArXiv.

[23]  Junjie Bai,et al.  Multi-scale segmentation using deep graph cuts: Robust lung tumor delineation in MVCBCT , 2018, 2018 IEEE 15th International Symposium on Biomedical Imaging (ISBI 2018).

[24]  Leixin Zhou,et al.  Simultaneous cosegmentation of tumors in PET‐CT images using deep fully convolutional networks , 2019, Medical physics.

[25]  Thomas Brox,et al.  U-Net: Convolutional Networks for Biomedical Image Segmentation , 2015, MICCAI.

[26]  C Huang,et al.  Feasibility study of FDG PET/CT-derived primary tumour glycolysis as a prognostic indicator of survival in patients with non-small-cell lung cancer. , 2014, Clinical radiology.

[27]  John L. Humm,et al.  Tumor Treatment Response Based on Visual and Quantitative Changes in Global Tumor Glycolysis Using PET-FDG Imaging. The Visual Response Score and the Change in Total Lesion Glycolysis. , 1999, Clinical positron imaging : official journal of the Institute for Clinical P.E.T.

[28]  C. Reddy,et al.  Maximum standardized uptake value from staging FDG-PET/CT does not predict treatment outcome for early-stage non-small-cell lung cancer treated with stereotactic body radiotherapy. , 2010, International journal of radiation oncology, biology, physics.

[29]  Hiroshi Onishi,et al.  Volume-based parameters measured by using FDG PET/CT in patients with stage I NSCLC treated with stereotactic body radiation therapy: prognostic value. , 2013, Radiology.

[30]  Jonas Kubilius,et al.  Deep Neural Networks as a Computational Model for Human Shape Sensitivity , 2016, PLoS Comput. Biol..

[31]  Johanna Uthoff,et al.  Machine learning approach for distinguishing malignant and benign lung nodules utilizing standardized perinodular parenchymal features from CT. , 2019, Medical physics.

[32]  Olaf Ronneberger,et al.  Invited Talk: U-Net Convolutional Networks for Biomedical Image Segmentation , 2017, Bildverarbeitung für die Medizin.

[33]  Markus Voelter,et al.  State of the Art , 1997, Pediatric Research.

[34]  A. Jemal,et al.  Cancer statistics, 2018 , 2018, CA: a cancer journal for clinicians.

[35]  Junzhou Huang,et al.  Imaging Biomarker Discovery for Lung Cancer Survival Prediction , 2016, MICCAI.

[36]  Nan-Tsing Chiu,et al.  Prognostic value of whole-body total lesion glycolysis at pretreatment FDG PET/CT in non-small cell lung cancer. , 2012, Radiology.

[37]  R. Gillies,et al.  Deep learning for lung cancer prognostication: A retrospective multi-cohort radiomics study , 2018, PLoS medicine.