Computer aided detection (CADe) of pulmonary nodules from computed tomography (CT) is crucial for early diagnosis of lung cancer. Self-learned features obtained by training datasets via deep learning have facilitated CADe of the nodules. However, the complexity of CT lung images renders a challenge of extracting effective features by self-learning only. This condition is exacerbated for limited size of datasets. On the other hand, the engineered features have been widely studied.
OBJECTIVE:
We proposed a novel nodule CADe which aims to relieve the challenge by the use of available engineered features to prevent convolution neural networks (CNN) from overfitting under dataset limitation and reduce the running-time complexity of self-learning.
METHODS:
The CADe methodology infuses adequately the engineered features, particularly texture features, into the deep learning process.
RESULTS:
The methodology was validated on 208 patients with at least one juxta-pleural nodule from the public LIDC-IDRI database. Results demonstrated that the methodology achieves a sensitivity of 88% with 1.9 false positives per scan and a sensitivity of 94.01% with 4.01 false positives per scan.
CONCLUSIONS:
The methodology shows high performance compared with the state-of-the-art results, in terms of accuracy and efficiency, from both existing CNN-based approaches and engineered feature-based classifications.
A.C.Society, Cancer Facts and Figures 2018, Atlanta: American Cancer society (2018).
2.
R.H.Sherrier, C.Chiles, W.E.Wilkinson, et al., Effects of image processing on nodule detection rates in digitized chest radiographs: ROC study of observer performance, Radiology166(2) (1988), 447–450.
3.
M.L.Giger, H.MacMahon, et al., Image feature analysis and computer-aided diagnosis in digital radiography.3. Automated detection of nodules in peripheral lung fields, Medical Physics15(2) (1988), 158–166.
4.
S.G.Armato, M.L.Giger, C.J.Moran, et al., Computerized detection of pulmonary nodules on CT scans, Radiographics19(5) (1999), 1303–1311.
5.
D.S.Paik, C.F.Beaulieu, G.D.Rubin, et al., Surface normal overlap: A computer-aided detection algorithm with application to colonic polyps and lung nodules in helical CT, IEEE Transactions on Medical Imaging23(6) (2004), 661–675.
6.
X.Ye, X.Lin, J.Dehmeshki, et al., Shape-based computer-aided detection of lung nodules in thoracic CT images, IEEE Transactions on Biomedical Engineering56(7) (2009), 1810–1820.
7.
H.Han, L.Li, F.Han, et al., Fast and adaptive detection of pulmonary nodules in thoracic CT images using a hierarchical vector quantization scheme, IEEE Journal of Biomedical and Health Informatics19(2) (2015), 648–659.
8.
R.Anirudh, J.J.Thiagarajan, T.Bremer and H.Kim, Lung nodule detection using 3D convolutional neural networks trained on weakly labeled data, in: Medical Imaging 2016: Computer-Aided Diagnosis, 9785 (2016), 978532.
9.
H.Jiang, H.Ma, W.Qian, et al., An automatic detection system of lung nodule based on multi-group patch-based deep learning network, IEEE Journal of Biomedical and Health Informatics (2017).
10.
H.C.Shin, H.R.Roth, M.Gao, et al., Deep Convolutional Neural Networks for Computer-Aided Detection: CNN architectures, dataset characteristics and transfer learning, IEEE Transactions on Medical Imaging35(5) (2016), 1285–1298.
11.
H.Wang, T.Zhao, L.C.Li, et al., A hybrid CNN feature model for pulmonary nodule malignancy risk differentiation, Journal of X-ray Science and Technology26(2) (2018), 171–187.
12.
M.Tan, R.Deklerck, B.Jansen, et al., A novel computer-aided lung nodule detection system for CT images, Medical Physics38(10) (2011), 5630–5645.
13.
W.J.Choi and T.S.Choi, Automated pulmonary nodule detection based on three-dimensional shape-based feature descriptor, Computer Methods and Programs in Biomedicine113(1) (2014), 37–54.
14.
D.M.Penã, S.Luo and A.Abdelgader, Auto diagnostics of lung nodules using minimal characteristics extraction technique, Diagnostics6(1) (2016), 13.
15.
D.Cascio, R.Magro, F.Fauci, et al., Automatic detection of lung nodules in CT datasets based on stable 3d mass-spring models, Computers in Biology and Medicine42(11) (2012), 1098–1109.
16.
S.Sivakumar and C.Chandrasekar, Lung nodule detection using fuzzy clustering and sup- port vector machines, International Journal of Engineering and Technology5(1) (2013), 179–185.
17.
N.Camarlinghi, I.Gori, A.Retico, et al., Combination of computer-aided detection algorithms for automatic lung nodule identification, International Journal of Computer Assisted Radiology and Surgery7(3) (2012), 455–464.
18.
Y.LeCun, Y.Bengio and G.Hinton, Deep learning, Nature521(7553) (2015), 436.
19.
