A Comparative Study of Decoders for Liver and Tumor Segmentation Using a Self-ONN-Based Cascaded Framework

Accurate liver and tumor detection and segmentation are crucial in diagnosis of early-stage liver malignancies. As opposed to manual interpretation, which is a difficult and time-consuming process, accurate tumor detection using a computer-aided diagnosis system can save both time and human efforts....

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Bibliographic Details
Published in:Diagnostics (Basel) 2024-12, Vol.14 (23), p.2761
Main Authors: Gul, Sidra, Khan, Muhammad Salman, Hossain, Md Sakib Abrar, Chowdhury, Muhammad E H, Sumon, Md Shaheenur Islam
Format: Article
Language:English
Subjects:
Accuracy
Algorithms
computer-aided diagnosis
convolution neural networks
Datasets
Deep learning
Design
Diagnosis
Image segmentation
Liver cancer
Liver diseases
liver segmentation
Liver tumors
Machine learning
medical image processing
Neural networks
self-organizing neural networks
Technology application
Tomography
Tumors
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Summary:Accurate liver and tumor detection and segmentation are crucial in diagnosis of early-stage liver malignancies. As opposed to manual interpretation, which is a difficult and time-consuming process, accurate tumor detection using a computer-aided diagnosis system can save both time and human efforts. We propose a cascaded encoder-decoder technique based on self-organized neural networks, which is a recent variant of operational neural networks (ONNs), for accurate segmentation and identification of liver tumors. The first encoder-decoder CNN segments the liver. For generating the liver region of interest, the segmented liver mask is placed over the input computed tomography (CT) image and then fed to the second Self-ONN model for tumor segmentation. For further investigation the other three distinct encoder-decoder architectures U-Net, feature pyramid networks (FPNs), and U-Net++, have also been investigated by altering the backbone at the encoders utilizing ResNet and DenseNet variants for transfer learning. For the liver segmentation task, Self-ONN with a ResNet18 backbone has achieved a dice similarity coefficient score of 98.182% and an intersection over union of 97.436%. Tumor segmentation with Self-ONN with the DenseNet201 encoder resulted in an outstanding DSC of 92.836% and IoU of 91.748%. The suggested method is capable of precisely locating liver tumors of various sizes and shapes, including tiny infection patches that were said to be challenging to find in earlier research.
ISSN:2075-4418
2075-4418
DOI:10.3390/diagnostics14232761