Three-dimensional finite element analysis on fiber-reinforced composite post-restored maxillary first molar with tooth defect

doi:10.3969/j.issn.1674-8115.2022.08.013

Abstract

Abstract:

Objective ·To explore the appropriate strategy for restoring maxillary first molars with palatal-occlusal (PO) defect or distal-occlusal (DO) defect by using fiber-reinforced composite posts. Methods ·Two types of defects in maxillary first molars were established: PO defect and DO defect. For each type, 5 finite element models with different restoration strategies were created: no post (NP), palatal post (PP), palatal and distobuccal posts (PDP), palatal and mesiobuccal posts (PMP), and palatal, distobuccal and mesiobuccal posts (PDMP). In the multi-post groups, if 2 posts overlapped in the resin core, the thinner one was horizontally trimmed 1 mm below the intersection point. The models were loaded by a vertical force—an 800 N force parallel to the long axis of the tooth, and a lateral force—a 225 N force directed at 45° to the long axis of the tooth. The following parameters were calculated by using finite element analysis: equivalent stress in the tooth structure and the posts, and maximum shear stress on the post-cement and cement-canal interfaces. Results ·Under the vertical loading, the maximal equivalent stress on the external surfaces of the tooth with PO defect was the lowest in the PMP group (36.17 MPa), while it was the lowest in the PDP group with DO defect (36.23 MPa). Under the lateral loading, it was the lowest in the PDMP group with PO defect (40.47 MPa), while it was the lowest in the PMP group with DO defect (42.05 MPa). With either defect, the equivalent stress on the internal surfaces generally decreased at the cervical 1/3 of root canals and increased at the middle 1/3 after post inserting. Palatal canal post and mesiobuccal canal post respectively withstood the highest equivalent stress under vertical loading and lateral loading (60.75?71.29 MPa and 45.91?51.82 MPa, respectively), and the maximal shear stresses on these two post-cement interfaces were also the highest under the corresponding loading (11.26?12.93 MPa and 12.38?13.03 MPa, respectively). The maximum shear stresses on the cement-canal interfaces were similar among the groups under the vertical loading (9.96?10.58 MPa), while under the lateral loading they were higher in the PMP group and the PDMP group. Conclusion ·The appropriate strategy for fiber-reinforced composite post restoration on maxillary first molars should be determined according to the type of tooth defect. For PO defect, the strategy of one post restoring in palatal canal is recommended; for DO defect, the strategy of two posts restoring in palatal and mesiobuccal canals respectively with approaches to reduce vertical occlusal force is recommended.

Key words: molar, fiber-reinforced composite post, post and core technique, finite element analysis, stress

CLC Number:

R783.3

ZHONG Qi, HUANG Yujie, ZHANG Yifan, SONG Yingshuang, WU Yaqin, QU Fang, HUANG Qingfeng, XU Chun. Three-dimensional finite element analysis on fiber-reinforced composite post-restored maxillary first molar with tooth defect[J]. Journal of Shanghai Jiao Tong University (Medical Science), 2022, 42(8): 1081-1094.

