Automatic lung segmentation in CT images using mask R-CNN for mapping the feature extraction in supervised methods of machine learning using transfer learning
Restricted accessResearch articleFirst published online November, 2020
Automatic lung segmentation in CT images using mask R-CNN for mapping the feature extraction in supervised methods of machine learning using transfer learning
According to the World Health Organization, severe lung pathologies bring about 250,000 deaths each year, and by 2030 it will be the third leading cause of death in the world. The usage of (CT) Computed Tomography is a crucial tool to aid medical diagnosis. Several studies, based on the computer vision area, in association with the medical field, provide computational models through machine learning and deep learning. In this study, we created a new feature extractor that works as the Mask R-CNN kernel for lung image segmentation through transfer learning. Our approaches minimize the number of images used by CNN’s training step, thereby also decreasing the number of interactions performed by the network. The model obtained results surpassing the standard results generated by Mask R-CNN, obtaining more than 99% about the metrics of real lung position on CT with our best model Mask SVM, surpassing methods in the literature reaching 11 seconds for pulmonary segmentation. To present the effectiveness of our approach also in the generalization of models (methods capable of generalizing machine knowledge to other different databases), we carried out experiments also with various databases. The method was able, with only one training based on a single database, to segment CT lung images belonging to another lung database, generating excellent results getting 99% accuracy.
Global tuberculosis report 2017, World Health Organization, Geneva, Switzerland, 2017.
2.
International Conference – Design and Applications of Intelligent Systems (ISDA-2019), (Petroria, South Afric, December 2019), Advances in Intelligent Systems and Computing, Petroria, South Afric, 2019. Springer.
3.
AhsanM.GomesR. and DentonA., Application of a convolutional neural network using transfer learning for tuberculosis detection, in: 2019 IEEE International Conference on Electro Information Technology (EIT), IEEE, 2019, pp. 427–433.
4.
Ait SkourtB.El HassaniA. and MajdaA., Lung CT Image Segmentation Using Deep Neural Networks, in: BoumhidiJ.ErdiP.GhanouY.NaouiE.H.OubenaallaY., eds, Proceedings of the First International Conference on Intelligent Computing in Data Sciences (ICDS2017), Vol. 127 of Procedia Computer Science, 2018, pp. 109–113. 1st International Conference on Intelligent Computing in Data Sciences (ICDS), Meknes, MOROCCO, DEC 18–19, 2017.
5.
Akin-AkintayoO.O.AlexanderL.F.NeillR.KrupinksiE.A.TangX.MittalP.K.SmallW.C. and MorenoC.C., Prevalence and severity of off-centering during diagnostic CT: Observations from 57,621 CT scans of the chest, abdomen, and/or pelvis, Current Problems in Diagnostic Radiology48(3) (May-Jun 2019), 229–234.
6.
AlzubaidiL.Al-ShammaO.FadhelM.A.FarhanL. and ZhangJ., Classification of red blood cells in sickle cell anemia using deep convolutional neural network, in: International Conference on Intelligent Systems Design and Applications, Springer, 2018, pp. 550–559.
7.
AnthimopoulosM.ChristodoulidisS.EbnerL.ChristeA. and MougiakakouS., Lung pattern classification for interstitial lung diseases using a deep convolutional neural network, IEEE Transactions on Medical Imaging35(5, SI) (May 2016), 1207–1216.
8.
AnthimopoulosM.ChristodoulidisS.EbnerL.GeiserT.ChristeA. and MougiakakouS., Semantic segmentation of pathological lung tissue with dilated fully convolutional networks, IEEE Journal of Biomedical and Health Informatics23(2) (2018), 714–722.
9.
AnwarS.M.MajidM.QayyumA.AwaisM.AlnowamiM. and KhanM.K., Medical image analysis using convolutional neural networks: A review, Journal of Medical Systems42(11) (Nov 2018).
10.
