Abstract
Oral cancer is caused by the mutation of the cells in the lips or in the mouth. The incidence rate and prevalence rate of oral cancer are increasing worldwide. Recently, the Machine Learning (ML) approaches play a vital role in medical image diagnosis. They provide accurate and rapid evaluation of the analysis of histopathological images using supervised learning. In this study, three different modules are developed namely preprocessing, feature extraction and classification module. Initially, the raw histopathological image is given to the median filter for the removal of background noise in the preprocessing module. In the next module, the temporal features such as energy, entropy etc., are extracted from the color components of the filtered images. Finally, the classification is done by employing the Support Vector Machine (SVM) and K-Nearest Neighbour (KNN) to classify histopathological images as normal or abnormal. Results show that the SVM classifier is better than KNN for the classification of oral cancer. The classification accuracy on 1224 histopathological images has been improved to 98% by using SVM classifier as compared with the KNN results of 83%.
Highlights
The incidence rate and prevalence rate of oral cancer are increasing worldwide and many artificial intelligence algorithms have been developed to analyze medical images as well as other fields of technology
Employing more than 1000 histopathological images (290 normal and 934 oral cancer images) from the database [18], the performance of the system is discussed in detail
In order to remove background noises and hairs, the image is first preprocessed using the intensity of colour channel separation technique
Summary
The incidence rate and prevalence rate of oral cancer are increasing worldwide and many artificial intelligence algorithms have been developed to analyze medical images as well as other fields of technology. A dynamic Bayesian network is utilized for oral cancer in [1] using genomic data. The significant network nodes are identified by applying functional and topological analysis on genomic data. A large scale image retrieval system is implemented in [3] for histopathological image analysis. A supervised kernel hashing is applied to compress the high dimensional image features into binary codes. An efficient hash table is generated using these codes to retrieve the images. A dictionary learning method is described in [4] for histopathological image analysis. It is a low-complexity method which grades the diseases using the learned dictionaries under a sparsely constraint
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