Double-reading mammograms using artificial intelligence technologies: A new model of mass preventive examination organization

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BACKGROUND: In recent years, the availability of medical datasets and technologies for software development based on artificial intelligence technology has resulted in a growth in the number of solutions for medical diagnostics, particularly mammography. Registered as a medical device, this program can interpret digital mammography, significantly saving time, material, and human resources in healthcare while ensuring the quality of mammary gland preventive studies.

AIM: This study aims to justify the possibility and effectiveness of artificial intelligence-based software for the first interpretation of digital mammograms while maintaining the practice of a radiologist’s second description of X-ray images.

MATERIALS AND METHODS: A dataset of 100 digital mammography studies (50 — “absence of target pathology” and 50 ― “presence of target pathology,” with signs of malignant neoplasms) was processed by software based on artificial intelligence technology that was registered as a medical device in the Russian Federation. Receiver operating characteristic analysis was performed. Limitations of the study include the values of diagnostic accuracy metrics obtained for software based on artificial intelligence technology versions, relevant at the end of 2022.

RESULTS: When set to 80.0% sensitivity, artificial intelligence specificity was 90.0% (95% CI, 81.7–98.3), and accuracy was 85.0% (95% CI, 78.0–92.0). When set to 100% specificity, artificial intelligence demonstrated 56.0% sensitivity (95% CI, 42.2–69.8) and 78.0% accuracy (95% CI, 69.9–86.1). When the sensitivity was set to 100%, the artificial intelligence specificity was 54.0% (95% CI, 40.2–67.8), and the accuracy was 77.0% (95% CI, 68.8–85.2). Two approaches have been proposed, providing an autonomous first interpretation of digital mammography using artificial intelligence. The first approach is to evaluate the X-ray image using artificial intelligence with a higher sensitivity than that of the double-reading mammogram by radiologists, with a comparable level of specificity. The second approach implies that artificial intelligence-based software will determine the mammogram category (“absence of target pathology” or “presence of target pathology”), indicating the degree of “confidence” in the obtained result, depending on the corridor into which the predicted value falls.

CONCLUSIONS: Both proposed approaches for using artificial intelligence-based software for the autonomous first interpretation of digital mammograms can provide diagnostic quality comparable to, if not superior to, double-image reading by radiologists. The economic benefit from the practical implementation of this approach nationwide can range from 0.6 to 5.5 billion rubles annually.

Sobre autores

Yuriy Vasilev

Moscow Center for Diagnostics and Telemedicine

Email: npcmr@zdrav.mos.ru
ORCID ID: 0000-0002-0208-5218
Código SPIN: 4458-5608

MD, Cand. Sci. (Med)

Rússia, Moscow

Ilya Tyrov

Moscow Health Care Department

Email: npcmr@zdrav.mos.ru
ORCID ID: 0000-0001-9337-624X
Código SPIN: 8625-3458
Rússia, Moscow

Anton Vladzymyrskyy

Moscow Center for Diagnostics and Telemedicine

Email: npcmr@zdrav.mos.ru
ORCID ID: 0000-0002-2990-7736
Código SPIN: 3602-7120

MD, Dr. Sci. (Med), Professor

Rússia, Moscow

Kirill Arzamasov

Moscow Center for Diagnostics and Telemedicine

Email: npcmr@zdrav.mos.ru
ORCID ID: 0000-0001-7786-0349
Código SPIN: 3160-8062

MD, Cand. Sci. (Med)

Rússia, Moscow

Igor Shulkin

Moscow Center for Diagnostics and Telemedicine

Email: npcmr@zdrav.mos.ru
ORCID ID: 0000-0002-7613-5273
Código SPIN: 5266-0618
Rússia, Moscow

Daria Kozhikhina

Moscow Center for Diagnostics and Telemedicine

Email: npcmr@zdrav.mos.ru
ORCID ID: 0000-0001-7690-8427
Código SPIN: 5869-3854
Rússia, Moscow

Lev Pestrenin

Moscow Center for Diagnostics and Telemedicine

Autor responsável pela correspondência
Email: PestreninLD@zdrav.mos.ru
ORCID ID: 0000-0002-1786-4329
Código SPIN: 7193-7706

Junior Research Associate

Rússia, Moscow

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2. Fig. 1. ROC for AI-based software. The highlight shows the 95% confidence interval. Experimental values corresponding to 100.0% sensitivity (a), 100.0% specificity (b), and 80.0% sensitivity (c) are highlighted individually. For each experimental point, the rectangle shows the diagnostic accuracy metrics at the corresponding cutoff value.

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3. Fig. 2. Concept of an approach to the first mammogram reading using artificial intelligence involving binary image classification with an indication of the degree of confidence of the AI-based software in the results obtained.

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