ArmatoS.G., IIIMcLennanG.BidautL.McNitt-GrayM.F.MeyerC.R.ReevesA.P.ZhaoB.AberleD.R.HenschkeC.I.HoffmanE.A.KazerooniE.A.MacMahonH.van BeekE.J.R.YankelevitzD.BiancardiA.M.BlandP.H.BrownM.S.EngelmannR.M.LaderachG.E.MaxD.PaisR.C.QingD.P.-Y.RobertsR.Y.SmithA.R.StarkeyA.BatraP.CaligiuriP.FarooqiA.GladishG.W.JudeC.M.MundenR.F.PetkovskaI.QuintL.E.SchwartzL.H.SundaramB.DoddL.E.FenimoreC.GurD.PetrickN.FreymannJ.KirbyJ.HughesB.CasteeleA.V.GupteS.SallamM.HeathM.D.KuhnM.H.DharaiyaE.BurnsR.FrydD.S.SalganicoffM.AnandV.ShreterU.VastaghS.CroftB.Y. and ClarkeL.P., 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) (Feb 2011), 915–931.
11.
BartholomaiJ.A. and FrieboesH.B., Lung Cancer Survival Prediction via Machine Learning Regression, Classification, and Statistical Techniques, in: 2018 IEEE International Symposium on Signal Processing and Information Technology (ISSPIT), IEEE International Symposium on Signal Processing and Information Technology, IEEE, 2018, pp. 632–637. IEEE International Symposium on Signal Processing and Information Technology (ISSPIT), Louisville, KY, DEC 06–08, 2018.
12.
BharatiS.PodderP.MondalR.MahmoodA. and Raihan-Al-MasudM., Comparative performance analysis of different classification algorithm for the purpose of prediction of lung cancer, in: International Conference on Intelligent Systems Design and Applications, Springer, 2018, pp. 447–457.
13.
BhatiaS.SinhaY. and GoelL., Lung cancer detection: A deep learning approach, in: Soft Computing for Problem Solving, Springer, 2019, pp. 699–705.
14.
BurneyP.G.J.PatelJ.NewsonR.MinelliC. and NaghaviM., Global and regional trends in COPD mortality, 1990–2010, European Respiratory Journal45(5) (May 2015), 1239–1247.
15.
ChevtchenkoS.ValeR.F.CordeiroF.R. and MacarioV., Deep Learning for People Detection on Beach Images, in: 2018 7th Brazilian Conference on Intelligent Systems (BRACIS), Brazilian Comp Soc, 2018, pp. 218–223. 7th Brazilian Conference on Intelligent Systems (BRACIS), IBM Res, Sao Paulo, BRAZIL, OCT 22–25, 2018.
16.
ChristodoulidisS.AnthimopoulosM.EbnerL.ChristeA. and MougiakakouS., Multisource transfer learning with convolutional neural networks for lung pattern analysis, IEEE Journal of Biomedical and Health Informatics21(1) (Jan 2017), 76–84.
17.
CunhaA.WatanabeC. and CarvalhoC., Jr, Medical image segmentation using the kohonen neural network, IEEE Latin America Transactions17(2) (Feb 2019), 297–304.
18.
de MarcoR.AccordiniS.CerveriI.CorsicoA.SunyerJ.NeukirchF.KunzliN.LeynaertB.JansonC.GislasonT.VermeireP.SvanesC.AntoJ.BurneyP. and SurveE.C.R.H., An international survey of chronic obstructive pulmonary disease in young adults according to GOLD stages, Thorax59(2) (Feb 1 2004), 120–125.
19.
DelvesL.WilkinsonR.OliverC. and WhiteR., Comparing the performance of sar image segmentation algorithms, International Journal of Remote Sensing13(11) (Jul 20 1992), 2121–2149.
20.
DiazA.A.CelliB. and CeledonJ.C., Chronic obstructive pulmonary disease in hispanics a 9-year update, American Journal of Respiratory and Critical Care Medicine197(1) (Jan 1 2018), 15–21.
21.
