Establishment and validation of a computer-assisted colonic polyp localization system based on deep learning

BACKGROUNDArtificial intelligence in colonoscopy is an emerging field, and its application may help colonoscopists improve inspection quality and reduce the rate of missed polyps and adenomas. Several deep learning-based computer-assisted detection (CADe) techniques were established from small singl...

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Published in:World journal of gastroenterology : WJG 2021-08, Vol.27 (31), p.5232-5246
Main Authors: Zhao, Sheng-Bing, Yang, Wei, Wang, Shu-Ling, Pan, Peng, Wang, Run-Dong, Chang, Xin, Sun, Zhong-Qian, Fu, Xing-Hui, Shang, Hong, Wu, Jian-Rong, Chen, Li-Zhu, Chang, Jia, Song, Pu, Miao, Ying-Lei, He, Shui-Xiang, Miao, Lin, Jiang, Hui-Qing, Wang, Wen, Yang, Xia, Dong, Yuan-Hang, Lin, Han, Chen, Yan, Gao, Jie, Meng, Qian-Qian, Jin, Zhen-Dong, Li, Zhao-Shen, Bai, Yu
Format: Article
Language:English
Subjects:
Clinical and Translational Research
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Summary:BACKGROUNDArtificial intelligence in colonoscopy is an emerging field, and its application may help colonoscopists improve inspection quality and reduce the rate of missed polyps and adenomas. Several deep learning-based computer-assisted detection (CADe) techniques were established from small single-center datasets, and unrepresentative learning materials might confine their application and generalization in wide practice. Although CADes have been reported to identify polyps in colonoscopic images and videos in real time, their diagnostic performance deserves to be further validated in clinical practice. AIMTo train and test a CADe based on multicenter high-quality images of polyps and preliminarily validate it in clinical colonoscopies. METHODSWith high-quality screening and labeling from 55 qualified colonoscopists, a dataset consisting of over 71000 images from 20 centers was used to train and test a deep learning-based CADe. In addition, the real-time diagnostic performance of CADe was tested frame by frame in 47 unaltered full-ranged videos that contained 86 histologically confirmed polyps. Finally, we conducted a self-controlled observational study to validate the diagnostic performance of CADe in real-world colonoscopy with the main outcome measure of polyps per colonoscopy in Changhai Hospital. RESULTSThe CADe was able to identify polyps in the test dataset with 95.0% sensitivity and 99.1% specificity. For colonoscopy videos, all 86 polyps were detected with 92.2% sensitivity and 93.6% specificity in frame-by-frame analysis. In the prospective validation, the sensitivity of CAD in identifying polyps was 98.4% (185/188). Folds, reflections of light and fecal fluid were the main causes of false positives in both the test dataset and clinical colonoscopies. Colonoscopists can detect more polyps (0.90 vs 0.82, P < 0.001) and adenomas (0.32 vs 0.30, P = 0.045) with the aid of CADe, particularly polyps < 5 mm and flat polyps (0.65 vs 0.57, P < 0.001; 0.74 vs 0.67, P = 0.001, respectively). However, high efficacy is not realized in colonoscopies with inadequate bowel preparation and withdrawal time (P = 0.32; P = 0.16, respectively). CONCLUSIONCADe is feasible in the clinical setting and might help endoscopists detect more polyps and adenomas, and further confirmation is warranted.
ISSN:1007-9327
2219-2840
DOI:10.3748/wjg.v27.i31.5232