Abstract
The approximity of the inferior alveolar nerve (IAN) to the roots of lower third molars (M3) is a risk factor for the occurrence of nerve damage and subsequent sensory disturbances of the lower lip and chin following the removal of third molars. To assess this risk, the identification of M3 and IAN on dental panoramic radiographs (OPG) is mandatory. In this study, we developed and validated an automated approach, based on deep-learning, to detect and segment the M3 and IAN on OPGs. As a reference, M3s and IAN were segmented manually on 81 OPGs. A deep-learning approach based on U-net was applied on the reference data to train the convolutional neural network (CNN) in the detection and segmentation of the M3 and IAN. Subsequently, the trained U-net was applied onto the original OPGs to detect and segment both structures. Dice-coefficients were calculated to quantify the degree of similarity between the manually and automatically segmented M3s and IAN. The mean dice-coefficients for M3s and IAN were 0.947 ± 0.033 and 0.847 ± 0.099, respectively. Deep-learning is an encouraging approach to segment anatomical structures and later on in clinical decision making, though further enhancement of the algorithm is advised to improve the accuracy.
Highlights
The removal of the third molar is one of the most frequently performed surgical procedures in oral surgery
Previous studies have demonstrated that certain radiographic features on OPGs, such as darkening of the root, narrowing of the mandibular canal, interruption of the white line, are risk factors for inferior alveolar nerve (IAN) injuries[11,12,13]
There may be a high potential for the implementation of deep-learning in the detection of third molars, mandibular canals and the identification of certain radiographic signs for potential IAN injuries
Summary
The removal of the third molar is one of the most frequently performed surgical procedures in oral surgery. There may be a high potential for the implementation of deep-learning in the detection of third molars, mandibular canals and the identification of certain radiographic signs for potential IAN injuries. The combined use of deep learning and OPG may allow an improved risk assessment of IAN injuries prior to the removal of third molars. The aim of this present study was to achieve an automated high-performance segmentation of the third molars, and the inferior alveolar nerves (IAN) on OPG images using deep-learning as a fundamental basis for an improved and more automated risk assessment of IAN injuries
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