数字化流程制作的上颌骨性扩弓器对上颌横向发育不足患者软硬组织的影响

doi:10.13591/j.cnki.kqyx.2025.08.005

摘要/Abstract

摘要：

目的探讨上颌横向发育不足患者经数字化流程制作的上颌骨性扩弓器治疗前后其软硬组织的三维变化。方法选择于南京医科大学附属口腔医院正畸科就诊并经数字化流程制作上颌骨性扩弓器治疗上颌横向发育不足青春期后期或成年患者20例,拍摄治疗前后的锥形束CT,应用Dolphin 11.95软件进行三维测量分析,采用SPSS软件进行统计学分析,采用自身对照配对t检验对上颌横向发育不足患者治疗前后的软硬组织变化进行比较。结果前部腭中缝宽度、后部腭中缝宽度、上颌根尖基骨宽度、上颌牙槽宽度均显著增大(P<0.001),牙槽嵴倾斜角度、牙槽嵴高度、∠SNA无明显变化(P>0.05);根尖距离、釉牙骨质交界处距离、窝间距离显著增加(P<0.001),第一磨牙倾斜度、∠U1-SN基本不变(P>0.05);上气道体积、鼻底基骨宽度、鼻腔宽度均显著增加(P<0.001)。结论对于青春期后期或成年的上颌横向发育不足患者,数字化流程制作的上颌骨性扩弓器可近乎平行地扩开腭中缝,从而改善上颌骨横向宽度,改善气道通气量,且牙性副作用较小。

关键词: 上颌骨性扩弓器, 数字化流程, 上颌横向发育不足

Abstract:

Objective To investigate the three-dimensional changes in hard and soft tissues before and after treatment with digitally fabricated maxillary skeletal expanders in patients with maxillary transverse deficiency. Methods Twenty late adolescents or adults with maxillary transverse deficiency treated at the Orthodontic Department of Affiliated Stomatological Hospital of Nanjing Medical University using digitally fabricated maxillary skeletal expanders were included. Cone-beam computed tomography(CBCT) scans were obtained before and after treatment. Three-dimensional measurements were analyzed using Dolphin 3D 11.95 software, and statistical analysis was performed with SPSS software. Paired t-tests were used to compare pre-treatment and post-treatment changes in hard and soft tissues. Results Significant increases were observed in anterior midpalatal suture width, posterior midpalatal suture width, maxillary apical base width, and maxillary alveolar width(P<0.001). No significant changes were found in alveolar ridge inclination, alveolar ridge height, ∠SNA(P>0.05). Significant increases occurred in apical distance, cementoenamel junction distance, and inter-fossa distance(P<0.001), while first molar inclinationand ∠U1-SN remained stable(P>0.05). Significant improvements were noted in upper airway volume, nasal floor base width, and nasal cavity width(P<0.001). Conclusion For late adolescents or adults with maxillary transverse deficiency, digitally fabricated maxillary skeletal expanders can achieve near-parallel expansion of the midpalatal suture, effectively improving maxillary transverse dimensions and airway volume while minimizing dental side effects.

Key words: maxillary skeletal expander, digital workflow, maxillary transverse deficiency

中图分类号:

R783.5

郝舒姝, 娄姝, 杨齐飞, 蔡旻纯, 胡敏, 王震东. 数字化流程制作的上颌骨性扩弓器对上颌横向发育不足患者软硬组织的影响[J]. 口腔医学, 2025, 45(8): 590-595.

HAO Shushu, LOU Shu, YANG Qifei, CAI Minchun, HU Min, WANG Zhendong. Effects of digitally processed maxillary skeletal expanders on hard and soft tissues in patients with maxillary transverse deficiency[J]. Stomatology, 2025, 45(8): 590-595.

