The optimal treatment strategy of newly diagnosed glioma is strongly influenced by tumour malignancy. Manual non-invasive grading based on MRI is not always accurate and biopsies to verify diagnosis negatively impact overall survival. In this paper, we propose a fully automatic 3D computer-aided diagnosis (CAD) system to non-invasively differentiate high-grade glioblastoma from lower-grade glioma. The approach consists of an automatic segmentation step to extract the tumour ROI followed by classification using a 3D convolutional neural network. Segmentation was performed using a 3D U-Net achieving a dice score of 88.53% which matches top performing algorithms in the BraTS 2018 challenge. The classification network was trained and evaluated on a large heterogeneous dataset of 549 patients reaching an accuracy of 91%. Additionally, the CAD system was evaluated on data from the Ghent University Hospital and achieved an accuracy of 92% which shows that the algorithm is robust to data from different centres

Decuyper, Milan

Van Holen, Roel

English

arXiv

Ghent University Academic Bibliography

Medical Imaging with Deep Learning 2019 MIDL 2019 – Extended Abstract TrackFully Automatic Binary Glioma Grading based onPre-Therapy MRI using 3D Convolutional Neural NetworksMilan Decuyper milan.decuyper@ugent.beand Roel Van Holen Roel.VanHolen@ugent.beMedical Image and Signal Processing (MEDISIP), Ghent University, Ghent, BelgiumAbstractThe optimal treatment strategy of newly diagnosed glioma is strongly influenced by tu-mour malignancy. Manual non-invasive grading based on MRI is not always accurate andbiopsies to verify diagnosis negatively impact overall survival. In this paper, we propose afully automatic 3D computer-aided diagnosis (CAD) system to non-invasively differentiatehigh-grade glioblastoma from lower-grade glioma. The approach consists of an automaticsegmentation step to extract the tumour ROI followed by classification using a 3D convo-lutional neural network. Segmentation was performed using a 3D U-Net achieving a dicescore of 88.53% which matches top performing algorithms in the BraTS 2018 challenge.The classification network was trained and evaluated on a large heterogeneous dataset of549 patients reaching an accuracy of 91%. Additionally, the CAD system was evaluatedon data from the Ghent University Hospital and achieved an accuracy of 92% which showsthat the algorithm is robust to data from different centres.Keywords: Deep Learning, CNN, Glioma Grading, MRI1. IntroductionTumour malignancy has a strong influence on therapy planning and prognosis of newlydiagnosed glioma. Whereas a watch-and-wait policy can be opted in case of low-gradeglioma, maximum safe resection combined with appropriate chemotherapy and radiotherapyis recommended by EANO for high-grade glioma (Weller et al., 2017). Differentiationbetween low- and high-grade glioma is usually based on MRI with gadolinium-based contrastagents. The presence of contrast enhancement and necrosis are indicative of higher tumourmalignancy, however 40-45% of non-enhancing lesions are subsequently found to be highlymalignant (Jansen et al., 2012). This results in reduced accuracy of non-invasive tumourgrading (sensitivities ranging between 55% and 83%). Biopsies to confirm histopathologicaldiagnosis negatively impact overall survival (Wijnenga et al., 2017) and hence accurate non-invasive grading is preferred. Most CAD methods for glioma grading reported today arenot fully automatic and often trained and evaluated on a small dataset from one clinicalcentre (Yang et al., 2018).In this study we designed a fully automatic computer-aided diagnosis system to non-invasively discriminate high-grade glioblastoma (GBM) from lower-grade glioma (WHOgrade II and III) using convolutional neural networks that are trained and evaluated on alarge multi-centre dataset.c© 2019 M. Decuyper & R. Van Holen.arXiv:1908.01506v1  [eess.IV]  5 Aug 2019Decuyper Van Holen2. Methods2.1. DataThe data used in the work originates from both public datasets and data that was retro-spectively acquired from the Ghent University Hospital, with permission of the local ethicscommittee (Belgian registration