A bone suppression model ensemble to improve COVID-19 detection in chest
X-rays
- URL: http://arxiv.org/abs/2111.03404v1
- Date: Fri, 5 Nov 2021 11:27:26 GMT
- Title: A bone suppression model ensemble to improve COVID-19 detection in chest
X-rays
- Authors: Sivaramakrishnan Rajaraman, Gregg Cohen, Les folio, and Sameer Antani
- Abstract summary: We propose to build an ensemble of convolutional neural network models to suppress bones in frontal Chest X-ray images.
It is observed that the bone suppression model ensemble outperformed the individual models in terms of MS-SSIM and other metrics.
A CXR modality-specific classification model is retrained and evaluated on the non-bone-suppressed and bone-suppressed images to classify them as showing normal lungs or other COVID-19-like manifestations.
- Score: 0.6999740786886535
- License: http://creativecommons.org/licenses/by-nc-nd/4.0/
- Abstract: Chest X-ray (CXR) is a widely performed radiology examination that helps to
detect abnormalities in the tissues and organs in the thoracic cavity.
Detecting pulmonary abnormalities like COVID-19 may become difficult due to
that they are obscured by the presence of bony structures like the ribs and the
clavicles, thereby resulting in screening/diagnostic misinterpretations.
Automated bone suppression methods would help suppress these bony structures
and increase soft tissue visibility. In this study, we propose to build an
ensemble of convolutional neural network models to suppress bones in frontal
CXRs, improve classification performance, and reduce interpretation errors
related to COVID-19 detection. The ensemble is constructed by (i) measuring the
multi-scale structural similarity index (MS-SSIM) score between the sub-blocks
of the bone-suppressed image predicted by each of the top-3 performing
bone-suppression models and the corresponding sub-blocks of its respective
ground truth soft-tissue image, and (ii) performing a majority voting of the
MS-SSIM score computed in each sub-block to identify the sub-block with the
maximum MS-SSIM score and use it in constructing the final bone-suppressed
image. We empirically determine the sub-block size that delivers superior bone
suppression performance. It is observed that the bone suppression model
ensemble outperformed the individual models in terms of MS-SSIM and other
metrics. A CXR modality-specific classification model is retrained and
evaluated on the non-bone-suppressed and bone-suppressed images to classify
them as showing normal lungs or other COVID-19-like manifestations. We observed
that the bone-suppressed model training significantly outperformed the model
trained on non-bone-suppressed images toward detecting COVID-19 manifestations.
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