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Application of Deep Learning-Based Medical Image Segmentation via Orbital Computed Tomography
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Fast and efficient retinal blood vessel segmentation method based on deep learning network.

Henda Boudegga1, Yaroub Elloumi2, Mohamed Akil3

  • 1Medical Technology and Image Processing Laboratory, Faculty of Medicine, University of Monastir, Tunisia; ISITCom Hammam-Sousse, University of Sousse, Tunisia.

Computerized Medical Imaging and Graphics : the Official Journal of the Computerized Medical Imaging Society
|April 23, 2021
PubMed
Summary
This summary is machine-generated.

This study introduces a novel deep learning (DL) method for fast and accurate retinal vessel segmentation. The new U-form DL architecture with lightweight convolutions improves performance while reducing computational time for ocular pathology detection.

Keywords:
Deep learningRetinal vessel treeSegmentation

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Area of Science:

  • Ophthalmology and Medical Imaging
  • Computer Vision and Artificial Intelligence

Background:

  • Accurate segmentation of the retinal vascular tree is crucial for diagnosing ocular pathologies.
  • Existing deep learning (DL) methods offer high accuracy but suffer from significant computational complexity and processing times.
  • Clinical applications require methods that balance high segmentation performance with reduced execution times.

Purpose of the Study:

  • To develop a novel deep learning (DL) based method for efficient and accurate retinal vessel tree segmentation.
  • To reduce the computational complexity and processing time of retinal vessel segmentation without compromising accuracy.
  • To enhance the trade-off between detection rate and detection time for automated retinal image analysis.

Main Methods:

  • A new U-form deep learning (DL) architecture incorporating lightweight convolution blocks was designed.
  • Specific preprocessing and data augmentation techniques tailored for retinal images and blood vessel characteristics were implemented.
  • The proposed method was evaluated on the publicly available DRIVE and STARE datasets.

Main Results:

  • The novel DL method achieved high segmentation accuracy, with average accuracies of 0.978 on DRIVE and 0.98 on STARE.
  • The method demonstrated significantly reduced processing times, averaging 0.59 seconds per image on DRIVE and 0.48 seconds on STARE using NVIDIA GTX 980 GPUs.
  • The proposed approach offers an improved balance between retinal blood vessel detection performance and computational efficiency.

Conclusions:

  • The developed U-form DL architecture with lightweight convolutions provides an effective solution for high-performance, time-efficient retinal vessel segmentation.
  • The tailored preprocessing and data augmentation steps contribute to the robustness and accuracy of the segmentation method.
  • This approach holds promise for accelerating the clinical diagnosis of ocular diseases through automated retinal image analysis.