Deep learning for caries lesion detection in near-infrared light transillumination images: A pilot study

Falk Schwendicke; Karim Elhennawy; Sebastian Paris; Philipp Friebertshäuser; Joachim Krois

doi:10.1016/j.jdent.2019.103260

Deep learning for caries lesion detection in near-infrared light transillumination images: A pilot study

J Dent. 2020 Jan:92:103260. doi: 10.1016/j.jdent.2019.103260. Epub 2019 Dec 9.

Authors

Falk Schwendicke¹, Karim Elhennawy², Sebastian Paris³, Philipp Friebertshäuser⁴, Joachim Krois³

Affiliations

¹ Department of Operative and Preventive Dentistry, Charité - Universitätsmedizin Berlin, Germany. Electronic address: falk.schwendicke@charite.de.
² Department of Operative and Preventive Dentistry, Charité - Universitätsmedizin Berlin, Germany; Department of Orthodontics, Dentofacial Orthopedics and Pedodontics, Charité - Universitätsmedizin Berlin, Germany.
³ Department of Operative and Preventive Dentistry, Charité - Universitätsmedizin Berlin, Germany.
⁴ Department of Operative and Preventive Dentistry, Charité - Universitätsmedizin Berlin, Germany; Markov Solutions, Berlin, Germany.

PMID: 31821853
DOI: 10.1016/j.jdent.2019.103260

Abstract

Objectives: In this pilot study, we applied deep convolutional neural networks (CNNs) to detect caries lesions in Near-Infrared-Light Transillumination (NILT) images.

Methods: 226 extracted posterior permanent human teeth (113 premolars, 113 molars) were allocated to groups of 2 + 2 teeth, and mounted in a pilot-tested diagnostic model in a dummy head. NILT images of single-tooth-segments were generated using DIAGNOcam (KaVo, Biberach). For each segment (on average 435 × 407 × 3 pixels), occlusal and/or proximal caries lesions were annotated by two experienced dentists using an in-house developed digital annotation tool. The pixel-based annotations were translated into binary class levels. We trained two state-of-the-art CNNs (Resnet18, Resnext50) and validated them via 10-fold cross validation. During the training process, we applied data augmentation (random resizing, rotations and flipping) and one-cycle-learning rate policy, setting the minimum and maximum learning rates to 10^-5 and 10^-3, respectively. Metrics for model performance were the area-under-the-receiver-operating-characteristics-curve (AUC), sensitivity, specificity, and positive/negative predictive values (PPV/NPV). Feature visualization was additionally applied to assess if the CNNs built on features dentists would also use.

Results: The tooth-level prevalence of caries lesions was 41%. The two models performed similar on predicting caries on tooth segments of NILT images. The marginal better model with respect to AUC was Resnext50, where we retrained the last 9 network layers, using the Adam optimizer, a learning rate of 0.5 × 10^-4, and a batch size of 10. The mean (95% CI) AUC was 0.74 (0.66-0.82). Sensitivity and specificity were 0.59 (0.47-0.70) and 0.76 (0.68-0.84) respectively. The resulting PPV was 0.63 (0.51-0.74), the NPV 0.73 (0.65-0.80). Visual inspection of model predictions found the model to be sensitive to areas affected by caries lesions.

Conclusions: A moderately deep CNN trained on a limited amount of NILT image data showed satisfying discriminatory ability to detect caries lesions.

Clinical significance: CNNs may be useful to assist NILT-based caries detection. This could be especially relevant in non-conventional dental settings, like schools, care homes or rural outpost centers.

Keywords: Artificial intelligence; Caries; Diagnostics; Digital imaging/radiology; Mathematical modeling.

Publication types

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

MeSH terms

Deep Learning
Dental Caries*
Humans
Pilot Projects
Sensitivity and Specificity
Transillumination*