Papers
Topics
Authors
Recent
Gemini 2.5 Flash
Gemini 2.5 Flash
102 tokens/sec
GPT-4o
59 tokens/sec
Gemini 2.5 Pro Pro
43 tokens/sec
o3 Pro
6 tokens/sec
GPT-4.1 Pro
50 tokens/sec
DeepSeek R1 via Azure Pro
28 tokens/sec
2000 character limit reached

2.75D: Boosting learning by representing 3D Medical imaging to 2D features for small data (2002.04251v3)

Published 11 Feb 2020 in eess.IV and cs.CV

Abstract: In medical-data driven learning, 3D convolutional neural networks (CNNs) have started to show superior performance to 2D CNNs in numerous deep learning tasks, proving the added value of 3D spatial information in feature representation. However, the difficulty in collecting more training samples to converge, more computational resources and longer execution time make this approach less applied. Also, applying transfer learning on 3D CNN is challenging due to a lack of publicly available pre-trained 3D models. To tackle these issues, we proposed a novel 2D strategical representation of volumetric data, namely 2.75D. In this work, the spatial information of 3D images is captured in a single 2D view by a spiral-spinning technique. As a result, 2D CNN networks can also be used to learn volumetric information. Besides, we can fully leverage pre-trained 2D CNNs for downstream vision problems. We also explore a multi-view 2.75D strategy, 2.75D 3 channels (2.75Dx3), to boost the advantage of 2.75D. We evaluated the proposed methods on three public datasets with different modalities or organs (Lung CT, Breast MRI, and Prostate MRI), against their 2D, 2.5D, and 3D counterparts in classification tasks. Results show that the proposed methods significantly outperform other counterparts when all methods were trained from scratch on the lung dataset. Such performance gain is more pronounced with transfer learning or in the case of limited training data. Our methods also achieved comparable performance on other datasets. In addition, our methods achieved a substantial reduction in time consumption of training and inference compared with the 2.5D or 3D method.

PDF HTML Abstract
Ai Sparkles Streamline Icon: https://streamlinehq.com Summarize Bookmark Chat Bubble Oval Streamline Icon: https://streamlinehq.com Chat (Pro)
Definition Search Book Streamline Icon: https://streamlinehq.com
References (58)
  1. Cancer screening recommendations: an international comparison of high income countries. Public health reviews, 39(1):1–19, 2018.
  2. Progress and prospects of early detection in lung cancer. Open biology, 7(9):170070, 2017.
  3. Imagenet large scale visual recognition challenge. International journal of computer vision, 115(3):211–252, 2015.
  4. Very deep convolutional networks for large-scale image recognition. arXiv preprint arXiv:1409.1556, 2014.
  5. Deep residual learning for image recognition. In Proceedings of the IEEE conference on computer vision and pattern recognition, pages 770–778, 2016.
  6. Multi-modal trained artificial intelligence solution to triage chest x-ray for covid-19 using pristine ground-truth, versus radiologists. Neurocomputing, 485:36–46, 2022.
  7. Lesion segmentation in ultrasound using semi-pixel-wise cycle generative adversarial nets. IEEE/ACM transactions on computational biology and bioinformatics, 2020.
  8. Pulmonary nodule detection in ct images: false positive reduction using multi-view convolutional networks. IEEE transactions on medical imaging, 35(5):1160–1169, 2016.
  9. Automatic collateral scoring from 3d cta images. IEEE Transactions on Medical Imaging, 39(6):2190–2200, 2020a.
  10. Transferring from ex-vivo to in-vivo: Instrument localization in 3d cardiac ultrasound using pyramid-unet with hybrid loss. In International Conference on Medical Image Computing and Computer-Assisted Intervention, pages 263–271. Springer, 2019.
  11. Prediction of tissue outcome and assessment of treatment effect in acute ischemic stroke using deep learning. Stroke, 49(6):1394–1401, 2018.
