Finite Element Analysis of Composite Resin Restoration in Injured Maxillary Central Incisors

doi:10.13701/j.cnki.kqyxyj.2025.06.008

Abstract

Abstract: Objective: To analyze the force distribution in the repair of maxillary central incisor trauma during the replacement stage using composite resin materials under different occlusal modes. Methods: The maxillary central incisors in the young permanent teeth with normal shape and size were selected, and three-dimensional finite element model of the maxillary central incisors was established by reverse engineering technology with the crown was cut and designed. According to different occlusal methods, it is divided into three groups of working conditions, working condition one: 0-degree to the long axis of the tooth; working condition 2: 45-degree to the long axis of the tooth; working condition 3: 60-degree to the long axis of the tooth. According to the different types of crown folds, each group contained 5 groups, i.e. group A: normal crowns; Group B: crown folded 2 mm; Group C: crown transverse fold 4 mm; Group D: crown obliquely folded 2 mm; Group E: crown obliquely folded 4 mm. Using the three-dimensional finite element method, the maximum stress and strain values of the tooth tissue after resin restoration of the central incisor with different crown and fold types were calculated under different occlusal modes. Results: When the traumatic tooth was loaded with a force at 0-degree, the maximum stress peak value of the transverse 4 mm group was 39.755 MPa, and the maximum strain peak value of the transverse 2 mm group was 0.0013441 mm. When the injured tooth was loaded with a force at 45-degree, the stress-strain peak value of the oblique fold 2 mm group was the largest with the stress peak at 426.10 MPa and the strain peak at 0.0099519 mm. When the wounded tooth was loaded with a force at 60-degree, the stress-strain peak value of the oblique fold 2 mm group was the largest with the stress peak value at 531.88 MPa and the strain peak value at 0.0124230 mm. Conclusion: The transverse fracture group had the highest loss rate when the traumatic teeth were subjected to a 0-degree occlusal force after composite resin restoration of the traumatic crown of the upper anterior teeth of young permanent teeth. When the injured tooth was subjected to a bite force of 45-degree and 60-degree, the loss rate was the highest in the oblique 2 mm group.

Key words: young permanent teeth, anterior tooth trauma, crown fracture, resin restoration, finite element, stress analysis

SHAO Tianyang, YU Miao, JI Yan, LI Xinhua, ZHAO Yue. Finite Element Analysis of Composite Resin Restoration in Injured Maxillary Central Incisors[J]. Journal of Oral Science Research, 2025, 41(6): 496-502.

References

[1] Davide A, Raffaella A, Marco T, et al. Direct restoration modalities of fractured central maxillary incisors: A multi-levels validated finite elements analysis with in vivo strain measurements [J]. Dent Mater, 2015, 31(12): e289-e305.
[2] Dezzen-Gomide AC, de Carvalho MA, Lazari-Carvalho PC, et al. A three-dimensional finite element analysis of permanent maxillary central incisors in different stages of root development and trauma settings [J]. Comput Methods Programs Biomed, 2021, 207: 106195.
[3] 周哲,于婉琦,杨诗卉,等.人天然牙的力学性能及其影响因素研究进展[J].实用口腔医学杂志, 2022, 38(2): 259-262.
[4] 陈誉,卢友光.上前牙外伤的临床治疗[D].福建医科大学,2020.
[5] 朱赛玲,王利民,王卫国.上颌中切牙切角缺损修复中牙本质纤维桩形态对树脂修复应力的影响[J].中国现代医生,2017,55(21): 10-13+169.
[6] Atif M, Tewari N, Reshikesh M, et al. Methods and applications of finite element analysis in dental trauma research: A scoping review [J]. Dent Traumatol, 2024, 40(4): 366-388.
[7] 董凯杰,程涛.上中切牙颈1/3唇舌侧斜折保存部分断冠的桩核冠有限元分析[D].郑州大学,2021.
[8] Rodríguez-Cervantes PJ, Sancho-Bru JL, González-Lluch C, et al. Premolars restored with posts of different materials: fatigue analysis [J]. Dent Mater J, 2011, 30(6): 881-886.
[9] 张大鹏,吴国锋.人上颌中切牙牙冠与牙周膜三维形态结构的初步研究[D].第四军医大学, 2016.
[10] Bucchi C, Marcé-Nogué J, Galler KM, et al. Biomechanical performance of an immature maxillary central incisor after revitalization: a finite element analysis [J]. Int Endod J, 2019, 52(10): 1508-1518.
[11] Gomes éA, Gueleri DB, da Silva SR, et al. Three-dimensional finite element analysis of endodontically treated teeth with weakened radicular walls restored with different protocols [J]. J Prosthet Dent, 2015, 114(3): 383-389.
[12] 樊明文.主编.牙体牙髓病学[M].人民卫生出版社,2012.
[13] 姜晓南,赵阿莉,王利民,等.上颌中切牙年轻恒牙期外伤撞击的应力分析[J].中国现代医生, 2019, 57(16): 77-80+84+169.
[14] 杜军,邱延菊,万哲.植入位点及轴向对上颌中切牙即刻种植即刻负重后微动度影响的三维有限元分析[J].口腔医学研究,2022,38(9): 831-836.
[15] 张红,丛茜.根管治疗后的牙齿仿生修复设计与试验研究[D].吉林大学, 2019.
[16] 钟慧,吴补领,高杰,等.前牙切1/3冠横折和断冠再接术三维有限元模型的建立[J].牙体牙髓牙周病学,2012,22(5):266-270.
[17] 高健,刘大勇.不同固位形和树脂对前牙断冠再接应力影响的有限元分析[J].中国组织工程研究,2023,27(25): 4063-4068.
[18] Vukicevic AM, Zelic K, Jovicic G, et al. Influence of dental restorations and mastication loadings on dentine fatigue behaviour: Image-based modelling approach [J]. J Dent, 2015, 43(5): 556-567.
[19] Iliescu AA, Petcu CM, Nitoi D, et al. Chewing stress developed in upper anterior teeth with root end resection. a finite element analysis study [J]. Chirurgia (Bucur), 2013, 108(3): 389-395.
[20] Vilela ABF, Soares PBF, Versluis A, et al. Dental trauma splints for the mixed dentition-A finite element analysis of splint material, splint extension, missing teeth, and PDL representation [J]. Dent Traumatol, 2022, 38(6):495-504.
[21] 胡德渝.主编.口腔预防医学[M]. 人民卫生出版社,1987.
[22] Hasna AA, Pinto ABA, Coelho MS, et al. Fracture resistance and biomechanical behavior of different access cavities of maxillary central incisors restored with different composite resins [J]. Clin Oral Invest, 2022, 26(10): 6295-6303.
[23] da Silva BR, Moreira Neto JJ, da Silva FI Jr, et al. Three-dimensional finite element analysis of the maxillary central incisor in two different situations of traumatic impact [J]. Comput Methods Biomech Biomed Engin, 2013, 16(2): 158-164.
[24] Benazzi S, Nguyen HN, Kullmer O, et al. Unravelling the functional biomechanics of dental features and tooth wear [J]. PLoS One, 2013, 8(7): e69990.