IJBTT

SpineResUnet: Classification and Prediction of Spinal Tuberculosis Disease on Exploiting the Structural and Texture Dependencies

SpineResUnet: Classification and Prediction of Spinal Tuberculosis Disease on Exploiting the Structural and Texture Dependencies
	© 2023 by IJETT Journal
	Volume-71 Issue-10
	Year of Publication : 2023
	Author : Askarali K.T, E.J. Thomson Fredrik
	DOI : 10.14445/22315381/IJETT-V71I10P214

How to Cite?

Askarali K.T, E.J. Thomson Fredrik, "SpineResUnet: Classification and Prediction of Spinal Tuberculosis Disease on Exploiting the Structural and Texture Dependencies," International Journal of Engineering Trends and Technology, vol. 71, no. 10, pp. 156-162, 2023. Crossref, https://doi.org/10.14445/22315381/IJETT-V71I10P214

Abstract
Spinal Tuberculosis is a most important and very dangerous extrapulmonary disease type of skeletal tuberculosis, which causes destruction, collapse of vertebrae and angulations of the vertebral column. Hence, detecting the disease early is becoming important to prevent serious complications such as spinal deformity and permanent neurological deficit. Many machine learning and deep learning models have been presented to detect and classify the disease. However, those techniques lead to various challenges in appearance and are complex in fully exploiting the dependency between the structural and texture characteristics of the image. In order to handle the challenges, a new deep learning framework named SpineResUnet was to achieve the classification of spinal tuberculosis disease on volumetric MR Images. SpineGraphNet is composed of automated segmentation and classification of the image. Initially, segmentation of the collapsed region of vertebrate or spinal deformity region is carried out using graph convolution segmentation network as fine-grained segments. The segmented region of the image is processed further towards classifying the segmented region into classes using an adjacency matrix containing semantic features in ResNet and U-Net with Skip Connection. The classes represent kyphosis, gibbus formation and osteomyelitis of the spinal tuberculosis. The proposed model successfully captures the dependency implicitly and explicitly. Experimental analysis of T2 weighted volumetric MR image of 100 subjects has been collected from the KMCH hospital, Coimbatore. In this, 60% of images have been employed to train corresponding experts in Spinal Tuberculosis disease characterization, 20% has been used as testing, and the remaining 20% of the image has been taken for 5-fold cross-validation through a confusion matrix. The proposed model exhibited optimal performance in terms of dice coefficient, specificity, and sensitivity compared against conventional approaches.

Keywords
Deep learning, Gibbus formation, Kyphosis, Osteomyelitis, Spinal tuberculosis.

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