Abstract
Due to the high availability of large-scale annotated image datasets, paramount progress has been made in deep convolutional neural networks (CNNs) for image classification tasks. CNNs enable learning highly representative and hierarchical local image features directly from data. However, the availability of annotated data, especially in the medical imaging domain, remains the biggest challenge in the field. Transfer learning can provide a promising and effective solution by transferring knowledge from generic image recognition tasks to the medical image classification. However, due to irregularities in the dataset distribution, transfer learning usually fails to provide a robust solution. Class decomposition facilitates easier to learn class boundaries of a dataset, and consequently can deal with any irregularities in the data distribution. Motivated by this challenging problem, the paper presents Decompose, Transfer, and Compose (DeTraC) approach, a novel CNN architecture based on class decomposition to improve the performance of medical image classification using transfer learning and class decomposition approach. DeTraC enables learning at the subclass level that can be more separable with a prospect to faster convergence. We validated our proposed approach with three different cohorts of chest X-ray images, histological images of human colorectal cancer, and digital mammograms. We compared DeTraC with the state-of-the-art CNN models to demonstrate its high performance in terms of accuracy, sensitivity, and specificity.
Highlights
Classification of chest X-ray (CXR) images into normal or having Tuberculosis (TB) is an essential component in computer-aided diagnosis (CAD) of lung health-care [1]–[4]
We propose a novel convolutional neural network architecture based on class decomposition, which we term Decompose, Transfer, and Compose (DeTraC) model, to improve the performance of pre-trained models on the classification of X-ray images
PARAMETER SENSITIVITY To demonstrate the sensitivity to changes in the parameter k with the three datasets, we evaluated the performance of our framework when different k values were used
Summary
Classification of chest X-ray (CXR) images into normal or having Tuberculosis (TB) is an essential component in computer-aided diagnosis (CAD) of lung health-care [1]–[4]. Statistical/classical machine learning algorithms have been extensively used for lung classification [5]–[8] and nodule diagnosis from computed tomography (CT) images [9]. In [10], three statistical features were calculated from lung texture to discriminate between malignant and benign lung nodules using support vector machines (SVM) classifier. (BPN) [11] to classify computed tomography (CT) images from being normal or cancerous. For emphysema diseases of lung images, different approaches were used to describe the texture features from lung region, such as in [12] Local
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