Faghih-RoohiS.HajizadehS.NunezA.BabuskaR. and De SchutterB., Deep Convolutional Neural Networks for Detection of Rail Surface Defects, in: 2016 International Joint Conference on Neural Networks (IJCNN), IEEE International Joint Conference on Neural Networks (IJCNN), IEEE; IEEE Computat Intelligence Soc; Int Nueral Network Soc; Evolutionary Programming Soc; IET; IEEE BigData; Gulf Univ Sci & Technol, 2016, pp. 2584–2589. International Joint Conference on Neural Networks (IJCNN), Vancouver, CANADA, JUL 24–29, 2016.
22.
FawcettT., An introduction to roc analysis, Pattern Recognition Letters27(8) (2006), 861–874.
23.
FordN.L.LeeI.TamA. and SinD.D., Micro-computed tomography imaging of a rodent model of chronic obstructive pulmonary disease (copd), in: Medical Imaging 2020: Biomedical Applications in Molecular, Structural, and Functional Imaging, Vol. 11317, International Society for Optics and Photonics, 2020, p. 113172F.
24.
Francesqui CandelaJ.R.SerranoM.BenegasM.LasernaE.CuerpoS.Hernandez-GonzalezF.VilasecaJ.SanchezM. and Sellares TorresJ., On-line multidisciplinary discussion on interstitial lung diseases (ILD): Using new technologies to connect general hospitals to expert units managing ILD, American Journal of Respiratory And Critical Care Medicine199 (2019). International Conference of the American-Thoracic-Society, Dallas, TX, MAY 17–22, 2019.
25.
FukunagaK. and NarendraP.M., A branch and bound algorithm for computing k-nearest neighbors, IEEE Transactions on ComputersC-24(7) (July 1975), 750–753.
26.
GhafoorianM.MehrtashA.KapurT.KarssemeijerN.MarchioriE.PesteieM.GuttmannC.R.de LeeuwF.-E.TempanyC.M.van GinnekenB. et al., Transfer learning for domain adaptation in mri: Application in brain lesion segmentation, in: International Conference on Medical Image Computing and Computer-assisted Intervention, Springer, 2017, pp. 516–524.
27.
GhoshS.SilS.GomesR.M. and DeyM., Using convolutions and image processing techniques to segment lungs from ct data, in: Emerging Technology in Modelling and Graphics, Springer, 2020, pp. 129–136.
28.
GirshickR., Fast R-CNN, in: 2015 IEEE International Conference on Computer Vision (ICCV), IEEE International Conference on Computer Vision, Amazon; Microsoft; Sansatime; Baidu; Intel; Facebook; Adobe; Panasonic; 360; Google; Omron; Blippar; iRobot; Hiscene; nVidia; Mvrec; Viscovery; AiCure, 2015, pp. 1440–1448. IEEE International Conference on Computer Vision, Santiago, CHILE, DEC 11–18, 2015.
29.
GirshickR.DonahueJ.DarrellT. and MalikJ., Rich feature hierarchies for accurate object detection and semantic segmentation, in: 2014 IEEE Conference on Computer Vision and Pattern Recognition (CVPR), IEEE Conference on Computer Vision and Pattern Recognition, Comp Vis Fdn; IEEE; IEEE Comp Soc, 2014, pp. 580–587. 27th IEEE Conference on Computer Vision and Pattern Recognition (CVPR), Columbus, OH, JUN 23–28, 2014.
30.
GrauV.MewesA.AlcanizM.KikinisR. and WarfieldS., Improved watershed transform for medical image segmentation using prior information, IEEE Transactions on Medical Imaging23(4) (Apr 2004), 447–458.
31.
HanT.NunesV.X.SouzaL.F.D.F.MarquesA.G.SilvaI.C.L.JuniorM.A.A.F.SunJ. and Rebouças FilhoP.P., Internet of medical things – based on deep learning techniques for segmentation of lung and stroke regions in ct scans, IEEE Access8 (2020), 71117–71135.
32.
HarsonoI.W.LiawatimenaS. and CenggoroT.W., Lung nodule detection and classification from thorax ct-scan using retinanet with transfer learning, Journal of King Saud University-Computer and Information Sciences (2020).
HeK.GkioxariG.DollarP. and GirshickR., Mask R-CNN, IEEE Transactions on Pattern Analysis and Machine Intelligence42(2) (Feb 2020), 386–397.
