Jumpei Okawa, Kazuhiro Hori, Hiromi Izuno, Masayo Fukuda, Takako Ujihashi, Shohei Kodama, Tasuku Yoshimoto, Rikako Sato, Takahiro Ono
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引用次数: 0
Abstract
Purpose: To build an image recognition network to evaluate tongue coating status.
Methods: Two image recognition networks were built: one for tongue detection and another for tongue coating classification. Digital tongue photographs were used to develop both networks; images from 251 (178 women, 74.7±6.6 years) and 144 older adults (83 women, 73.8±7.3 years) who volunteered to participate were used for the tongue detection network and coating classification network, respectively. The learning objective of the tongue detection network is to extract a rectangular region that includes the tongue. You-Only-Look-Once (YOLO) v2 was used as the detection network, and transfer learning was performed using ResNet-50. The accuracy was evaluated by calculating the intersection over the union. For tongue coating classification, the rectangular area including the tongue was divided into a grid of 7×7. Five experienced panelists scored the tongue coating in each area using one of five grades, and the tongue coating index (TCI) was calculated. Transfer learning for tongue coating grades was performed using ResNet-18, and the TCI was calculated. Agreement between the panelists and network for the tongue coating grades in each area and TCI was evaluated using the kappa coefficient and intraclass correlation, respectively.
Results: The tongue detection network recognized the tongue with a high intersection over union (0.885±0.081). The tongue coating classification network showed high agreement with tongue coating grades and TCI, with a kappa coefficient of 0.826 and an intraclass correlation coefficient of 0.807, respectively.
Conclusions: Image recognition enables simple and detailed assessment of tongue coating status.
目的:建立一个图像识别网络来评估舌苔状况。方法:建立两个图像识别网络:一个用于舌头检测,另一个用于舌苔分类。这两个网络都使用了数字舌头照片;251名(178名女性,74.7±6.6岁)和144名自愿参与的老年人(83名女性,73.8±7.3岁)的图像分别用于舌头检测网络和涂层分类网络。舌头检测网络的学习目标是提取包括舌头的矩形区域。You Only Look Once(YOLO)v2被用作检测网络,并且使用ResNet-50执行迁移学习。通过计算并集上的交点来评估精度。对于舌苔分类,将包括舌头的矩形区域划分为7×7的网格。五名经验丰富的小组成员使用五个等级中的一个对每个区域的舌苔进行评分,并计算舌苔指数(TCI)。使用ResNet-18进行舌苔等级的迁移学习,并计算TCI。分别使用kappa系数和组内相关性评估了小组成员和网络对每个区域舌苔等级和TCI的一致性。结果:舌苔检测网络识别出具有较高交集的舌(0.885±0.081)。舌苔分类网络与舌苔等级和TCI高度一致,kappa系数分别为0.826和0.807。结论:图像识别能够简单而详细地评估舌苔状况。
期刊介绍:
Journal of Prosthodontic Research is published 4 times annually, in January, April, July, and October, under supervision by the Editorial Board of Japan Prosthodontic Society, which selects all materials submitted for publication.
Journal of Prosthodontic Research originated as an official journal of Japan Prosthodontic Society. It has recently developed a long-range plan to become the most prestigious Asian journal of dental research regarding all aspects of oral and occlusal rehabilitation, fixed/removable prosthodontics, oral implantology and applied oral biology and physiology. The Journal will cover all diagnostic and clinical management aspects necessary to reestablish subjective and objective harmonious oral aesthetics and function.
The most-targeted topics:
1) Clinical Epidemiology and Prosthodontics
2) Fixed/Removable Prosthodontics
3) Oral Implantology
4) Prosthodontics-Related Biosciences (Regenerative Medicine, Bone Biology, Mechanobiology, Microbiology/Immunology)
5) Oral Physiology and Biomechanics (Masticating and Swallowing Function, Parafunction, e.g., bruxism)
6) Orofacial Pain and Temporomandibular Disorders (TMDs)
7) Adhesive Dentistry / Dental Materials / Aesthetic Dentistry
8) Maxillofacial Prosthodontics and Dysphagia Rehabilitation
9) Digital Dentistry
Prosthodontic treatment may become necessary as a result of developmental or acquired disturbances in the orofacial region, of orofacial trauma, or of a variety of dental and oral diseases and orofacial pain conditions.
Reviews, Original articles, technical procedure and case reports can be submitted. Letters to the Editor commenting on papers or any aspect of Journal of Prosthodontic Research are welcomed.
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