Page 65 - Handbook of Deep Learning in Biomedical Engineering Techniques and Applications
P. 65
Chapter 2 Deep convolutional neural network in medical image processing 53
[17] Y. Feng, H. Zhao, X. Li, X. Zhang, H. Li, A multi-scale 3D Otsu
thresholding algorithm for medical image segmentation, Digit. Signal
Process. 60 (2017) 186e199.
[18] D. Gupta, R.S. Anand, A hybrid edge-based segmentation approach for
ultrasound medical images, Biomed. Signal Process. Contr. 31 (2017)
116e126.
[19] S.M. Anwar, S. Yousaf, M. Majid, Brain tumor segmentation on
multimodal MRI scans using EMAP algorithm, in: 2018 40th Annual
International Conference of the IEEE Engineering in Medicine and
Biology Society (EMBC), IEEE, 2018, July, pp. 550e553.
[20] C. Mosquera-Lopez, S. Agaian, A. Velez-Hoyos, I. Thompson, Computer-
aided prostate cancer diagnosis from digitized histopathology: a review
on texture-based systems, IEEE Rev. Biomed. Eng. 8 (2014) 98e113.
[21] J. Torrents-Barrena, P. Lazar, R. Jayapathy, M.R. Rathnam, B. Mohandhas,
D. Puig, Complex wavelet algorithm for computer-aided diagnosis of
Alzheimer's disease, Electron. Lett. 51 (20) (2015) 1566e1568.
[22] H.Y. Ma, Z. Zhou, S. Wu, Y.L. Wan, P.H. Tsui, A computer-aided diagnosis
scheme for detection of fatty liver in vivo based on ultrasound kurtosis
imaging, J. Med. Syst. 40 (1) (2016) 33.
[23] M. Saha, R. Mukherjee, C. Chakraborty, Computer-aided diagnosis of
breast cancer using cytological images: a systematic review, Tissue Cell 48
(5) (2016) 461e474.
[24] B. Remeseiro, A. Mosquera, M.G. Penedo, CASDES: a computer-aided
system to support dry eye diagnosis based on tear film maps, IEEE J.
Biomed. Health Inform. 20 (3) (2015) 936e943.
[25] A.A. Salam, M.U. Akram, K. Wazir, S.M. Anwar, M. Majid, December.
Autonomous Glaucoma detection from fundus image using cup to disc
ratio and hybrid features, in: 2015 IEEE International Symposium on
Signal Processing and Information Technology (ISSPIT), IEEE, 2015,
pp. 370e374.
[26] T. Li, J. Cohen, M. Craig, K. Tsourides, N. Mahmud, T.M. Berzin, Mo1979
the next endoscopic frontier: a novel computer vision program accurately
identifies colonoscopic colorectal adenomas, Gastrointest. Endosc. 83 (5)
(2016) AB482.
[27] T. Altaf, S.M. Anwar, N. Gul, M.N. Majeed, M. Majid, Multi-class
Alzheimer's disease classification using image and clinical features,
Biomed. Signal Process. Contr. 43 (2018) 64e74.
[28] T. Brosch, R. Tam, Alzheimer's Disease Neuroimaging Initiative, Manifold
learning of brain MRIs by deep learning, in: International Conference on
Medical Image Computing and Computer-Assisted Intervention, Springer,
Berlin, Heidelberg, 2013, September, pp. 633e640.
[29] S.M. Plis, D.R. Hjelm, R. Salakhutdinov, E.A. Allen, H.J. Bockholt, J.D. Long,
H.J. Johnson, J.S. Paulsen, J.A. Turner, V.D. Calhoun, Deep learning for
neuroimaging: a validation study, Front. Neurosci. 8 (2014) 229.
[30] H.I. Suk, D. Shen, Deep learning-based feature representation for AD/
MCI classification, in: International Conference on Medical Image
Computing and Computer-Assisted Intervention, Springer, Berlin,
Heidelberg, 2013, September, pp. 583e590.
[31] H.I. Suk, S.W. Lee, D. Shen, Alzheimer's Disease Neuroimaging Initiative,
Hierarchical feature representation and multimodal fusion with deep
learning for AD/MCI diagnosis, Neuroimage 101 (2014) 569e582.