35.
HoriT.NamekawaM. and KanagawaS., Analysis of overhead view images at intersection using machine learning, in: International Conference on Intelligent Systems Design and Applications, Springer, 2018, pp. 783–791.
36.
HuQ.SouzaL.F.d.F.HolandaG.B.AlvesS.S.A.SilvaF.H.d.S.HanT. and Reboucas FilhoP.P., An effective approach for CT lung segmentation using mask region-based convolutional neural networks, Artificial Intelligence in Medicine103 (Mar 2020).
37.
HuaQ.OhataE.F.SilvaF.H.S.RamalhoG.L.B.HanT. and Reboucas FilhoP.P., A new online approach for classification of pumps vibration patterns based on intelligent IoT system, Measurement151 (Feb 2020).
38.
HuynhH.T. and AnhV.N.N., A deep learning method for lung segmentation on large size chest X-ray image, in: 2019 IEEE – Rivf International Conference on Computing and Communication Technologies (RIVF), IEEE RIVF International Conference on Computing and Communication Technologies Research Innovation and Vision for the Future, IEEE; Natl Fdn Sci & Technol Dev; Univ Danang, 2019, pp. 250–254. IEEE – RIVF International Conference on Computing and Communication Technologies (RIVF), Danang, VIETNAM, MAR 20–22, 2019.
39.
JiangZ.ZhangH.WangY. and KoS.-B., Retinal blood vessel segmentation using fully convolutional network with transfer learning, Computerized Medical Imaging and Graphics68 (Sep 2018), 1–15.
40.
KayalibayB.JensenG. and van der SmagtP., Cnn-based segmentation of medical imaging data, arXiv preprint arXiv: 1701.03056, 2017.
41.
KhosravanN.CelikH.TurkbeyB.JonesE.C.WoodB. and BagciU., A collaborative computer aided diagnosis (C-CAD) system with eye-tracking, sparse attentional model, and deep learning, Medical Image Analysis51 (Jan 2019), 101–115.
42.
KumarE.S. and JayadevP.S., Deep learning for clinical decision support systems: A review from the panorama of smart healthcare, in: Deep Learning Techniques for Biomedical and Health Informatics, Springer, 2020, pp. 79–99.
43.
KumarN., Large scale deep network architecture of cnn for unconstraint visual activity analytics, in: International Conference on Intelligent Systems Design and Applications, Springer, 2017, pp. 251–261.
44.
LustbergT.van SoestJ.GoodingM.PeressuttiD.AljabarP.van der StoepJ.van ElmptW. and DekkerA., Clinical evaluation of atlas and deep learning based automatic contouring for lung cancer, Radiotherapy and Oncology126(2) (Feb 2018), 312–317.
45.
MahapatraD. and GeZ., Training data independent image registration with gans using transfer learning and segmentation information, in: 2019 IEEE 16th International Symposium on Biomedical Imaging (ISBI 2019), IEEE International Symposium on Biomedical Imaging, Inst Elect & Elect Engineers; IEEE Engn Med & Biol Soc; IEEE Signal Proc Soc; Canon Med Res Europe Ltd; UAI, United Imaging Intelligence; Baidu; GSK; Kitware, 2019, pp. 709–713. 16th IEEE International Symposium on Biomedical Imaging (ISBI), Venice, ITALY, APR 08–11, 2019.
46.
MasoliM.FabianD.HoltS.BeasleyR. and ProgramG., The global burden of asthma: Executive summary of the GINA dissemination committee report, Allergy59(5) (May 2004), 469–478.
47.
MatthewsB.W., Comparison of the predicted and observed secondary structure of t4 phage lysozyme, Biochimica et Biophysica Acta (BBA)-Protein Structure405(2) (1975), 442–451.
48.
