Convolutional Neural Network Model for Diabetic Retinopathy Feature Extraction and Classification (2310.10806v1)
Abstract: The application of Artificial Intelligence in the medical market brings up increasing concerns but aids in more timely diagnosis of silent progressing diseases like Diabetic Retinopathy. In order to diagnose Diabetic Retinopathy (DR), ophthalmologists use color fundus images, or pictures of the back of the retina, to identify small distinct features through a difficult and time-consuming process. Our work creates a novel CNN model and identifies the severity of DR through fundus image input. We classified 4 known DR features, including micro-aneurysms, cotton wools, exudates, and hemorrhages, through convolutional layers and were able to provide an accurate diagnostic without additional user input. The proposed model is more interpretable and robust to overfitting. We present initial results with a sensitivity of 97% and an accuracy of 71%. Our contribution is an interpretable model with similar accuracy to more complex models. With that, our model advances the field of DR detection and proves to be a key step towards AI-focused medical diagnosis.
- “Diabetic retinopathy–an historical review”. Semin. Ophthalmol., 16(1), Mar., pp. 2–7.
- “A short feature vector for image matching: The Log-Polar magnitude feature descriptor”. PLoS One, 12(11), Nov., p. e0188496.
- “Diabetic retinopathy classification using CNN and hybrid deep convolutional neural networks”. Symmetry (Basel), 14(9), Sept., p. 1932.
- “Convolutional neural networks for diabetic retinopathy”. Procedia Comput. Sci., 90, pp. 200–205.
- “Detection of diabetic retinopathy using custom CNN to segment the lesions”. Intell. Autom. Soft Comput., 33(2), pp. 837–853.
- “Detection of diabetic retinopathy using bichannel convolutional neural network”. J. Ophthalmol., 2020, June, p. 9139713.
- “Artificial intelligence (AI) acceptance in primary care during the coronavirus pandemic: What is the role of patients’ gender, age and health awareness? a two-phase pilot study”. Front. Public Health, 10, p. 931225.
- “Diverse patients’ attitudes towards artificial intelligence (AI) in diagnosis”. PLOS Digit. Health, 2(5), May, p. e0000237.
- “An integrative review on the acceptance of artificial intelligence among healthcare professionals in hospitals”. NPJ Digit. Med., 6(1), June, p. 111.
- “Deep convolutional neural networks for computer-aided detection: CNN architectures, dataset characteristics and transfer learning”. IEEE Trans. Med. Imaging, 35(5), May, pp. 1285–1298.
- “Convolutional neural networks: an overview and application in radiology”. Insights Imaging, 9(4), Aug., pp. 611–629.
- “Review of deep learning: concepts, CNN architectures, challenges, applications, future directions”. J. Big Data, 8(1), Mar., p. 53.
- “A deep learning mammography-based model for improved breast cancer risk prediction”. Radiology, 292(1), July, pp. 60–66.
- “Deep learning for FAST quality assessment”. J. Ultrasound Med., 42(1), Jan., pp. 71–79.
- “Boosting semi-supervised image segmentation with global and local mutual information regularization”. J. Mach. Learn. Biomed. Imaging, 1(MIDL 2020), June, pp. 1–29.
- “Transfer learning for diabetic retinopathy detection: A study of dataset combination and model performance”. Appl. Sci. (Basel), 13(9), May, p. 5685.
- “Image preprocessing in classification and identification of diabetic eye diseases”. Data Sci. Eng., 6(4), Aug., pp. 455–471.
- https://doi.org10.1016/j.procs.2018.05.069. Accessed: 2023-10-8.
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