Literature DB >> 33937804

A User Interface for Optimizing Radiologist Engagement in Image Data Curation for Artificial Intelligence.

Mutlu Demirer1, Sema Candemir1, Matthew T Bigelow1, Sarah M Yu1, Vikash Gupta1, Luciano M Prevedello1, Richard D White1, Joseph S Yu1, Rainer Grimmer1, Michael Wels1, Andreas Wimmer1, Abdul H Halabi1, Alvin Ihsani1, Thomas P O'Donnell1, Barbaros S Erdal1.   

Abstract

PURPOSE: To delineate image data curation needs and describe a locally designed graphical user interface (GUI) to aid radiologists in image annotation for artificial intelligence (AI) applications in medical imaging.
MATERIALS AND METHODS: GUI components support image analysis toolboxes, picture archiving and communication system integration, third-party applications, processing of scripting languages, and integration of deep learning libraries. For clinical AI applications, GUI components included two-dimensional segmentation and classification; three-dimensional segmentation and quantification; and three-dimensional segmentation, quantification, and classification. To assess radiologist engagement and performance efficiency associated with GUI-related capabilities, image annotation rate (studies per day) and speed (minutes per case) were evaluated in two clinical scenarios of varying complexity: hip fracture detection and coronary atherosclerotic plaque demarcation and stenosis grading.
RESULTS: For hip fracture, 1050 radiographs were annotated over 7 days (150 studies per day; median speed: 10 seconds per study [interquartile range, 3-21 seconds per study]). A total of 294 coronary CT angiographic studies with 1843 arteries and branches were annotated for atherosclerotic plaque over 23 days (15.2 studies [80.1 vessels] per day; median speed: 6.08 minutes per study [interquartile range, 2.8-10.6 minutes per study] and 73 seconds per vessel [interquartile range, 20.9-155 seconds per vessel]).
CONCLUSION: GUI-component compatibility with common image analysis tools facilitates radiologist engagement in image data curation, including image annotation, supporting AI application development and evolution for medical imaging. When complemented by other GUI elements, a continuous integrated workflow supporting formation of an agile deep neural network life cycle results.Supplemental material is available for this article.© RSNA, 2019. 2019 by the Radiological Society of North America, Inc.

Entities:  

Year:  2019        PMID: 33937804      PMCID: PMC8017380          DOI: 10.1148/ryai.2019180095

Source DB:  PubMed          Journal:  Radiol Artif Intell        ISSN: 2638-6100


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