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山东大学学报 (医学版) ›› 2024, Vol. 62 ›› Issue (3): 77-86.doi: 10.6040/j.issn.1671-7554.0.2024.0209

• 临床医学 • 上一篇    下一篇

上颌快速扩弓联合前方牵引对替牙期骨性Ⅲ类错牙合畸形的矫治疗效

赵天然1,2,刘东旭1   

  1. 1.山东大学齐鲁医学院口腔医学院·口腔医院正畸科, 山东省口腔组织再生重点实验室, 山东省口腔生物材料与组织再生工程实验室, 山东 济南 250012;2.中国人民解放军联勤保障部队第九六〇医院口腔科, 山东 济南 250031
  • 发布日期:2024-05-06
  • 通讯作者: 刘东旭. E-mail:liudongxu@sdu.edu.com

Orthodontic effects of rapid maxillary expansion combined with maxillary protraction on skeletal Class III malocclusion during the mixed dentition

ZHAO Tianran1,2, LIU Dongxu1   

  1. 1. Department of Orthodontics, School and Hospital of Stomatology, Cheeloo College of Medicine, Shandong University &
    Shandong Key Laboratory of Oral Tissue Regeneration &
    Shandong Engineering Laboratory for Dental Materials and Oral Tissue Regeneration, Jinan 250012, Shandong, China;
    2. Department of Stomatology, The 960th Hospital of the PLA Joint Logistics Support Force, Jinan 250031, Shandong, China
  • Published:2024-05-06

摘要: 目的 通过锥形束断层扫描技术(cone beam computed tomography, CBCT)研究评价上颌快速扩弓联合前方牵引对替牙期骨性Ⅲ类错牙合横向不足的治疗效果。 方法 选择替牙期骨性Ⅲ类错牙合患儿19例,平均(8.47±0.70)岁。分别于上颌快速扩弓联合前方牵引治疗前(T1)及扩弓结束3个月后(T2)拍摄CBCT,测量上颌第一磨牙倾斜度、上颌前磨牙段及第一磨牙牙冠宽度、牙槽突宽度、上颌基骨宽度、牙槽嵴高度、第二前磨牙牙胚在牙槽骨中的位置等,比较治疗前后各测量项目的差异。 结果 从T1到T2阶段,上颌第一前磨牙牙冠宽度增加(2.37±3.47)mm(P=0.008),第二乳磨牙牙冠宽度增加量中位数为3.37 mm(P=0.009),第一磨牙牙冠宽度增加(2.60±2.53)mm(P<0.001),上颌第一前磨牙、第二乳磨牙、第一磨牙对应牙槽突宽度分别增加(1.63±2.45)mm(P=0.010)、(2.12±2.59)mm(P=0.002)、(1.98±2.10)mm(P<0.001),第一磨牙腭根根尖宽度、第一磨牙阻抗中心宽度分别增加(2.00±2.40)mm(P=0.002)、(2.00±2.07)mm(P<0.001),差异具有统计学意义;上颌第一磨牙倾斜度(P=0.196、P=0.251)、上颌基骨宽度(P=0.192)、下颌基骨宽度(P=0.266)及第一磨牙根分叉宽度(P=0.678)、上颌第一前磨牙牙槽骨高度(P=0.136)、第二乳磨牙牙槽骨高度(P=0.638)、第一磨牙牙槽骨高度(P=0.274)、第二前磨牙牙胚在牙槽骨中的相对位置(P=0.058)治疗前后差异均无统计学意义。 结论 上颌快速扩弓联合前方牵引可明显改善替牙期骨性Ⅲ类错牙合患儿中后段牙弓及颌骨横向不调,治疗对前磨牙牙胚在牙槽骨中的相对位置无影响。

关键词: 替牙期, 骨性Ⅲ类错牙合, 上颌扩弓, 基骨宽度, 锥形束计算机断层扫描

Abstract: Objective To evaluate the therapeutic effect of rapid maxillary expansion combined with anterior traction on maxillary transverse deficiency in patients with skeletal Class III malocclusion during the mixed dentition period using cone beam computed tomography(CBCT)technology. Methods A total of 19 mixed dentition patients(average age 8.47±0.70 years old )with skeletal Class Ⅲ malocclusion were selected. CBCT was taken before maxillary protraction combined with rapid maxillary expansion(T1)and 3 months after treatment(T2), respectively, to measure the inclination of the first maxillary molar, the crown width and alveolar width of the first maxillary premolar, the second primary molar and the first molar, the width of the maxillary basal bone, the height of the alveolar crest and the location of the second maxillary premolar germ in the alveolar bone. The differences in various measurement items before and after treatment were compared. Results The crown width of the first maxillary premolar increased by(2.37±3.47)mm(P=0.008), the median increase in crown width of the second primary molar was 3.37mm(P=0.009)and the crown width of the first molar increased by(2.60±2.53)mm(P<0.001)from T1 to T2. The alveolar width of the maxillary first premolar, the second primary molar and the first molar increased by(1.63±2.45)mm(P=0.010),(2.12±2.59)mm(P=0.002)and(1.98±2.10)mm(P<0.001)respectively. The width of the apex of the palatal root and the width of resistance center of the first molar increased by(2.00±2.40)mm(P=0.002)and(2.00±2.07)mm(P<0.001)respectively, with statistically significant differences. There was no statistically significant difference in.the tipping of the first maxillary molar(P=0.196, P=0.251), the width of the maxillary basal bone(P=0.192), the width of the mandibular basal bone(P=0.266)and the width of the center of resistance of the first molar(P=0.678), the height of the alveolar bone of the first maxillary molar(P=0.136), the second primary molar(P=0.638)and the first molar(P=0.274)and the location of the germ of the second premolar in alveolar bone(P=0.058)before and after treatment. Conclusion Rapid maxillary expansion combined with maxillary protraction can significantly improve the transverse deficiency of the middle-posterior arch and maxillary bone in mixed dentition patients with skeletal Class Ⅲ malocclusion. The treatment has no effect on the relative position of the premolar tooth germ in the alveolar bone.

Key words: Mixed dentition, Skeletal Class Ⅲ malocclusion, Rapid maxillary expansion, Basal bone width, Cone beam computed tomography

中图分类号: 

  • R783.5
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