Abstract
High-resolution computed tomography (HRCT) images in interstitial lung disease (ILD) screening can help improve healthcare quality. However, most of the earlier ILD classification work involves time-consuming manual identification of the region of interest (ROI) from the lung HRCT image before applying the deep learning classification algorithm. This paper has developed a two-stage hybrid approach of deep learning networks for ILD classification. A conditional generative adversarial network (c-GAN) has segmented the lung part from the HRCT images at the first stage. The c-GAN with multiscale feature extraction module has been used for accurate lung segmentation from the HRCT images with lung abnormalities. At the second stage, a pretrained ResNet50 has been used to extract the features from the segmented lung image for classification into six ILD classes using the support vector machine classifier. The proposed two-stage algorithm takes a whole HRCT as input eliminating the need for extracting the ROI and classifies the given HRCT image into an ILD class. The performance of the proposed two-stage deep learning network-based ILD classifier has improved considerably due to the stage-wise improvement of deep learning algorithm performance.
Highlights
As the risk of lung cancer incidences among patients with interstitial lung disease (ILD) is high [1], identifying the specific type of ILD becomes essential to develop appropriate therapy plans
The lung segmentation removes the unwanted background from High-resolution computed tomography (HRCT) images, helping the stage deep learning algorithm focus on the lung’s ILD features (iii) The ResNet50 has been used to extract the deep features from the segmented lung images in the second stage
The lung segmentation removes the unwanted background from HRCT images, helping the stage to accurately extract ILD features from the lung image
Summary
As the risk of lung cancer incidences among patients with interstitial lung disease (ILD) is high [1], identifying the specific type of ILD becomes essential to develop appropriate therapy plans. Data-driven decision-making [2] is becoming popular due to its ability to quickly gather and analyze complete and accurate data. It makes the decision-makers choose an appropriate treatment, predict future events, and plan long-term action. Feature extraction involves efficient shape, texture, and colour extraction for spatial and frequency-based image analysis These methods include gray level values [3], texture feature extraction, statistic filters such as gray level cooccurrence matrix and run length [4], edge features such as Gaussian and Wavelet filters [5], and spatial and shape features [6]. These features will not capture the features of deep learning proposed by deep learning algorithms
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