图/表 6

图1

图2

表1

表2

表3

表4

参考文献 26

[1]	Baccetti T, Franchi L, Cameron CG, et al. Treatment timing for rapid maxillary expansion[J]. Angle Orthod, 2001, 71(5): 343-350. doi: 10.1043/0003-3219(2001)071<0343:TTFRME>2.0.CO;2 pmid: 11605867
[2]	de Oliveira CB, Ayub P, Ledra IM, et al. Microimplant assisted rapid palatal expansion vs. surgically assisted rapid palatal expansion for maxillary transverse discrepancy treatment[J]. Am J Orthod Dentofacial Orthop, 2021, 159(6): 733-742.
[3]	Chamberland S. Maxillary expansion in nongrowing patients. Conventional, surgical, or miniscrew-assisted, an update[J]. J World Fed Orthod, 2023, 12(4): 173-183.
[4]	Rutili V, Nieri M, Franceschi D, et al. Comparison of rapid versus slow maxillary expansion on patient-reported outcome measures in growing patients: A systematic review and meta-analysis[J]. Prog Orthod, 2022, 23(1): 47. doi: 10.1186/s40510-022-00440-5 pmid: 36503984
[5]	Angelieri F, Cevidanes LHS, Franchi L, et al. Midpalatal suture maturation: Classification method for individual assessment before rapid maxillary expansion[J]. Am J Orthod Dentofac Orthop, 2013, 144(5): 759-769.
[6]	Carvalho PA, Moura LB, Trento GS, et al. Surgically assisted rapid maxillary expansion: A systematic review of complications[J]. Int J Oral Maxillofac Surg, 2020, 49(3): 325-332.
[7]	Chun JH, Oh S, et al. Skeletal and alveolar changes in conventional rapid palatal expansion(RPE)and miniscrew-assisted RPE(MARPE): A prospective randomized clinical trial using low-dose CBCT[J]. BMC Oral Health, 2022, 22(1): 114.
[8]	Akyalcin S, Alev Y. Clinical advances in maxillary skeletal expansion and introduction of a new MARPE concept[J]. J Esthet Restor Dent, 2023, 35(1): 291-298.
[9]	Jia HC, Zhuang L, Zhang N, et al. Comparison of skeletal maxillary transverse deficiency treated by microimplant-assisted rapid palatal expansion and tooth-borne expansion during the post-pubertal growth spurt stage[J]. Angle Orthod, 2021, 91(1): 36-45. doi: 10.2319/041920-332.1 pmid: 33289835
[10]	Li N, Sun WQ, Li QM, et al. Skeletal effects of monocortical and bicortical mini-implant anchorage on maxillary expansion using cone-beam computed tomography in young adults[J]. Am J Orthod Dentofacial Orthop, 2020, 157(5): 651-661.
[11]	Shih SN, Ho KH, Wang CW, et al. Management of Class Ⅲ malocclusion and maxillary transverse deficiency with microimplant-assisted rapid palatal expansion(MARPE): A case report[J]. Medicina(Kaunas), 2022, 58(8): 1052.
[12]	Rezallah NNF, Luke AM. Evaluating micro-computed tomography in dental implant osseointegration: A systematic review and meta-analysis[J]. Acad Radiol, 2025, 32(2): 1086-1099.
[13]	Choi IGG, Pinhata-Baptista OH, Ferraço R, et al. Correlation among alveolar bone assessments provided by CBCT, micro-CT, and 14 T MRI[J]. Dentomaxillofac Radiol, 2022, 51(5): 20210243.
[14]	Cantarella D, Dominguez-Mompell R, Moschik C, et al. Zygomaticomaxillary modifications in the horizontal plane induced by micro-implant-supported skeletal expander, analyzed with CBCT images[J]. Prog Orthod, 2018, 19(1): 41. doi: 10.1186/s40510-018-0240-2 pmid: 30345476
[15]	Hsu LF, Moon W, Chen SC, et al. Digital workflow for mini-implant-assisted rapid palatal expander fabrication-A case report[J]. BMC Oral Health, 2023, 23(1): 887.
[16]	Cantarella D, Savio G, Grigolato L, et al. A new methodology for the digital planning of micro-implant-supported maxillary skeletal expansion[J]. Med Devices(Auckl), 2020, 13: 93-106.
[17]	Cantarella D, Dominguez-Mompell R, Mallya SM, et al. Changes in the midpalatal and pterygopalatine sutures induced by micro-implant-supported skeletal expander, analyzed with a novel 3D method based on CBCT imaging[J]. Prog Orthod, 2017, 18(1): 34. doi: 10.1186/s40510-017-0188-7 pmid: 29090368
[18]	Wang CL, Xiang XS, Mao Q, et al. CAD/CAM design and 3D printing of a personalised rapid palatal expander for maxillary transverse deficiency[J]. J Pak Med Assoc, 2024, 74(1): 153-157. doi: 10.47391/JPMA.8363 pmid: 38219189
[19]	Nucera R, Costa S, Bellocchio AM, et al. Evaluation of palatal bone depth, cortical bone, and mucosa thickness for optimal orthodontic miniscrew placement performed according to the third palatal rugaclinical reference[J]. Eur J Orthod, 2022, 44(5): 530-536.
[20]	Vale F, Travassos R, Couto I, et al. Patient’s perspective on miniscrews during orthodontic treatment-a systematic review with meta-analysis[J]. Orthod Craniofac Res, 2025, 28(2): 217-241.
[21]	Giudice AL, Rustico L, Longo M, et al. Complications reported with the use of orthodontic miniscrews: A systematic review[J]. Korean J Orthod, 2021, 51(3): 199-216. doi: 10.4041/kjod.2021.51.3.199 pmid: 33984227
[22]	Motoyoshi M, Sanuki-Suzuki R, Uchida Y, et al. Maxillary sinus perforation by orthodontic anchor screws[J]. J Oral Sci, 2015, 57(2): 95-100. doi: 10.2334/josnusd.57.95 pmid: 26062857
[23]	Garib DG, Henriques JFC, Janson G, et al. Periodontal effects of rapid maxillary expansion with tooth-tissue-borne and tooth-borne expanders: A computed tomography evaluation[J]. Am J Orthod Dentofacial Orthop, 2006, 129(6): 749-758.
[24]	Lin L, Ahn HW, Kim SJ, et al. Tooth-borne vs bone-borne rapid maxillary expanders in late adolescence[J]. Angle Orthod, 2015, 85(2): 253-262. doi: 10.2319/030514-156.1 pmid: 25490552
[25]	Combs A, Paredes N, Dominguez-Mompell R, et al. Long-term effects of maxillary skeletal expander treatment on functional breathing[J]. Korean J Orthod, 2024, 54(1): 59-68. doi: 10.4041/kjod23.090 pmid: 38268461
[26]	Kabalan O, Gordon J, Heo G, et al. Nasal airway changes in bone-borne and tooth-borne rapid maxillary expansion treatments[J]. Int Orthod, 2015, 13(1): 1-15.

