Detecting Pulp Stones with Automatic Deep Learning in Bitewing Radiographs: A Pilot Study of Artificial Intelligence-Reference-Cited by-同舟云学术

Detecting Pulp Stones with Automatic Deep Learning in Bitewing Radiographs: A Pilot Study of Artificial Intelligence

Published:2023-04-30 Issue:1 Volume:50 Page:12-16
ISSN:2757-6744
Container-title:European Annals of Dental Sciences
language:
Short-container-title:

Author:

ALTINDAĞ Ali¹^ORCID,UZUN Sultan¹^ORCID,BAYRAKDAR İbrahim Şevki²^ORCID,ÇELİK Özer³^ORCID

Affiliation:

1. NECMETTIN ERBAKAN UNIVERSITY, FACULTY OF DENTISTRY, DENTISTRY PR.

2. ESKISEHIR OSMANGAZI UNIVERSITY, FACULTY OF DENTISTRY

3. ESKISEHIR OSMANGAZI UNIVERSITY, FACULTY OF ARTS AND SCIENCES, DEPARTMENT OF MATHEMATICS AND COMPUTER, MATHEMATICS-COMPUTER PR.

Abstract

Purpose: This study aims to examine the diagnostic performance of detecting pulp stones with a deep learning model on bite-wing radiographs. Material and Methods: 2203 radiographs were scanned retrospectively. 1745 pulp stones were marked on 1269 bite-wing radiographs with the CranioCatch labeling program (CranioCatch, Eskişehir, Turkey) in patients over 16 years old after the consensus of two experts of Maxillofacial Radiologists. This dataset was divided into 3 grou as training (n = 1017 (1396 labels), validation (n = 126 (174 labels)) and test (n = 126) (175 labels) sets, respectively. The deep learning model was developed using Mask R-CNN architecture. A confusion matrix was used to evaluate the success of the model. Results: The results of precision, sensitivity, and F1 obtained using the Mask R-CNN architecture in the test dataset were found to be 0.9115, 0.8879, and 0.8995, respectively. Discussion- Conclusion: Deep learning algorithms can detect pulp stones. With this, clinicians can use software systems based on artificial intelligence as a diagnostic support system. Mask R-CNN architecture can be used for pulp stone detection with approximately 90% sensitivity. The larger data sets increase the accuracy of deep learning systems. More studies are needed to increase the success rates of deep learning models.

Publisher

Ankara University

Subject

General Materials Science

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