Artificial Intelligence in Colorectal Polyp Detection and Characterization.

Alexander Le, Moro O Salifu, Isabel M McFarlane
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引用次数: 4

Abstract

Background: Over the past 20 years, the advancement of artificial intelligence (AI) and deep learning (DL) has allowed for fast sorting and analysis of large sets of data. In the field of gastroenterology, colorectal screening procedures produces an abundance of data through video and imaging. With AI and DL, this information can be used to create systems where automatic polyp detection and characterization is possible. Convoluted Neural Networks (CNNs) have proven to be an effective way to increase polyp detection and ultimately adenoma detection rates. Different methods of polyp characterization of being hyperplastic vs. adenomatous or non-neoplastic vs. neoplastic has also been investigated showing promising results.

Findings: The rate of missed polyps on colonoscopy can be as high as 25%. At the beginning of the 2000s, hand-crafted machine learning (ML) algorithms were created and trained retrospectively on colonoscopy images and videos, achieving high sensitivity, specificity, and accuracy of over 90% in many of the studies. Over time, the advancement of DL and CNNs has allowed algorithms to be trained on non-medical images and applied retrospectively to colonoscopy videos and images with similar results. Within the past few years, these algorithms have been applied in real-time colonoscopies and has shown mixed results, one showing no difference while others showing increased polyp detection.Various methods of polyp characterization have also been investigated. Through AI, DL, and CNNs polyps can be identified has hyperplastic/adenomatous or non-neoplastic/neoplastic with high sensitivity, specificity, and accuracy. One of the research areas in polyp characterization is how to capture the polyp image. This paper looks at different modalities of characterizing polyps such as magnifying narrow band imaging (NBI), endocytoscopy, laser-induced florescent spectroscopy, auto-florescent endoscopy, and white-light endoscopy.

Conclusions: Overall, much progress has been made in automatic detection and characterization of polyps in real time. Barring ethical or mass adoption setbacks, it is inevitable that AI will be involved in the field of GI, especially in colorectal polyp detection and identification.

人工智能在结直肠息肉检测与表征中的应用。
背景:在过去的20年里,人工智能(AI)和深度学习(DL)的进步使得对大型数据集的快速分类和分析成为可能。在胃肠病学领域,结直肠筛查程序通过视频和成像产生丰富的数据。通过人工智能和深度学习,这些信息可用于创建自动息肉检测和表征系统。卷积神经网络(cnn)已被证明是提高息肉检测和最终腺瘤检测率的有效方法。不同的方法表征息肉增生与腺瘤或非肿瘤性与肿瘤性也进行了研究,显示出有希望的结果。结果:结肠镜检查息肉漏诊率可高达25%。在21世纪初,手工制作的机器学习(ML)算法被创建并在结肠镜检查图像和视频上进行回顾性训练,在许多研究中实现了超过90%的高灵敏度、特异性和准确性。随着时间的推移,深度学习和cnn的进步使得算法可以在非医学图像上进行训练,并回顾性地应用于结肠镜检查视频和图像,结果类似。在过去的几年中,这些算法已经应用于实时结肠镜检查,并显示出不同的结果,一种显示没有差异,而另一种显示增加了息肉的检测。还研究了各种表征息肉的方法。通过AI、DL和cnn可以识别息肉是增生性/腺瘤性还是非肿瘤性/肿瘤性,具有较高的敏感性、特异性和准确性。如何捕获息肉图像是息肉表征的研究热点之一。本文着眼于不同的方式表征息肉,如放大窄带成像(NBI),内吞镜,激光诱导荧光光谱,自动荧光内镜和白光内镜。结论:总的来说,在息肉的实时自动检测和表征方面取得了很大进展。除了伦理或大规模应用方面的挫折,人工智能将不可避免地进入胃肠道领域,特别是在结肠直肠息肉的检测和识别方面。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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