Automated Mammogram Analysis with a Deep Learning Pipeline

Azam Hamidinekoo; Erika Denton; Reyer Zwiggelaar

doi:10.48550/arXiv.1907.11953

Automated Mammogram Analysis with a Deep Learning Pipeline

Azam Hamidinekoo, Erika Denton, Reyer Zwiggelaar

Department of Computer Science

Norfolk & Norwich University Hospital

Research output: Working paper › Preprint

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Abstract

Current deep learning based detection models tackle detection and segmentation tasks by casting them to pixel or patch-wise classification. To automate the initial mass lesion detection and segmentation on the whole mammographic images and avoid the computational redundancy of patch-based and sliding window approaches, the conditional generative adversarial network (cGAN) was used in this study. Subsequently, feeding the detected regions to the trained densely connected network (DenseNet), the binary classification of benign versus malignant was predicted. We used a combination of publicly available mammographic data repositories to train the pipeline, while evaluating the model's robustness toward our clinically collected repository, which was unseen to the pipeline.

Original language	English
Publisher	arXiv
Number of pages	5
DOIs	https://doi.org/10.48550/arXiv.1907.11953
Publication status	Published - 27 Jul 2019

Keywords

Mammography
Generative Adversarial Network
DenseNet
Detection
Segmentation
Classification

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1907.11953v1Submitted manuscript, 1.56 MB

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title = "Automated Mammogram Analysis with a Deep Learning Pipeline",

abstract = " Current deep learning based detection models tackle detection and segmentation tasks by casting them to pixel or patch-wise classification. To automate the initial mass lesion detection and segmentation on the whole mammographic images and avoid the computational redundancy of patch-based and sliding window approaches, the conditional generative adversarial network (cGAN) was used in this study. Subsequently, feeding the detected regions to the trained densely connected network (DenseNet), the binary classification of benign versus malignant was predicted. We used a combination of publicly available mammographic data repositories to train the pipeline, while evaluating the model's robustness toward our clinically collected repository, which was unseen to the pipeline. ",

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author = "Azam Hamidinekoo and Erika Denton and Reyer Zwiggelaar",

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AB - Current deep learning based detection models tackle detection and segmentation tasks by casting them to pixel or patch-wise classification. To automate the initial mass lesion detection and segmentation on the whole mammographic images and avoid the computational redundancy of patch-based and sliding window approaches, the conditional generative adversarial network (cGAN) was used in this study. Subsequently, feeding the detected regions to the trained densely connected network (DenseNet), the binary classification of benign versus malignant was predicted. We used a combination of publicly available mammographic data repositories to train the pipeline, while evaluating the model's robustness toward our clinically collected repository, which was unseen to the pipeline.

KW - Mammography

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KW - Detection

KW - Segmentation

KW - Classification

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ER -

Automated Mammogram Analysis with a Deep Learning Pipeline

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Keywords

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