Computational models for stuctural analysis of retinal images

Kaba, Djibril

January 2014

The evaluation of retina structures has been of great interest because it could be used as a non-intrusive diagnosis in modern ophthalmology to detect many important eye diseases as well as cardiovascular disorders. A variety of retinal image analysis tools have been developed to assist ophthalmologists and eye diseases experts by reducing the time required in eye screening, optimising the costs as well as providing efficient disease treatment and management systems. A key component in these tools is the segmentation and quantification of retina structures. However, the imaging artefacts such as noise, intensity homogeneity and the overlapping tissue of retina structures can cause significant degradations to the performance of these automated image analysis tools. This thesis aims to provide robust and reliable automated retinal image analysis technique to allow for early detection of various retinal and other diseases. In particular, four innovative segmentation methods have been proposed, including two for retinal vessel network segmentation, two for optic disc segmentation and one for retina nerve fibre layers detection. First, three pre-processing operations are combined in the segmentation method to remove noise and enhance the appearance of the blood vessel in the image, and a Mixture of Gaussians is used to extract the blood vessel tree. Second, a graph cut segmentation approach is introduced, which incorporates the mechanism of vectors flux into the graph formulation to allow for the segmentation of very narrow blood vessels. Third, the optic disc segmentation is performed using two alternative methods: the Markov random field image reconstruction approach detects the optic disc by removing the blood vessels from the optic disc area, and the graph cut with compensation factor method achieves that using prior information of the blood vessels. Fourth, the boundaries of the retinal nerve fibre layer (RNFL) are detected by adapting a graph cut segmentation technique that includes a kernel-induced space and a continuous multiplier based max-flow algorithm. The strong experimental results of our retinal blood vessel segmentation methods including Mixture of Gaussian, Graph Cut achieved an average accuracy of 94:33%, 94:27% respectively. Our optic disc segmentation methods including Markov Random Field and Compensation Factor also achieved an average sensitivity of 92:85% and 85:70% respectively. These results obtained on several public datasets and compared with existing methods have shown that our proposed methods are robust and efficient in the segmenting retinal structures such the blood vessels and the optic disc.

617.7

Les dérivées de l’hémoglobine dans la structure rétinienne par la technique de réflectométrie multi-spectrale

Vucea, Valentina

01 1900

No description available.

Spectrophotométrie

Oxymétrie

Modélisation

Concentration d’oxygène

Vaisseaux sanguins rétiniens

Hémoglobine

Oxyhémoglobine

Spectrophotometry

Oximeter

Model

Oxygen concentration

Retinal blood vessels

Haemoglobin

Oxyhaemoglobin

Residues in Succession U-Net for Fast and Efficient Segmentation

Sultana, Aqsa

11 August 2022

No description available.

Computer Engineering

Computer Science

Artificial Intelligence

Biomedical Research

residues in succession U-Net

efficient segmentation

residues in succession

subsequent layers

residual in subsequent layers

encoder

decoder

U-Net

segmentation for biomedical dataset

retinal blood vessel segmentation