测量项目	定义
前部腭中缝宽度(ASW)	腭平面上两侧前鼻嵴之间的宽度
后部腭中缝宽度(PSW)	腭平面上两侧上颌第一磨牙腭侧根尖间腭中缝的宽度
上气道体积(UAV)	气管隆嵴以上至声门的气道部分的三维空间中所占据的空间大小
鼻腔宽度(NW)	冠状面上鼻腔最宽处的水平距离
鼻底基骨宽度(BWNF)	冠状面上鼻底平面与上颌窦内侧壁交点之间的距离
上颌根尖基骨宽度(MBBW)	冠状面上两侧接近根尖的颊侧基骨最凹点之间的水平距离
上颌牙槽宽度(MABW)	冠状面上两侧牙槽嵴颊侧最凸点之间的距离
牙槽嵴倾斜角度(AI)	冠状面上,上颌左右第一磨牙中央沟之间的距离
牙槽嵴高度(ABH)	上颌第一磨牙近中颊根的冠状面上,颊侧牙槽嵴顶到釉牙骨质界的距离
SNA	蝶鞍中心-鼻根点-上牙槽座点连线所构成角
U1-SN	上颌中切牙长轴与SN平面之间的夹角
根尖距离(IAW)	第一磨牙腭根尖之间的距离
釉牙骨质交界处距离(ICW)	第一磨牙的腭釉牙骨质交界之间的距离
窝间距离(IFW)	第一磨牙中央窝之间的距离
第一磨牙倾斜度(MFMT)	在显示上颌第一磨牙腭侧根的冠状面上,上颌第一磨牙腭根根管口中点与腭根尖连线和鼻底平面所成夹角角度

测量项目	治疗前(T1)	治疗后(T2)	T2-T1	P
ASW/mm	0.00±0.00	2.05±0.55	2.05±0.55	<0.001
PSW/mm	0.00±0.00	2.05±0.54	2.05±0.54	<0.001
MBBW/mm	62.66±4.12	65.42±4.52	2.77±1.39	<0.001
MABW/mm	61.20±5.04	63.65±5.05	2.45±1.38	<0.001
AI-L/(°)	105.19±4.61	105.26±4.52	0.07±0.10	0.170
AI-R/(°)	103.21±2.42	103.30±2.21	0.10±0.20	0.320
ABH-L/mm	2.70±0.60	2.80±0.43	0.12±0.05	0.306
ABH-R/mm	2.60±0.41	2.70±0.32	0.10±0.01	0.079
SNA/(°)	80.60±2.02	80.60±1.92	0.00±0.01	0.056

测量项目	治疗前(T1)	治疗后(T2)	T2-T1	P
U1-SN/(°)	105.55±5.73	106.55±3.95	1.00±0.49	0.165
IAW/mm	35.85±2.55	37.90±4.14	2.05±0.35	<0.001
ICW/mm	34.35±3.21	38.35±3.25	3.99±1.63	<0.001
IPW/mm	46.25±1.15	50.15±3.15	3.90±0.93	<0.001
MFMT-L/(°)	96.65±6.43	96.74±6.51	0.09±0.34	0.084
MFMT-R/(°)	95.30±7.41	95.30±5.43	0.01±1.21	0.074

测量项目	治疗前(T1)	治疗后(T2)	T2-T1	P
UAV/mm²	119.40±35.62	141.25±48.75	21.85±12.75	<0.001
NW/mm	33.60±1.74	36.50±1.10	2.90±0.85	<0.001
BWNF/mm	31.52±2.25	33.97±2.00	2.46±0.91	<0.001