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Journal of Peking University (Health Sciences) ›› 2022, Vol. 54 ›› Issue (1): 134-139. doi: 10.19723/j.issn.1671-167X.2022.01.021

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Deep learning-assisted construction of three-demensional facial midsagittal plane

ZHU Yu-jia1,2,XU Qing3,ZHAO Yi-jiao1,2,ZHANG Lei1,2,FU Zi-wang3,WEN Ao-nan1,2,GAO Zi-xiang1,2,ZHANG Jun4,FU Xiang-ling3,(),WANG Yong1,2,()   

  1. 1. Center of Digital Dentistry, Peking University School and Hospital of Stomatology & National Center of Stomatology & National Clinical Research Center for Oral Diseases & National Engineering Laboratory for Digital and Material Technology of Stomatology & Beijing Key Laboratory of Digital Stomatology & NHC Research Center of Engineering and Technology for Computerized Dentistry & NMPA Key Laboratory for Dental Materials, Beijing 100081, China
    2. Department of Prosthodontics, Peking University School and Hospital of Stomatology, Beijing 100081, China
    3. School of Computer Science, Beijing University of Posts and Telecommunications(National Pilot Software Engineering School), Beijing 100876, China
    4. Department of Geriatric Dentistry, Lanzhou Stomatological Hospital, Lanzhou 730000, China
  • Received:2021-10-10 Online:2022-02-18 Published:2022-02-21
  • Contact: Xiang-ling FU,Yong WANG E-mail:fuxiangling@bupt.edu.cn;kqcadc@bjmu.edu.cn
  • Supported by:
    National Natural Science Foundation of China(81870815);National Natural Science Foundation of China(82071171);National Key Research and Development Program of Gansu Province(21YF5FA165)

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Abstract:

Objective: To establish a deep learning algorithm that can accurately determine three-dimensional facial anatomical landmarks, multi-view stacked hourglass convolutional neural networks (MSH-CNN) and to construct three-dimensional facial midsagittal plane automatically based on MSH-CNN and weighted Procrustes analysis algorithm. Methods: One hundred subjects with no obvious facial deformity were collected in our oral clinic. Three-dimensional facial data were scanned by three-dimensional facial scanner. Experts annotated twenty-one facial landmarks and midsagittal plane of each data. Eighty three-dimensional facial data were used as training set, to train the MSH-CNN in this study. The overview of MSH-CNN network architecture contained multi-view rendering and training the MSH-CNN network. The three-dimensional facial data were rendered from ninety-six views that were fed to MSH-CNN and the output was one heatmap per landmark. The result of the twenty-one landmarks was accurately placed on the three-dimensional facial data after a three-dimensional view ray voting process. The remaining twenty three-dimensional facial data were used as test set. The trained MSH-CNN automatically determined twenty-one three-dimensional facial anatomical landmarks of each case of data, and calculated the distance between each MSH-CNN landmark and the expert landmark, which was defined as position error. The midsagittal plane of the twenty subjects’ could be automatically constructed, using the MSH-CNN and Procrustes analysis algorithm. To evaluate the effect of midsagittal plane by automatic method, the angle between the midsagittal plane constructed by the automatic method and the expert annotated plane was calculated, which was defined as angle error. Results: For twenty subjects with no obvious facial deformity, the average angle error of the midsagittal plane constructed by MSH-CNN and weighted Procrustes analysis algorithm was 0.73°±0.50°, in which the average position error of the twenty-one facial landmarks automatically determined by MSH-CNN was (1.13±0.24) mm, the maximum position error of the orbital area was (1.31±0.54) mm, and the minimum position error of the nasal area was (0.79±0.36) mm. Conclusion: This research combines deep learning algorithms and Procrustes analysis algorithms to realize the fully automated construction of the three-dimensional midsagittal plane, which initially achieves the construction effect of clinical experts. The obtained results constituted the basis for the independent intellectual property software development.

Key words: Midsagittal plane, Deep learning, Procrustes analysis

CLC Number: 

  • R783.2

Figure 1

Anatomic landmarks of three-dimensional facial data Ex, exocanthion; Ala, alare; Sal, subalare; Cph, crista philtre; Ch, cheilion; Gn, gnathion; Su, superciliary ridge; Pu, pupil; En, endocanthion; Prn, pronasale; Sn, subnasale; Ls, labiale superius; Li, labiale inferius."

Figure 2

Multi-view stacked hourglass convolutional neural networks MSH-CNN, multi-view stacked hourglass convolutional neural networks; 3D, three-dementional."

Figure 3

Twenty-one three-dimensional facial anatomical landmarks automatically determined by multi-view stacked hourglass convolutional neural networks A, right lateral view; B, front view; C, left lateral view."

Figure 4

Determining the midsagittal plane based on the multi-view stacked hourglass convolutional neural networks The red plane signifies the ground truth plane, the green plane constructed by the multi-view stacked hourglass convolutional neural networks algorithm."

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