Medeiros da NobregaR.V.PeixotoS.A.da SilvaS.P.P. and Reboucas FilhoP.P., Lung Nodule Classification via Deep Transfer Learning in CT Lung Images, in: HollmenJ.McGregorC.SodaP.KaneB., eds, 2018 31st IEEE International Symposium on Computer-Based Medical Systems (CBMS 2018), IEEE International Symposium on Computer-Based Medical Systems, IEEE; IEEE Comp Soc; Technical Committee on Computational Life Sciences; Karlstad Univ Business Sch; Karlstad Univ, Dept Comp Sci, 2018, pp. 244–249. 31st IEEE International Symposium on Computer-Based Medical Systems (CBMS), Karlstad Univ, Karlstad, SWEDEN, JUN 18–21, 2018.
49.
MittalA.HoodaR. and SofatS., Lung field segmentation in chest radiographs: A historical review, current status, and expectations from deep learning, Iet Image Processing11(11) (Nov 2017), 937–952.
50.
Molina-RomeroC.ArrietaO. and Hernandez-PandoR., Tuberculosis and lung cancer, Salud Publica de Mexico61(3) (May-Jun 2019), 286–291.
51.
MuzammalM.TalatR.SodhroA.H. and PirbhulalS., A multi-sensor data fusion enabled ensemble approach for medical data from body sensor networks, Information Fusion53 (Jan 2020), 155–164.
52.
NegahdarM.BeymerD. and Syeda-MahmoodT., Automated Volumetric Lung Segmentation of Thoracic CT Images using Fully Convolutional Neural Network, in: PetrickN.MoriK., eds, Medical Imaging 2018: Computer-Aided Diagnosis, Vol. 10575 of Proceedings of SPIE. SPIE; DECTRIS Ltd, 2018. Conference on Medical Imaging – Computer-Aided Diagnosis, Houston, TX, FEB 12–15, 2018.
53.
NiyazU.SambyalA.S. and PadhaD., Evaluation of deep learning model with optimizing and satisficing metrics for lung segmentation, in: Soft Computing for Problem Solving, Springer, 2020, pp. 67–78.
54.
NovikovA.A.LenisD.MajorD.HladuvkaJ.WimmerM. and BuehlerK., Fully convolutional architectures for multiclass segmentation in chest radiographs, IEEE Transactions on Medical Imaging37(8) (Aug 2018), 1865–1876.
55.
PanS.J. and YangQ., A survey on transfer learning, IEEE Transactions on Knowledge and Data Engineering22(10) (Oct 2010), 1345–1359.
56.
PawelczykK.KawulokM.NalepaJ.HayballM.P.McQuaidS.J.PrakashV. and GaneshanB., Towards Detecting High-Uptake Lesions from Lung CT Scans Using Deep Learning, in: BattiatoS.GalloG.SchettiniR.StancoF., eds, Image Analysis and Processing (ICIAP 2017), PT II, Vol. 10485 of Lecture Notes in Computer Science, Univ Catania, Dept Math & Comp Sci, Image Proc Lab; iCTLab; Micron; STMicroelectronics, 2017, pp. 310–320. 19th International Conference on Image Analysis and Processing (ICIAP), Catania, ITALY, SEP 11–15, 2017.
57.
PillaiR.OzaP. and SharmaP., Review of machine learning techniques in health care, in: Proceedings of ICRIC 2019, Springer, 2020, pp. 103–111.
58.
PritchardD.AdegunsoyeA.LafondE.PugashettiJ.V.DiGeronimoR.BoctorN.SarmaN.PanI.StrekM.KadochM. et al., Diagnostic test interpretation and referral delay in patients with interstitial lung disease, Respiratory Research20(1) (2019), 253.
59.
RazzakM.I.NazS. and ZaibA., Deep learning for medical image processing: Overview, challenges and the future, in: Classification in BioApps, Springer, 2018, pp. 323–350.
60.
Reboucas FilhoP.P.CortezP.C.da Silva BarrosA.C.AlbuquerqueV.H.C. and TavaresJ.M.R.S., Novel and powerful 3D adaptive crisp active contour method applied in the segmentation of CT lung images, Medical Image Analysis35 (Jan 2017), 503–516.
61.
Reboucas FilhoP.P.CortezP.C.da Silva BarrosA.C. and de AlbuquerqueV.H.C., Novel adaptive balloon active contour method based on internal force for image segmentation – A systematic evaluation on synthetic and real images, Expert Systems with Applications41(17) (Dec 1 2014), 7707–7721.
