2019
DOI: 10.1148/radiol.2019191225
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Deep Learning for Chest Radiograph Diagnosis in the Emergency Department

Abstract: I n 2015, approximately 137 million patients presented to the emergency department (ED) in the United States (43.3 visits per 100 persons) (1). Respiratory diseases were the second most common primary diagnosis in these patients, accounting for 9.8% of all visits (1). Chest radiography is the first-line examination for the evaluation of various thoracic diseases (2-8). The number of chest radiographs per ED visit increased by 81% between 1994 and 2014, suggesting an increasing dependency on chest radiographs (… Show more

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Cited by 129 publications
(94 citation statements)
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“…Although we were unable to determine the baseline performance of radiologists without use of the CAD system, it may enhance sensitivity for the detection of pulmonary abnormalities. In a previous study using the same CAD system, the sensitivity of radiology residents for identification of abnormal CXR were significantly enhanced (65.6-73.4%) after review of the CAD results (28).…”
Section: Discussionmentioning
confidence: 80%
“…Although we were unable to determine the baseline performance of radiologists without use of the CAD system, it may enhance sensitivity for the detection of pulmonary abnormalities. In a previous study using the same CAD system, the sensitivity of radiology residents for identification of abnormal CXR were significantly enhanced (65.6-73.4%) after review of the CAD results (28).…”
Section: Discussionmentioning
confidence: 80%
“…Automatic pulmonary disease detection using computer-aided diagnosis (CAD) is based on the correct segmentation of anatomical structures, such as the lungs, heart, and clavicle bones [2]. With the success of deep learning, artificially intelligent algorithms can help medical experts and ophthalmologists to detect and diagnose the disease and increase diagnostic throughput [14][15][16][17][18][19][20]. Semantic segmentation is a special branch of deep learning that involves pixel-wise classification of the image, which is important to accurately locate the infected areas for disease analysis [21,22].…”
Section: Introductionmentioning
confidence: 99%
“…Workflow improvements include prioritizing worklists for radiologists (2,3), triaging screening mammograms (4), reducing or eliminating gadolinium-based contrast media for MRI (5,6), and reducing the radiation dose of CT imaging by advancing image noise reduction (7)(8)(9). Automatic lesion detection by using machine learning has been applied to many imaging modalities and includes detection of pneumothorax (10,11), intracranial hemorrhage (12), Alzheimer disease (13), and urinary stones (14). Automatic quantification of medical images includes assessing skeletal maturity on pediatric hand radiographs (15), coronary calcium scoring on CT images (16), prostate classification at MRI (17), breast density at mammography (18), and ventricle segmentation at cardiac MRI (19,20).…”
mentioning
confidence: 99%