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©The Author(s) 2020.
World J Gastroenterol. Oct 14, 2020; 26(38): 5784-5796
Published online Oct 14, 2020. doi: 10.3748/wjg.v26.i38.5784
Published online Oct 14, 2020. doi: 10.3748/wjg.v26.i38.5784
Table 3 Summary of all the studies investigating the development of machine learning algorithms for the detection of early squamous cell neoplasia
| Ref. | Year | Endoscopic processor | Study design | Study aim | Algorithm used | No. of patients | No. of images | Sensitivity | Specificity |
| Shin et al[37] | 2015 | High resolution micro-endoscopy | Retrospective | Differentiate neoplastic and non-neoplastic squamous oesophageal mucosa | Quantitative image analysis. Two-class linear discriminant analysis to develop classifier | 177 | 375 | 87% | 97% |
| Quang et al[38] | 2016 | High resolution micro-endoscopy | Retrospective | Differentiate neoplastic and non-neoplastic squamous oesophageal mucosa | Two-class linear discriminant analysis to develop classifier | 3 | - | 95% | 91% |
| Horie et al[39] | 2018 | WLE, NBI, Olympus | Retrospective | Ability of AI to detect oesophageal cancer | Deep CNN (Multibox detector architecture) | 481 | - | 97% | - |
| Everson et al[16] | 2019 | Magnified NBI, Olympus | Retrospective | Develop AI system to classify IPCL patterns as normal/abnormal in endoscopically resectable lesions real time | CNN, explicit class activation maps generated to depict area of interest for CNN | 17 | 7046 | 89% | 98% |
| Nakagawa et al[34] | 2019 | Magnified and non-magnified, NBI, BLI, Olympus, Fujifilm | Retrospective | Predict depth of invasion of ESCN | Deep CNN (multibox detector architecture) | 959 | 15,252 | 90.1% | 95.8% |
| Kumagai et al[36] | 2019 | ECS | Retrospective | Deep learning AI to analyse ECS images as possible replacement of biopsy-based histology | CNN constructed based on GoogLeNet | - | 6235 | 92.6% | 89.3% |
| Zhao et al[40] | 2019 | ME NBI, Olympus | Retrospective | Classification of IPCLs to improve ESCN detection | A double-labeling fully convolutional network | 219 | - | 87% | 84.1% |
| Guo et al[3] | 2020 | ME and non-ME NBI, olympus | Retrospective | Develop a CAD for real-time diagnosis of ESCN | Model based on SegNet architecture | 2672 | 13144 images (4250 malignant, 8894 non-cancerous), 168865 video frames | Images = 98.04%, non-magnified video = 60.8%, magnified video = 96.1% | Images = 95.03%, non-magnified /magnified video = 99.9% |
| Tokai et al[41] | 2020 | WLE, NBI, Olympus | Retrospective | Ability of AI to measure squamous cell cancer depth | Deep CNN | - | 2044 | 84.1% | 73.3% |
| Ohmori et al[42] | 2020 | Magnified and non-magnified, WLE, NBI, BLI, Olympus, Fujifilm | Retrospective | Detect Oesophageal squamous cell cancer | CNN | - | 11806 non- magnified images, 11483 magnified images | Non-ME WLE = 90%, non-ME NBI/BLI = 100%, ME = 98% | Non-ME WLE = 76%, non-ME NBI/BLI = 63%, ME = 56% |
- Citation: Hussein M, González-Bueno Puyal J, Mountney P, Lovat LB, Haidry R. Role of artificial intelligence in the diagnosis of oesophageal neoplasia: 2020 an endoscopic odyssey. World J Gastroenterol 2020; 26(38): 5784-5796
- URL: https://www.wjgnet.com/1007-9327/full/v26/i38/5784.htm
- DOI: https://dx.doi.org/10.3748/wjg.v26.i38.5784