62.
Rebouças FilhoP.P.CortezP.C.FélixJ.H.d.S.CavalcanteT.d.S. and HolandaM.A., Adaptive 2d crisp active contour model applied to lung segmentation in ct images of the thorax of healthy volunteers and patients with pulmonary emphysema, Revista Brasileira de Engenharia Biomédica29(4) (2013), 363–376.
63.
RenS.HeK.GirshickR. and SunJ., Faster R-CNN: Towards Real-Time Object Detection with Region Proposal Networks, 39 (Jun 2017), pp. 1137–1149.
64.
RodriguesM.B.MarinhoL.B.NobregaR.V.M.SouzaJ.W.M. and Reboucas FilhoP.P., Lung Segmentation in Chest Computerized Tomography Images Using the Border Following Algorithm, in: MadureiraA.M.AbrahamA.GamboaD.NovaisP., eds, Intelligent Systems Design and Applications (ISDA 2016), Vol. 557 of Advances in Intelligent Systems and Computing, Inst Super Engn Porto; Machine Intelligence Res Labs, 2017, pp. 539–548. 16th International Conference on Intelligent Systems Design and Applications (ISDA), Porto, PORTUGAL, DEC 16–18, 2016.
65.
SantosR.M.MatosL.N.MacedoH.T. and MontalvaoJ., Speech recognition in noisy environments with Convolutional Neural Networks, in: 2015 Brazilian Conference on Intelligent Systems (BRACIS 2015), Soc Brasileira Comp SBC; Univ Federal do Rio Grande do Norte, 2015, pp. 175–179. 4th Brazilian Conference on Intelligent Systems (BRACIS), Natal, BRAZIL, NOV 04–07, 2015.
66.
SenthilkumaranN. and VaithegiS., Image segmentation by using thresholding techniques for medical images, Computer Science & Engineering: An International Journal6(1) (2016), 1–13.
67.
SergioA.T. and LudermirT.B., Deep Learning for Wind Speed Forecasting in Northeastern Region of Brazil, in: 2015 Brazilian Conference On Intelligent Systems (BRACIS 2015), Soc Brasileira Comp SBC; Univ Federal do Rio Grande do Norte, 2015, pp. 322–327. 4th Brazilian Conference on Intelligent Systems (BRACIS), Natal, BRAZIL, NOV 04–07, 2015.
68.
ShiZ.HaoH.ZhaoM.FengY.HeL.WangY. and SuzukiK., A deep CNN based transfer learning method for false positive reduction, Multimedia Tools and Applications78(1) (Jan 2019), 1017–1033.
69.
ShinH.-C.RothH.R.GaoM.LuL.XuZ.NoguesI.YaoJ.MolluraD. and SummersR.M., Deep convolutional neural networks for computer-aided detection: CNN architectures, dataset characteristics and transfer learning, IEEE Transactions on Medical Imaging35(5, SI) (May 2016), 1285–1298.
70.
SimonyanK.VedaldiA. and ZissermanA., Deep inside convolutional networks: Visualising image classification models and saliency maps, arXiv preprint arXiv:1312.6034, 2013.
71.
SinghP.K.DashM.K.MittalP.NandiS.K. and NandiS., Misbehavior detection in c-its using deep learning approach, in: International Conference on Intelligent Systems Design and Applications, Springer, 2018, pp. 641–652.
72.
SodhroA.H.PirbhulalS.LuoZ. and de AlbuquerqueV.H.C., Towards an optimal resource management for IoT based Green and sustainable smart cities, Journal of Cleaner Production220 (May 20 2019), 1167–1179.
73.
Suarez GomezS.L.Gonzalez GutierrezC.Santos RodriguezJ.D.Sanchez RodriguezM.L.Sanchez LasherasF. and de Cos JuezF.J., Analysing the Performance of a Tomographic Reconstructor with Different Neural Networks Frameworks, in: MadureiraA.M.AbrahamA.GamboaD.NovaisP., eds, Intelligent Systems Design and Applications (ISDA 2016), Vol. 557 of Advances in Intelligent Systems and Computing, Inst Super Engn Porto; Machine Intelligence Res Labs, 2017, pp. 1051–1060. 16th International Conference on Intelligent Systems Design and Applications (ISDA), Porto, PORTUGAL, DEC 16–18, 2016.