J.Tan, Y.Huo, Z.Liang, et al., A Fast Automatic Juxta-pleural Lung Nodule Detection Framework Using Convolutional Neural Networks and Vote Algorithm, Patch-Based Techniques in Medical Imaging (2018).
20.
A.Setio, F.Ciompi, G.Litjens, et al., Pulmonary Nodule Detection in CT images: False Positive Reduction Using Multi-view Convolutional Networks, IEEE Transactions on Medical Imaging35(5) (2016), 1160–1169.
21.
A.Teramoto, H.Fujita, O.Yamamuro and T.Tamaki, Automated detection of pulmonary nodules in PET/CT images: Ensemble false-positive reduction using a convolutional neural network technique, Medical Physics43(6Part1) (2016), 2821–2827.
22.
Z.Lan, M.Lin, X.Li, A.G.Hauptmann and B.Raj, Beyond gaussian pyramid: Multi-skip feature stacking for action recognition, Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (2015), 204–212.
23.
K.Simonyan and A.Zisserman, Two-stream Convolutional Networks for action recognition in videos, A dvances in Neural Information Processing Systems (2014), 568–576.
24.
L.Wang, Y.Qiao and X.Tang, Action recognition with trajectory-pooled deep- convolutional descriptors, Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (2015), 4305–4314.
25.
J.Yue-Hei Ng, M.Hausknecht, S.Vijayanarasimhan, et al., Beyond short snippets: Deep networks for video classification, Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition (2015), 4694–4702, IEEE.
26.
S.Zha, F.Luisier, W.Andrews, et al., Exploiting image-trained CNN architectures for unconstrained video classification, arXiv Preprint arXiv: 1503.04144 (2015).
27.
E.Park, X.Han, T.L.Berg and A.C.Berg, Combining multiple sources of knowledge in deep CNNs for action recognition, Applications of Computer Vision (WACV), 2016 IEEE Winter Conference on (2016), 1–8, IEEE.
28.
E.Taşci and A.Ugur, Shape and texture based novel features for automated juxtapleural nodule detection in lung CTs, Journal of Medical Systems39(5) (2015), 46.
29.
A.M.Santos, A.O.deCarvalhoFilhox, A.C.Silva, et al., Automatic detection of small lung nodules in 3D CT data using Gaussian mixture models, Tsallis entropy and SVM, Engineering Applications of Artificial Intelligence36 (2014), 27–39.
30.
S.G.Armato, G.McLennan, L.Bidaut, et al., The lung image database consortium (LIDC) and image database resource initiative (IDRI): A completed reference database of lung nodules on CT scans, Medical Physics38(2) (2011), 915–931.
31.
S.Wold, K.Esbensen and P.Geladi, Principal component analysis, Chemometrics and Intelligent Laboratory Systems2(1-3) (1987), 37–52.
32.
R.Donyet al., Karhunen-loeve transform, The Transform and Data Ompression Handbook1 (2001), 1–34.
33.
A.S.Glassner, Graphics Gems (2013).
34.
J.Serra, Image analysis and mathematical morphology (1983).
35.
A.Krizhevsky, I.Sutskever and G.E.Hinton, Imagenet classification with Deep Con- volutional Neural Networks, Advances in Neural Information Processing Systems (2012), 1097–1105.
36.
N.Tajbakhsh and K.Suzuki, Comparing two classes of end-to-end machine-learning models in lung nodule detection and classification: MTANNs vs. CNNs, Pattern Recognition63 (2017), 476–486.
N.Dalal and B.Triggs, Histograms of Oriented Gradients for Human Detection1 (2005), 886–893, IEEE.
39.
T.Ojala, M.Pietikainen and T.Maenpaa, Multiresolution gray-scale and rotation in- variant texture classification with local binary patterns, IEEE Transactions on Pattern Analysis and Machine Intelligence24(7) (2002), 971–987.
40.
X.Wang, T.X.Han and S.Yan, An HOG-LBP human detector with partial occlusion handling (2009), 32–39, IEEE.
41.
R.M.Haralick, K.Shanmugamet al., Textural features for image classification, IEEE Transactions on Systems, Man, and Cybernetics (1973), 610–621.
42.
F.Han, H.Wang, G.Zhang, et al., Texture feature analysis for computer-aided diagnosis on pulmonary nodules, Journal of Digital Imaging28(1) (2015), 99–115.
43.
Y.Hu, Z.Liang, B.Song, et al., Texture feature extraction and analysis for polyp differentiation via computed tomography colonography, IEEE Transactions on Medical Imaging35(6) (2016), 1522–1531.
44.
A.Paszke, S.Gross, S.Chintala, et al., Automatic differentiation in PyTorch (2017).
45.
D.P.Kingma and J.Ba, Adam: A method for stochastic optimization, arXivpreprint arXiv: 1412.6980 (2014).
46.
F.Wilcoxon, Individual comparisons by ranking methods, Biometrics Bulletin1(6) (1945), 80–83.
