Development and evaluation of a deep learning model to improve the usability of polyp detection systems during interventions

Markus Brand; Joel Troya; Adrian Krenzer; Zita Saßmannshausen; Wolfram G Zoller; Alexander Meining; Thomas J Lux; Alexander Hann

doi:10.1002/ueg2.12235

Development and evaluation of a deep learning model to improve the usability of polyp detection systems during interventions

United European Gastroenterol J. 2022 Jun;10(5):477-484. doi: 10.1002/ueg2.12235. Epub 2022 May 5.

Authors

Markus Brand¹, Joel Troya¹, Adrian Krenzer^{1

2}, Zita Saßmannshausen¹, Wolfram G Zoller³, Alexander Meining¹, Thomas J Lux¹, Alexander Hann¹

Affiliations

¹ Interventional and Experimental Endoscopy (InExEn), Internal Medicine II, Gastroenterology, University Hospital Würzburg, Würzburg, Germany.
² Artificial Intelligence and Knowledge Systems, Institute for Computer Science, Julius-Maximilians-Universität Würzburg, Würzburg, Germany.
³ Department of Internal Medicine and Gastroenterology, Katharinenhospital, Stuttgart, Germany.

Abstract

Background: The efficiency of artificial intelligence as computer-aided detection (CADe) systems for colorectal polyps has been demonstrated in several randomized trials. However, CADe systems generate many distracting detections, especially during interventions such as polypectomies. Those distracting CADe detections are often induced by the introduction of snares or biopsy forceps as the systems have not been trained for such situations. In addition, there are a significant number of non-false but not relevant detections, since the polyp has already been previously detected. All these detections have the potential to disturb the examiner's work.

Objectives: Development and evaluation of a convolutional neuronal network that recognizes instruments in the endoscopic image, suppresses distracting CADe detections, and reliably detects endoscopic interventions.

Methods: A total of 580 different examination videos from 9 different centers using 4 different processor types were screened for instruments and represented the training dataset (519,856 images in total, 144,217 contained a visible instrument). The test dataset included 10 full-colonoscopy videos that were analyzed for the recognition of visible instruments and detections by a commercially available CADe system (GI Genius, Medtronic).

Results: The test dataset contained 153,623 images, 8.84% of those presented visible instruments (12 interventions, 19 instruments used). The convolutional neuronal network reached an overall accuracy in the detection of visible instruments of 98.59%. Sensitivity and specificity were 98.55% and 98.92%, respectively. A mean of 462.8 frames containing distracting CADe detections per colonoscopy were avoided using the convolutional neuronal network. This accounted for 95.6% of all distracting CADe detections.

Conclusions: Detection of endoscopic instruments in colonoscopy using artificial intelligence technology is reliable and achieves high sensitivity and specificity. Accordingly, the new convolutional neuronal network could be used to reduce distracting CADe detections during endoscopic procedures. Thus, our study demonstrates the great potential of artificial intelligence technology beyond mucosal assessment.

Keywords: CADe; colonoscopy; deep learning; instrument; intervention.

Publication types

Research Support, Non-U.S. Gov't

MeSH terms

Artificial Intelligence
Colonic Polyps* / diagnosis
Colonic Polyps* / pathology
Colonic Polyps* / surgery
Colonoscopy / methods
Deep Learning*
Humans
Sensitivity and Specificity