74.
SunJ. and BinderA., Comparison of Deep Learning Architectures for H&E Histopathology Images, in: 2017 IEEE Conference on Big Data and Analytics (ICBDA), IEEE; IEEE Comp Soc Malaysia, 2017, pp. 43–48. IEEE Conference on Big Data and Analytics (ICBDA), Kuching, MALAYSIA, NOV 16–17, 2017.
75.
TeamE.E., WHO publishes Global tuberculosis report 2013, 18 (OCT 24 2013).
76.
ThawaniR.McLaneM.BeigN.GhoseS.PrasannaP.VelchetiV. and MadabhushiA., Radiomics and radiogenomics in lung cancer: A review for the clinician, Lung Cancer115 (Jan 2018), 34–41.
77.
TheodoridisS. and KoutroumbasK., Pattern Recognition (Fourth Edition), Academic Press, USA, 2008.
78.
TravisW.D.BrambillaE.NicholsonA.G.YatabeY.AustinJ.H.M.BeasleyM.B.ChirieacL.R.DacicS.DuhigE.FliederD.B.GeisingerK.HirschF.R.IshikawaY.KerrK.M.NoguchiM.PelosiG.PowellC.A.TsaoM.S.WistubaI. and PanelW., The 2015 world health organization classification of lung tumors impact of genetic, clinical and radiologic advances since the 2004 classification, Journal of Thoracic Oncology10(9) (Sep 2015), 1243–1260.
79.
van OpbroekA.AchterbergH.C.VernooijM.W. and de BruijneM., Transfer learning for image segmentation by combining image weighting and kernel learning, IEEE Transactions on Medical Imaging38(1) (Jan 2019), 213–224.
80.
VapnikV.N., Statistical Learning Theory, John Wiley & Sons, Nova Jersey, EUA, 1998.
81.
WangX.TengP.LoP.BanolaA.KimG.AbtinF.GoldinJ. and BrownM., High Throughput Lung and Lobar Segmentation by 2D and 3D CNN on Chest CT with Diffuse Lung Disease, in: StoyanovD.TaylorZ.KainzB.MaicasG.BeichelR.R., eds, Image Analysis for Moving Organ, Breast, and Thoracic Images, Vol. 11040 of Lecture Notes in Computer Science, 2018, pp. 202–214. 3rd International Workshop on Reconstruction and Analysis of Moving Body Organs (RAMBO)/4th International Workshop on Breast Image Analysis (BIA)/1st International Workshop on Thoracic Image Analysis (TIA), Granada, SPAIN, SEP 16–20, 2018.
82.
YanH.LuH.YeM.YanK.XuY. and JinQ., Improved mask r-cnn for lung nodule segmentation, in: 2019 10th International Conference on Information Technology in Medicine and Education (ITME), IEEE, 2019, pp. 137–141.
83.
YangQ.ZhangY.DaiW. and PanS.J., Transfer learning, Cambridge University Press, 2020.
84.
YangY.SuZ. and SunL., Medical image enhancement algorithm based on wavelet transform, Electronics Letters46(2) (Jan 21 2010), 120–U33.
85.
ZeilerM.D. and FergusR., Visualizing and understanding convolutional networks, in: European Conference on Computer Vision, Springer, 2014, pp. 818–833.
86.
ZhangS.ChenH. and LiJ., Segmentation of microcalcifications in mammograms based on multi-resolution region growth and image difference, in: 2011 4th International Congress on Image and Signal Processing, IEEE, Vol. 3, 2011, pp. 1273–1276.
87.
ZhuZ.PengG.ChenY. and GaoH., A convolutional neural network based on a capsule network with strong generalization for bearing fault diagnosis, Neurocomputing323 (Jan 5 2019), 62–75.