  12. Spatio-temporal deep learning for automatic detection of intracranial vessel perforation in digital subtraction angiography during endovascular thrombectomy. Medical Image Analysis, 77:102377, 2022.
  13. Automated sleep state classification of wide-field calcium imaging data via multiplex visibility graphs and deep learning. Journal of neuroscience methods, 366:109421, 2022.
  14. Prediction of final infarct volume from native ct perfusion and treatment parameters using deep learning. Medical image analysis, 59:101589, 2020.
  15. ImageNet: A Large-Scale Hierarchical Image Database. In CVPR09, 2009.
  16. Going deeper with convolutions. In Proceedings of the IEEE conference on computer vision and pattern recognition, pages 1–9, 2015.
  17. Deep learning with convolutional neural network for differentiation of liver masses at dynamic contrast-enhanced ct: a preliminary study. Radiology, 286(3):887–896, 2018.
  18. Deep convolutional neural network for the classification of hepatocellular carcinoma and intrahepatic cholangiocarcinoma. In Medical Imaging 2018: Computer-Aided Diagnosis, volume 10575, page 1057528. International Society for Optics and Photonics, 2018.
  19. Automatic detection on intracranial aneurysm from digital subtraction angiography with cascade convolutional neural networks. Biomedical engineering online, 18(1):110, 2019.
  20. Computer-aided detection of pulmonary nodules: a comparative study using the public lidc/idri database. European radiology, 26(7):2139–2147, 2016.
  21. Multilevel contextual 3-d cnns for false positive reduction in pulmonary nodule detection. IEEE Transactions on Biomedical Engineering, 64(7):1558–1567, 2016.
  22. Lung nodule detection in ct using 3d convolutional neural networks. In 2017 IEEE 14th International Symposium on Biomedical Imaging (ISBI 2017), pages 379–383. IEEE, 2017.
  23. Accurate pulmonary nodule detection in computed tomography images using deep convolutional neural networks. In International Conference on Medical Image Computing and Computer-Assisted Intervention, pages 559–567. Springer, 2017.
  24. Visual explanations from deep 3d convolutional neural networks for alzheimer’s disease classification. In AMIA annual symposium proceedings, volume 2018, page 1571. American Medical Informatics Association, 2018.
  25. 3d multi-view convolutional neural networks for lung nodule classification. PloS one, 12(11):e0188290, 2017.
  26. Deep 3d convolution neural network for ct brain hemorrhage classification. In Medical Imaging 2018: Computer-Aided Diagnosis, volume 10575, page 105751C. International Society for Optics and Photonics, 2018.
  27. Weakly supervised 3d deep learning for breast cancer classification and localization of the lesions in mr images. Journal of Magnetic Resonance Imaging, 50(4):1144–1151, 2019.
  28. 3d deep learning on medical images: a review. Sensors, 20(18):5097, 2020.
  29. An ensemble of 2d convolutional neural networks for tumor segmentation. In Scandinavian conference on image analysis, pages 201–211. Springer, 2015.
  30. Multi-view convolutional neural networks for 3d shape recognition. In Proceedings of the IEEE international conference on computer vision, pages 945–953, 2015.
  31. Pulmonary nodule classification with deep residual networks. International journal of computer assisted radiology and surgery, 12(10):1799–1808, 2017.
  32. Multiview convolutional neural networks for lung nodule classification. International Journal of Imaging Systems and Technology, 27(1):12–22, 2017.
  33. Multi-view multi-scale cnns for lung nodule type classification from ct images. Pattern Recognition, 77:262–275, 2018.
  34. Automated pulmonary nodule detection in ct images using deep convolutional neural networks. Pattern Recognition, 85:109–119, 2019.
  35. autotici: Automatic brain tissue reperfusion scoring on 2d dsa images of acute ischemic stroke patients. arXiv preprint arXiv: 2010.01432, 2020b.
  36. Approximate and exact cone-beam reconstruction with standard and non-standard spiral scanning. Physics in Medicine & Biology, 52(6):R1, 2007a.
