Retinal image blood vessel classification using hybrid deep learning in cataract diseased fundus images

•The proposed work introduces an effective hybrid deep learning technique for RBV segmentation and classification of vessels.•To attain higher classification accuracy, the most essential features are extracted through DenseNet, and the RBV is classified using ShuffleNet V2.•Several performance metri...

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Bibliographic Details
Published in:Biomedical signal processing and control 2023-07, Vol.84, p.104776, Article 104776
Main Authors: Kumar, Yogesh, Gupta, Bharat
Format: Article
Language:English
Subjects:
Blood vessel segmentation
DenseNet
Enhanced Fuzzy C-Means (EFCM) Clustering
Retinal blood vessels
ShuffleNet
Vessel classification
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Summary:•The proposed work introduces an effective hybrid deep learning technique for RBV segmentation and classification of vessels.•To attain higher classification accuracy, the most essential features are extracted through DenseNet, and the RBV is classified using ShuffleNet V2.•Several performance metrics are evaluated and compared with other existing methods to analyse the proposed techniques' performance. With recent advanced technologies, various automated diagnosis tools were developed to prevent retinal diseases. The automatic segmentation of blood vessels can help detect various retinal diseases and also assist in reducing doctors’ workload. In existing, numerous techniques have been established to segment RBV automatically. But, they failed to provide better accuracy because of higher computational complexity and lower efficiency. Thus, the proposed work introduces an effective hybrid deep learning technique for RBV segmentation and classification of vessels. Initially, the retinal images are pre-processed to enhance the image quality by performing two steps such as image cropping and colour channel conversion. From the pre-processed images, the most important regions are segmented through a new Enhanced Fuzzy C-Means (EFCM) clustering scheme. During the segmentation process, the retinal images are clustered according to the thickness of the blood vessels, which helps minimize the computational complexity. After segmentation, a hybrid deep learning technique like DenseNet and ShuffleNet is introduced to perform feature extraction and classification. The experimental setup is done by the Python platform using the databases like DRIVE (Digital Retinal Images for Vessel Extraction), STARE (STructured Analysis of the Retina), and HRF (High Resolution fundus). Using the DRIVE dataset, the proposed model achieves an accuracy of 99%, the attained accuracy value of the STARE dataset is 98%, and the HRF dataset obtains an accuracy of 98%. The result analysis proves that the proposed hybrid deep learning technique is more efficient than the state-of-the-art techniques.
ISSN:1746-8094
1746-8108
DOI:10.1016/j.bspc.2023.104776