number B670201838395 2018/1500). The included pub-lic databases are the BraTS 2018 dataset (Menze et al., 2015; Bakas et al., 2017a) andthe TCGA-GBM (Scarpace et al., 2016), TCGA-LGG (Pedano et al., 2016) and LGG-1p19qDeletion (Erickson et al., 2017) collections on The Cancer Imaging Archive (Clarket al., 2013). Inclusion criteria were: a histologically proven glioma of WHO grade II, IIIor IV and the availability of a preoperative T1ce MRI together with a FLAIR and/or T2sequence of sufficient quality. In total 549 patients were acquired from the public databasesand 112 patients from the University Hospital resulting in data from 660 patients. All MRIwere co-registered, interpolated to 1 mm3 voxel sizes, bias corrected and skull-stripped us-ing SPM12. Each modality of every patient is independently normalised by subtracting themean and dividing by the standard deviation.2.2. SegmentationThe first part of the Grading system consists of segmenting the whole tumour volume. AsU-Nets have shown state-of-the-art performance for brain tumour segmentation in recentBraTS challenges, we implemented a 3D U-Net similar to the architecture proposed inIsensee et al. (2018) with 25 features at the highest resolution, instance normalisation andleaky ReLUs. The network was trained on random patches of size 128x128x128, batch size oftwo, ADAM optimisation (lrinit = 1·10−4), soft dice loss and L2 weight decay of 10−5. Fromthe 285 patients in the BraTS 2018 training data, 60 were used for validation. The networkwas finally evaluated on 76 patients from the TCGA-GBM and TCGA-LGG collectionsthat were included in the BraTS 2018 test data (Bakas et al., 2017b). For patients fromTCIA and the University Hospital, not all four MRI sequences (T1, T1ce, T2 and FLAIR)are always available. Therefore, during training, the T1 and the T2 or FLAIR channels arerandomly set to zero to increase robustness to missing modalities.2.3. GradingAfter segmentation, the glioma is classified as a glioblastoma or a lower-grade glioma (WHOgrade II or III). To this end, a tumour region of interest (ROI) is extracted from the T1ceMRI, resized to a size of 112x112x112 and subsequently fed into the classification network.The used network architecture (see Figure 1) consists of one convolutional layer with a kernelsize of 7 followed by 4 residual blocks. Every convolutional layer is succeeded with instancenormalisation and a ReLU layer. The network is trained using SGD (lrinit = 1 · 10−3,momentum = 0.9), L2 weight decay of 10−5 and a batch size of 8. To prevent overfitting,data augmentations like flipping, rotations, and padding were applied on the fly duringtraining. Four hundred patients were used for training (200 GBM and 200 LGG cases), 69for validation (35 GBM, 34 LGG) and 80 TCIA patients for final evaluation (34 GBM, 46LGG). We made sure that test patients were not used in the training set of the segmentationnetwork in order to evaluate the system on data that both parts have never seen before.2Automatic Glioma Grading based on Pre-Therapy MRI using 3D CNNsThe University Hospital data (63GBM, 49 LGG) was used to test the performance on a finalindependent dataset. Both the segmentation and classification networks were implementedin PyTorch and trained on an 11GB NVIDIA GTX 1080 Ti GPU.27x7x7 conv, 64 /23x3x3 conv, 643x3x3 conv, 64 3x3x3 conv, 128 /23x3x3 conv, 1283x3x3 conv, 256 /23x3x3 conv, 2563x3x3 conv, 512 /23x3x3 conv, 512Avgpoolfc 2Input 112x112x112Figure 1: Architecture used to classify a tumour ROI as GBM or LGG. Every convolutionallayer is succeeded with instance normalisation and a ReLU activation.3. Results and DiscussionThe obtained whole tumour dice scores on the 76 BraTS 2018 test patients were 88.53%,86.38% and 84.62% when providing all four modalities, only T1ce and FLAIR and onlyT1ce and T2 sequences as input respectively. These scores match the performance of state-of-the-art algorithms in the most recent BraTS 2018 challenge (Myronenko, 2018). Smallvariations between manual and predicted segmentations won’t have a strong influence onthe tumour ROI, making the obtained performance sufficient for the current task.The area under the ROC curve (AUC), matthews correlation coefficient (MCC), ac-curacy, sensitivity (percentage of GBM cases that are correctly classified as such) andspecificity scores on the TCIA test set and University Hospital data are shown in Table 1.These results indicate that, to the best of the authors’ knowledge, state-of-the-art gradingperformance is achieved using a system that is trained on a large heterogeneous dataset andis fully automatic. Moreover, the strong performance on independent data from the GhentUniversity Hospital shows that it is robust to variations in imaging protocols and data fromdifferent clinical centres.Table 1: Results of the binary glioma grading system on both data from TCIA and theGhent University HospitalDataset AUC MCC Acc. Sens. Spec.TCIA Test Data 96.29 82.19 91.25 91.18 91.30Ghent Univeristy Hospital Data 93.39 83.91 91.96 90.48 93.884. ConclusionIn this paper we presented a fully automatic 3D approach to classify glioma as a high gradeglioblastoma or lower-grade glioma based on pre-therapy structural MRI which has impor-tant value for optimal therapy planning and prognosis. The two-step procedure consistingof segmentation using a 3D U-Net and classification with a 3D residual network achievedstate-of-the-art results on a large heterogeneous dataset and generalises well to data fromdifferent centres.3Decuyper Van HolenReferencesSpyridon Bakas, Hamed Akbari, et al. Advancing The Cancer Genome Atlas glioma MRIcollections with expert segmentation labels and radiomic features. Scientific Data, 4:170117, sep 2017a. ISSN 2052-4463. doi: 10.1038/sdata.2017.117.Spyridon Bakas, Hamed Akbari, et al. Segmentation Labels and Radiomic Features for thePre-operative Scans of the TCGA-GBM collection. The Cancer Imaging Archive, 2017b.doi: 10.7937/K9/TCIA.2017.KLXWJJ1Q.Kenneth Clark, Bruce Vendt, et al. The Cancer Imaging Archive (TCIA): Maintaining andOperating a Public Information Repository. Journal of Digital Imaging, 26(6):1045–1057,dec 2013. ISSN 0897-1889. doi: 10.1007/s10278-013-9622-7.Bradley Erickson, Zeynettin Akkus, et al. Data From LGG-1p19qDeletion. The CancerImaging Archive, 2017. doi: 10.7937/K9/TCIA.2017.dwehtz9v.Fabian Isensee, Philipp Kickingereder, et al. No new-net. CoRR, abs/1809.10483, 2018.Nathalie L. Jansen, Vera Graute, et al. MRI-suspected low-grade glioma: is there a needto perform dynamic FET PET? European Journal of Nuclear Medicine and MolecularImaging, 39(6):1021–1029, jun 2012. ISSN 1619-7070. doi: 10.1007/s00259-012-2109-9.Bjoern H. Menze, Andras Jakab, et al. The Multimodal Brain Tumor Image SegmentationBenchmark (BRATS). IEEE Transactions on Medical Imaging, 34(10):1993–2024, oct2015. ISSN 0278-0062. doi: 10.1109/TMI.2014.2377694.Andriy Myronenko. 3d MRI brain tumor segmentation using autoencoder regularization.CoRR, abs/1810.11654, 2018.Nancy Pedano, Adam E. Flanders, et al. Radiology Data from The Cancer Genome AtlasLow Grade Glioma [TCGA-LGG] collection. jan 2016. doi: 10.7937/K9/TCIA.2016.L4LTD3TK.Lisa Scarpace, Tom Mikkelsen, and others. Radiology Data from The Cancer Genome AtlasGlioblastoma Multiforme [TCGA-GBM] collection. jan 2016. doi: 10.7937/K9/TCIA.2016.RNYFUYE9.Michael Weller, Martin van den Bent, et al. European Association for Neuro-Oncology(EANO) guideline on the diagnosis and treatment of adult astrocytic and oligodendroglialgliomas. The Lancet Oncology, 18(6):e315–e329, jun 2017. ISSN 1470-2045. doi: 10.1016/S1470-2045(17)30194-8.Maarten M J Wijnenga, Tariq Mattni, et al. Does early resection of presumed low-gradeglioma improve survival? A clinical perspective. Journal of neuro-oncology, 133(1):137–146, may 2017. ISSN 1573-7373. doi: 10.1007/s11060-017-2418-8.Yang Yang, Lin-Feng Yan, et al. Glioma Grading on Conventional MR Images: A DeepLearning Study With Transfer Learning. Frontiers in neuroscience, 12:804, 2018. ISSN1662-4548. doi: 10.3389/fnins.2018.00804.4

Fully automatic binary glioma grading based on pre-therapy MRI using 3D Convolutional Neural Networks

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Fully automatic binary glioma grading based on pre-therapy MRI using 3D Convolutional Neural Networks

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