  37. Segmentation of pulmonary nodules in three-dimensional ct images by use of a spiral-scanning technique. Medical Physics, 34(12):4678–4689, 2007b.
  38. Spiral scanning with improved control for faster imaging of afm. IEEE Transactions on Nanotechnology, 13(3):541–550, 2014.
  39. 2.75 d: Boosting learning efficiency and capability by representing 3d features in 2d. arXiv preprint arXiv:2002.04251, 2020c.
  40. Dynamic contrast-enhanced magnetic resonance images of breast cancer patients with tumor locations. data set]. Cancer Imag Archiv, 2021.
  41. A large-scale evaluation of automatic pulmonary nodule detection in chest ct using local image features and k-nearest-neighbour classification. Medical image analysis, 13(5):757–770, 2009.
  42. Automatic detection of subsolid pulmonary nodules in thoracic computed tomography images. Medical image analysis, 18(2):374–384, 2014.
  43. Automatic detection of large pulmonary solid nodules in thoracic ct images. Medical physics, 42(10):5642–5653, 2015.
  44. The lung image database consortium (lidc) and image database resource initiative (idri): a completed reference database of lung nodules on ct scans. Medical physics, 38(2):915–931, 2011.
  45. Validation, comparison, and combination of algorithms for automatic detection of pulmonary nodules in computed tomography images: the luna16 challenge. Medical image analysis, 42:1–13, 2017.
  46. A machine learning approach to radiogenomics of breast cancer: a study of 922 subjects and 529 dce-mri features. British journal of cancer, 119(4):508–516, 2018.
  47. Prostatex challenges for computerized classification of prostate lesions from multiparametric magnetic resonance images. Journal of Medical Imaging, 5(4):044501, 2018.
  48. Deep feature learning for knee cartilage segmentation using a triplanar convolutional neural network. In International conference on medical image computing and computer-assisted intervention, pages 246–253. Springer, 2013.
  49. Large-scale video classification with convolutional neural networks. In Proceedings of the IEEE conference on Computer Vision and Pattern Recognition, pages 1725–1732, 2014.
  50. Lung cancer detection and classification with 3d convolutional neural network (3d-cnn). Lung Cancer, 8(8):409, 2017.
  51. A survey on transfer learning. Knowledge and Data Engineering, IEEE Transactions on, 22(10):1345–1359, 2010.
  52. Hospital-scale chest x-ray database and benchmarks on weakly-supervised classification and localization of common thorax diseases. In IEEE CVPR, 2017.
  53. Chexnet: Radiologist-level pneumonia detection on chest x-rays with deep learning. arXiv preprint arXiv:1711.05225, 2017.
  54. Adam: A method for stochastic optimization. arXiv preprint arXiv:1412.6980, 2014.
  55. Understanding the difficulty of training deep feedforward neural networks. In Proceedings of the thirteenth international conference on artificial intelligence and statistics, pages 249–256, 2010.
  56. On combining computer-aided detection systems. IEEE Transactions on Medical Imaging, 30(2):215–223, 2010.
  57. Xu Sun and Weichao Xu. Fast implementation of delong’s algorithm for comparing the areas under correlated receiver operating characteristic curves. IEEE Signal Processing Letters, 21(11):1389–1393, 2014.
  58. Fully automated detection of breast cancer in screening mri using convolutional neural networks. Journal of Medical Imaging, 5(1):014502, 2018.
User Edit Pencil Streamline Icon: https://streamlinehq.com
Authors (8)
  1. Xin Wang (1307 papers)
  2. Ruisheng Su (15 papers)
  3. Weiyi Xie (9 papers)
  4. Wenjin Wang (56 papers)
  5. Yi Xu (304 papers)
  6. Ritse Mann (21 papers)
  7. Jungong Han (111 papers)
  8. Tao Tan (54 papers)
Citations (3)
View on Semantic Scholar