Direct Cup-to-Disc Ratio Estimation for Glaucoma Screening via Semi-Supervised Learning

Glaucoma is a chronic eye disease that leads to irreversible vision loss. The Cup-to-Disc Ratio (CDR) serves as the most important indicator for glaucoma screening and plays a significant role in clinical screening and early diagnosis of glaucoma. In general, obtaining CDR is subjected to measuring on manually or automatically segmented optic disc and cup. Despite great efforts have been devoted, obtaining CDR values automatically with high accuracy and robustness is still a great challenge due to the heavy overlap between optic cup and neuroretinal rim regions. In this paper, a direct CDR estimation method is proposed based on the well-designed semi-supervised learning scheme, in which CDR estimation is formulated as a general regression problem while optic disc/cup segmentation is cancelled. The method directly regresses CDR value based on the feature representation of optic nerve head via deep learning technique while bypassing intermediate segmentation. The scheme is a two-stage cascaded approach comprised of two phases: unsupervised feature representation of fundus image with a convolutional neural networks (MFPPNet) and CDR value regression by random forest regressor. The proposed scheme is validated on the challenging glaucoma dataset Direct-CSU and public ORIGA, and the experimental results demonstrate that our method can achieve a lower average CDR error of 0.0563 and a higher correlation of around 0.726 with measurement before manual segmentation of optic disc/cup by human experts. Our estimated CDR values are also tested for glaucoma screening, which achieves the areas under curve of 0.905 on dataset of 421 fundus images. The experiments show that the proposed method is capable of state-of-the-art CDR estimation and satisfactory glaucoma screening with calculated CDR value.

[1]  Shuicheng Yan,et al.  Automatic Feature Learning for Glaucoma Detection Based on Deep Learning , 2015, MICCAI.

[2]  Elijah Blessing Rajsingh,et al.  An empirical study on optic disc segmentation using an active contour model , 2015, Biomed. Signal Process. Control..

[3]  Baihua Li,et al.  A Novel Adaptive Deformable Model for Automated Optic Disc and Cup Segmentation to Aid Glaucoma Diagnosis , 2017, Journal of Medical Systems.

[4]  Amit Kale,et al.  Automatic Optic Disk and Cup Segmentation of Fundus Images Using Deep Learning , 2018, 2018 25th IEEE International Conference on Image Processing (ICIP).

[5]  U. Rajendra Acharya,et al.  Automated Diagnosis of Glaucoma Using Texture and Higher Order Spectra Features , 2011, IEEE Transactions on Information Technology in Biomedicine.

[6]  Chenyu Shi,et al.  Automatic Determination of Vertical Cup-to-Disc Ratio in Retinal Fundus Images for Glaucoma Screening , 2019, IEEE Access.

[7]  Bin Gu,et al.  Direct Estimation of Cardiac Biventricular Volumes With an Adapted Bayesian Formulation , 2014, IEEE Transactions on Biomedical Engineering.

[8]  Jianwen Luo,et al.  Robust Segmentation of Intima–Media Borders With Different Morphologies and Dynamics During the Cardiac Cycle , 2018, IEEE Journal of Biomedical and Health Informatics.

[9]  Tien Yin Wong,et al.  Superpixel Classification Based Optic Disc and Optic Cup Segmentation for Glaucoma Screening , 2013, IEEE Transactions on Medical Imaging.

[10]  Mamta Juneja,et al.  Survey on segmentation and classification approaches of optic cup and optic disc for diagnosis of glaucoma , 2018, Biomed. Signal Process. Control..

[11]  Tien Yin Wong,et al.  Similarity regularized sparse group lasso for cup to disc ratio computation. , 2017, Biomedical optics express.

[12]  Tien Yin Wong,et al.  Automatic optic disc segmentation with peripapillary atrophy elimination , 2011, 2011 Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[13]  Wufeng Xue,et al.  Direct Multitype Cardiac Indices Estimation via Joint Representation and Regression Learning , 2017, IEEE Transactions on Medical Imaging.

[14]  László G. Nyúl,et al.  Glaucoma risk index:  Automated glaucoma detection from color fundus images , 2010, Medical Image Anal..

[15]  Shen Zhao,et al.  Automatic spondylolisthesis grading from MRIs across modalities using faster adversarial recognition network , 2019, Medical Image Anal..

[16]  Xiantong Zhen,et al.  Direct and Simultaneous Four-Chamber Volume Estimation by Multi-Output Regression , 2015, MICCAI.

[17]  Dacheng Tao,et al.  Sparse Dissimilarity-Constrained Coding for Glaucoma Screening , 2015, IEEE Transactions on Biomedical Engineering.

[18]  Qing Liu,et al.  Optic Cup Segmentation Using Large Pixel Patch Based CNNs , 2016 .

[19]  Jayanthi Sivaswamy,et al.  1 & , 2001 .

[20]  Malay Kishore Dutta,et al.  Classification of glaucoma based on texture features using neural networks , 2014, 2014 Seventh International Conference on Contemporary Computing (IC3).

[21]  Giri Babu Kande,et al.  Segmentation of optic disk and optic cup from digital fundus images for the assessment of glaucoma , 2016, Biomed. Signal Process. Control..

[22]  Muhammad Sharif,et al.  Fundus Image Segmentation and Feature Extraction for the Detection of Glaucoma: A New Approach , 2017 .

[23]  Stephen Lin,et al.  Optic Cup Segmentation for Glaucoma Detection Using Low-Rank Superpixel Representation , 2014, MICCAI.

[24]  Jui-Kai Wang,et al.  Multimodal Segmentation of Optic Disc and Cup From SD-OCT and Color Fundus Photographs Using a Machine-Learning Graph-Based Approach , 2015, IEEE Transactions on Medical Imaging.

[25]  Antonio Criminisi,et al.  Decision Forests for Computer Vision and Medical Image Analysis , 2013, Advances in Computer Vision and Pattern Recognition.

[26]  Wufeng Xue,et al.  Full left ventricle quantification via deep multitask relationships learning , 2018, Medical Image Anal..

[27]  Jayanthi Sivaswamy,et al.  Optic disk and cup boundary detection using regional information , 2010, 2010 IEEE International Symposium on Biomedical Imaging: From Nano to Macro.

[28]  Jiwen Lu,et al.  Learning Compact Binary Descriptors with Unsupervised Deep Neural Networks , 2016, 2016 IEEE Conference on Computer Vision and Pattern Recognition (CVPR).

[29]  Juan Xu,et al.  Automated Optic Disk Boundary Detection by Modified Active Contour Model , 2007, IEEE Transactions on Biomedical Engineering.

[30]  Leo Breiman,et al.  Random Forests , 2001, Machine Learning.

[31]  Luc Van Gool,et al.  Deep Retinal Image Understanding , 2016, MICCAI.

[32]  Tien Yin Wong,et al.  Automated segmentation of optic disc and optic cup in fundus images for glaucoma diagnosis , 2012, 2012 25th IEEE International Symposium on Computer-Based Medical Systems (CBMS).

[33]  Jayanthi Sivaswamy,et al.  Optic Disk and Cup Segmentation From Monocular Color Retinal Images for Glaucoma Assessment , 2011, IEEE Transactions on Medical Imaging.

[34]  Jian Sun,et al.  Spatial Pyramid Pooling in Deep Convolutional Networks for Visual Recognition , 2014, IEEE Transactions on Pattern Analysis and Machine Intelligence.