Breast Cancer Identification via Thermography Image Segmentation with a Gradient Vector Flow and a Convolutional Neural Network

被引：53

作者：

Tello-Mijares S. ^{[1
,2
]}

Woo F. ^{[3
]}

Flores F. ^{[2
]}

机构：

[1] Instituto Tecnológico Superior de Lerdo, Postgraduate Department, Lerdo

[2] Instituto Tecnológico de la Laguna, Postgraduate Department, Torreón

[3] Instituto de Seguridad y Servicios Sociales de Los Trabajadores Del Estado, Medical Familiar Unit, Torreón

来源：

Journal of Healthcare Engineering | 2019年 / 2019卷

关键词：

Bayes networks - Breast Cancer - Classification technique - Curvature function - Early diagnosis - Gradient vector flow - Multi layer perceptron - Segmentation methods;

D O I：

10.1155/2019/9807619

中图分类号：

学科分类号：

摘要：

Breast cancer is the most common cancer among women worldwide with about half a million cases reported each year. Mammary thermography can offer early diagnosis at low cost if adequate thermographic images of the breasts are taken. The identification of breast cancer in an automated way can accelerate many tasks and applications of pathology. This can help complement diagnosis. The aim of this work is to develop a system that automatically captures thermographic images of breast and classifies them as normal and abnormal (without cancer and with cancer). This paper focuses on a segmentation method based on a combination of the curvature function k and the gradient vector flow, and for classification, we proposed a convolutional neural network (CNN) using the segmented breast. The aim of this paper is to compare CNN results with other classification techniques. Thus, every breast is characterized by its shape, colour, and texture, as well as left or right breast. These data were used for training as well as to compare the performance of CNN with three classification techniques: tree random forest (TRF), multilayer perceptron (MLP), and Bayes network (BN). CNN presents better results than TRF, MLP, and BN. © 2019 Santiago Tello-Mijares et al.

引用

共 48 条

[31]

Hu G., Wang K., Peng Y., Qiu M., Shi J., Liu L., Deep learning methods for underwater target feature extraction and recognition, Computational Intelligence and Neuroscience, 2018, (2018)

[32]

Abiyev R.H., Ma'Aitah M.K.S., Deep convolutional neural networks for chest diseases detection, Journal of Healthcare Engineering, 2018, (2018)

[33]

Hiwa S., Hanawa K., Tamura R., Hachisuka K., Hiroyasu T., Analyzing brain functions by subject classification of functional near-infrared spectroscopy data using convolutional neural networks analysis, Computational Intelligence and Neuroscience, 2016, (2016)

[34]

Song Q., Zhao L., Luo X., Dou X., Using deep learning for classification of lung nodules on computed tomography images, Journal of Healthcare Engineering, 2017, (2017)

[35]

Kong Z., Li T., Luo J., Xu S., Automatic tissue image segmentation based on image processing and deep learning, Journal of Healthcare Engineering, 2019, (2019)

[36]

Tello-Mijares S., Flores F., A novel method for the separation of overlapping pollen species for automated detection and classification, Computational and Mathematical Methods in Medicine, 2016, (2016)

[37]

Kass M., Witkin A., Terzopoulos D., Snakes: Active contour models, International Journal of Computer Vision, 1, 4, pp. 321-331, (1988)

[38]

Xu C., Prince J.L., Snakes, shapes, and gradient vector flow, IEEE Transactions on Image Processing, 7, 3, pp. 359-369, (1998)

[39]

Haralick R.M., Statistical and structural approaches to texture, Proceedings of the IEEE, 67, 5, pp. 786-804, (1979)

[40]

Mariarputham E.J., Stephen A., Nominated texture based cervical cancer classification, Computational and Mathematical Methods in Medicine, 2015, (2015)

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