Journal of Peking University(Health Sciences) ›› 2017, Vol. 49 ›› Issue (1): 176-180. doi: 10.3969/j.issn.1671-167X.2017.01.032

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A new method to orthodontically correct dental occlusal plane canting: waveshaped arch

ZHENG Xu1△, HU Xing-Xue2,3, MA Ning1, CHEN Xiao-Hong1   

  1. (1.Department of Stomatology, Peking University Third Hospital, Beijing 100191,China; 2. The Forsyth Institute, Harvard Medical School, Cambridge, Massachusetts 02142, USA; 3. Division of General Practice and Materials Science, The Ohio State University College of Dentistry, Columbus, Ohio 43210, USA)
  • Online:2017-02-18 Published:2017-02-18
  • Contact: ZHENG Xu E-mail:zhengxu_allen@sina.com
  • Supported by:

    Supported by the Peking University Third Hospital Initial Scientific Research Fund for Returned Oversea Scholars(Y73512-01)

Abstract:

Objective: To introduce a technique of second order wave-shaped arch wire to orthodontically treat dental occlusal plane canting (DOPC) with left-right interactive anchorage, and to test its cli-nical efficacy. Methods: Among the permanent dentition malocclusion patients who showed no obvious facial asymmetry, we screened for patients who showed anterior occlusal plane canting (AOPC) after routine orthodontic examination, treatment planning, MBT fixed appliance installation and serial arch wires alignment. Each patient had been clinically appraised in frontal view by 2 orthodontists and the patient him/herself; if all 3 agreed that the AOPC was obvious, the patient was included. By this means, we included 37 patients, including 10 males and 27 females; the average age was (21.9±5.2) years. To correct AOPC, opposite direction equal curvature second order rocking-chair curve was bent on each side of 0.46 mm×0.56 mm stainless steel edgewise wire. With reference to normal occlusal plane, a curve toward the occlusal surface was made to extrude undererupted teeth on one side while a curve toward the gingiva was made to intrude over-erupted teeth on the other side, so that the arch wire was made into a wave shape in vertical dimension. Before and after application of wave-shaped arch wire, frontal facial photographs were taken when the patient’s mouth was open slightly with lips retracted to show anterior occlusal plane (AOP) clearly. An AOP was constructed by connecting the center of the slot in the medial edge of canine bracket on each side in the photograph. The angles between the bipupillary plane(BPP) and the constructed AOP were measured in ImageJ1-48v software and the angle differences before and after treatment were compared with paired Wilcoxon test in SPSS 10.0 software. Results: The wave-shaped arch could correct AOPC effectively in 3 to 10 months time with an average of 5.5±1.7 months; the angles between AOP and BBP before treatment ranged from 2.90° to 6.12° with a median of 4.01°; after treatment the angles were from -0.17° to 2.57° with a median of 1.87°, the decrease of the angles between AOP and BBP after treatment ranged from 1.08° to 4.15° with a median of 2.21°. Paired Wilcoxon test P was 0.000. Conclusion: The wave-shaped arch can be used independently or in combination with other treatment methods, which can take advantage of left and right interactive anchorage to correct AOPC effectively, so it has certain application value in clinical practice.

Key words: Malocclusion, Anterior occlusal plane, Orthodontic anchorage procedures

CLC Number: 

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