4.6 Article

Utilizing Synthetic Nodules for Improving Nodule Detection in Chest Radiographs

Journal

JOURNAL OF DIGITAL IMAGING
Volume 35, Issue 4, Pages 1061-1068

Publisher

SPRINGER
DOI: 10.1007/s10278-022-00608-9

Keywords

Generative adversarial networks; Online data augmentation; Chest radiographs; Computer-aided detection

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Automated algorithms that identify nodular patterns in chest X-ray images can help reduce reading time and improve accuracy for radiologists. This study proposes a framework to generate realistic nodules and shows how they can be used to train a deep neural network for accurate detection and localization of nodular patterns in CXR images. The proposed method enhances the recall of the detection model while maintaining a low level of false positives.
Algorithms that automatically identify nodular patterns in chest X-ray (CXR) images could benefit radiologists by reducing reading time and improving accuracy. A promising approach is to use deep learning, where a deep neural network (DNN) is trained to classify and localize nodular patterns (including mass) in CXR images. Such algorithms, however, require enough abnormal cases to learn representations of nodular patterns arising in practical clinical settings. Obtaining large amounts of high-quality data is impractical in medical imaging where (1) acquiring labeled images is extremely expensive, (2) annotations are subject to inaccuracies due to the inherent difficulty in interpreting images, and (3) normal cases occur far more frequently than abnormal cases. In this work, we devise a framework to generate realistic nodules and demonstrate how they can be used to train a DNN identify and localize nodular patterns in CXR images. While most previous research applying generative models to medical imaging are limited to generating visually plausible abnormalities and using these patterns for augmentation, we go a step further to show how the training algorithm can be adjusted accordingly to maximally benefit from synthetic abnormal patterns. A high-precision detection model was first developed and tested on internal and external datasets, and the proposed method was shown to enhance the model's recall while retaining the low level of false positives.

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