HARD EXUDATE SEGMENTATION IN VARIOUS RESOLUTION OF RETINAL FUNDUS IMAGES TO SUPPORT THE DIAGNOSIS OF DIABETIC RETINOPATHY
Diabetic retinopathy is a complication of diabetes that can cause vision loss. High blood sugar in retinal vessels causes blockage and leakage of blood vessels fluids. To reduce the risk of vision loss, detection of this disease should be done as early as possible by checking the retina for any c...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/67884 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Diabetic retinopathy is a complication of diabetes that can cause vision loss. High
blood sugar in retinal vessels causes blockage and leakage of blood vessels fluids.
To reduce the risk of vision loss, detection of this disease should be done as early
as possible by checking the retina for any clinical signs of diabetic retinopathy. The
screening of diabetic retinopathy should be done regularly and will need a large
number of ophthalmologists. The detection of clinical signs using computer will
help this process. One of the clinical signs that characterize diabetic retinopathy is
hard exudate. Hard exudate happens because fluids from blood vessels of the eye
leaks. The presence of hard exudates has been associated with higher risk of vision
loss and requires treatment to disappear. Therefore, detection and segmentation of
hard exudates can help in reducing the risk of vision loss, detecting diabetic
retinopathy and monitor the progress of treatment to remove hard exudate.
Currently, there are many deep learning methods used to segment hard exudates
using U-Net. In this study, a semantic hard exudate segmentation model was trained
on IDRiD dataset using U-Net architecture by tuning the parameters of activation
function, loss function, and dropout. The size of the input image will affect
computation, the larger the image, the heavier the computational burden. There
has been research that changes the image size into 640 × 640, 960 × 640, and
1440 × 960 sizes to segment hard exudate. The 1440 × 960 size produced a
higher F1-score than 960 × 640, and a higher AUPR than the 640 × 640 input
size. Research was conducted to determine the effect of using input sizes of
640 × 640 and 960 × 960. F1-score from each input size do not vary much,
640 × 640 resulted in 0.6925, 960 × 960 resulted in 0.6934. The p-value between
the segmentation results of 80 images of both sizes for the F1-score, accuracy,
sensitivity, specificity, PPV, and NPV metrics each yielded a value greater than
0.05, indicating no significant difference between the sizes and the results of hard
exudate segmentation. The main cause of false positives in the segmentation results
is the resampling done to restore the image to its original size. Other false positives
are caused by misclassification of reflective parts of larger blood vessels and
similar retinal pathologies such as drusen and soft exudate. |
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