Abstract
The automated and accurate classification of the images portraying the Human Epithelial cells of type 2 (HEp-2) represents one of the most important steps in the diagnosis procedure of many autoimmune diseases. The extreme intra-class variations of the HEp-2 cell images datasets drastically complicates the classification task. We propose in this work a classification framework that, unlike most of the state-of-the-art methods, uses a deep learning-based feature extraction method in a strictly unsupervised way. We propose a deep learning-based hybrid feature learning with two levels of deep convolutional autoencoders. The first level takes the original cell images as the inputs and learns to reconstruct them, in order to capture the features related to the global shape of the cells, and the second network takes the gradients of the images, in order to encode the localized changes in intensity (gray variations) that characterize each cell type. A final feature vector is constructed by combining the latent representations extracted from the two networks, giving a highly discriminative feature representation. The created features will be fed to a nonlinear classifier whose output will represent the type of the cell image. We have tested the discriminability of the proposed features on two of the most popular HEp-2 cell classification datasets, the SNPHEp-2 and ICPR 2016 datasets. The results show that the proposed features manage to capture the distinctive characteristics of the different cell types while performing at least as well as the actual deep learning-based state-of-the-art methods in terms of discrimination.
Highlights
Computer-aided diagnostic (CAD) systems have gained tremendous interests since the unfolding of various machine learning techniques in the past decades
The complexity of the images leaves an important part to the subjectivity of the pathologists, which can lead to some inconsistency in the diagnosis results [2]
All of the experiments were conducted with MATLAB (9.4 (R2018a), Natick, MA, USA), and performed on a computer with a Core i7 3.40 GHz processor and 8 GB of RAM
Summary
Computer-aided diagnostic (CAD) systems have gained tremendous interests since the unfolding of various machine learning techniques in the past decades. They comprise all the systems that aim to consolidate the automation of the disease diagnostic procedures. One of the most challenging tasks regarding those CAD systems is the complete analysis and understanding of the images representing the biological organisms. Manual analysis of the IIF images represents an arduous task that can cost a substantial time. That is the reason why CAD systems have gained critical attention for assisting pathologists in diagnosis, mainly for the automatic classification of the different types of the HEp-2 cells
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