Figures/Tables 12

TrendMD

References 33

1	YAMUNADEVI A, PRATIBHA R, RAJMOHAN M, et al. First molars in permanent dentition and their malformations in various pathologies: a review[J]. J Pharm Bioallied Sci, 2021, 13(Suppl 1): S23-S30.
2	何三纲. 口腔解剖生理学[M]. 8版. 北京: 人民卫生出版社, 2020.
	HE S G. Oral anatomy and physiology[M]. 8th ed. Beijing: People's Medical Publishing House, 2020.
3	王兴. 第四次全国口腔健康流行病学调查报告[M]. 北京: 人民卫生出版社, 2018.
	WANG X. Report of the fourth national oral health epidemiological survey[M]. Beijing: People's Medical Publishing House, 2018.
4	张文玲, 黄永丽, 赵勇. 牙齿折裂的相关因素分析和治疗[J]. 河南大学学报(医学版), 2015, 34(2): 123-125.
	ZHANG W L, HUANG Y L, ZHAO Y. Analysis factors and treatment associated with fractured teeth[J]. J Henan Univ (Med Sci), 2015, 34(2): 123-125.
5	胡坤娥, 胡冬梅, 谭荣, 等. 影响后牙折裂的相关因素分析[J]. 中国美容医学, 2012, 21(17): 2235-2237.
	HU K E, HU D M, TAN R, et al. Analysis of factors associated with posterior fractured teeth[J]. Chin J Aesthetic Med, 2012, 21(17): 2235-2237.
6	ELIYAS S, JALILI J, MARTIN N. Restoration of the root canal treated tooth[J]. Br Dent J, 2015, 218(2): 53-62.
7	牛光良. 纤维桩理论与实践[M]. 北京: 人民卫生出版社, 2013.
	NIU G L. Fiber post: current principles and practice[M]. Beijing: People's Medical Publishing House, 2020.
8	乔玮. 桩核材料的临床应用与发展[J]. 包头医学院学报, 2011, 27(1): 136-138.
	QIAO W. Clinical application and development of post-core materials[J]. J Baotou Med Coll, 2011, 27(1): 136-138.
9	杜珍, 汲平. 纤维桩的分类及性能特点[J]. 口腔颌面修复学杂志, 2007, 8(3): 227-228, 232.
	DU Z, JI P. Classification and properties of fiber posts[J]. Chin J Prosthodont, 2007, 8(3): 227-228, 232.
10	MARCHIONATTI A M E, WANDSCHER V F, RIPPE M P, et al. Clinical performance and failure modes of pulpless teeth restored with posts: a systematic review[J]. Braz Oral Res, 2017, 31: e64.
11	YANG A, LAMICHHANE A, XU C. Remaining coronal dentin and risk of fiber-reinforced composite post-core restoration failure: a meta-analysis[J]. Int J Prosthodont, 2015, 28(3): 258-264.
12	HARGREAVES K M, BERMAN L H. Cohen's pathways of the pulp expert consult[M]. 11th ed. St. Louis: Elsevier, 2015.
13	SCHWARTZ R S, ROBBINS J W. Post placement and restoration of endodontically treated teeth: a literature review[J]. J Endod, 2004, 30(5): 289-301.
14	YOON H G, OH H K, LEE D Y, et al. 3-D finite element analysis of the effects of post location and loading location on stress distribution in root canals of the mandibular 1st molar[J]. J Appl Oral Sci, 2018, 26: e20160406.
15	赵莉, 李丽君, 赵克, 等. 不同桩核系统修复上颌第一磨牙的有限元分析[J]. 上海口腔医学, 2013, 22(6): 607-612.
	ZHAO L, LI L J, ZHAO K, et al. Finite element analysis of first maxillary molars restored with different post and core materials[J]. Shanghai J Stomatol, 2013, 22(6): 607-612.
16	刘峰. 纤维桩修复技术[M]. 北京: 人民卫生出版社, 2012.
	LIU F. Fiber post restoration[M]. Beijing: People's Medical Publishing House, 2012.
17	ZHONG Q, HUANG Y, ZHANG Y, et al. Finite element analysis of maxillary first molar with a 4-wall defect and 1.5-mm-high ferrule restored with fiber-reinforced composite resin posts and resin core: the number and placement of the posts[J]. J Prosthet Dent, 2022. DOI: 10.1016/j.prosdent.2022.01.029.
18	王春艳. 龋病发生部位与年龄关系[J]. 内蒙古中医药, 2013, 32(25): 41.
	WANG C Y. The relationship between caries location and age[J]. Inner Mong J Tradit Chin Med, 2013, 32(25): 41.
19	刘凡. 纤维桩性价比之王: Matchpost[Z/OL]. (2018-12-18) [2020-01-28]. https://mp.weixin.qq.com/s/-eEbnPK3BbRby0JtpOxuIw.
	LIU F. The king of cost performance in fiber posts: Matchpost[Z/OL]. (2018-12-18) [2020-01-28]. https://mp.weixin.qq.com/s/-eEbn PK3BbRby0JtpOxuIw.
20	LI X X, KANG T, ZHAN D T, et al. Biomechanical behavior of endocrowns vs fiber post-core-crown vs cast post-core-crown for the restoration of maxillary central incisors with 1 mm and 2 mm ferrule height: a 3D static linear finite element analysis[J]. Medicine, 2020, 99(43): e22648.
21	GONZÁLEZ-LLUCH C, PÉREZ-GONZÁLEZ A. Analysis of the effect of design parameters and their interactions on the strength of dental restorations with endodontic posts, using finite element models and statistical analysis[J]. Comput Methods Biomech Biomed Engin, 2016, 19(4): 428-439.
22	SAVYCHUK A, MANDA M, GALANIS C, et al. Stress generation in mandibular anterior teeth restored with different types of post-and-core at various levels of ferrule[J]. J Prosthet Dent, 2018, 119(6): 965-974.
23	MAHMOUDI M, SAIDI A R, AMINI P, et al. Influence of inhomogeneous dental posts on stress distribution in tooth root and interfaces: three-dimensional finite element analysis[J]. J Prosthet Dent, 2017, 118(6): 742-751.
24	DURMUŞ G, OYAR P. Effects of post core materials on stress distribution in the restoration of mandibular second premolars: a finite element analysis[J]. J Prosthet Dent, 2014, 112(3): 547-554.
25	AUSIELLO P, CIARAMELLA S, MARTORELLI M, et al. Mechanical behavior of endodontically restored canine teeth: effects of ferrule, post material and shape[J]. Dent Mater, 2017, 33(12): 1466-1472.
26	JIANG Q Z, HUANG Y T, TU X R, et al. Biomechanical properties of first maxillary molars with different endodontic cavities: a finite element analysis[J]. J Endod, 2018, 44(8): 1283-1288.
27	CHIBA A, HATAYAMA T, KAINOSE K, et al. The influence of elastic moduli of core materials on shear stress distributions at the adhesive interface in resin built-up teeth[J]. Dent Mater J, 2017, 36(1): 95-102.
28	AROLA D D, REPROGEL R K. Tubule orientation and the fatigue strength of human dentin[J]. Biomaterials, 2006, 27(9): 2131-2140.
29	PLOTINO G, GRANDE N M, BEDINI R, et al. Flexural properties of endodontic posts and human root dentin[J]. Dent Mater, 2007, 23(9): 1129-1135.
30	KINNEY J H, MARSHALL S J, MARSHALL G W. The mechanical properties of human dentin: a critical review and re-evaluation of the dental literature[J]. Crit Rev Oral Biol Med, 2003, 14(1): 13-29.
31	吴悦梅, 张富强, 宋宁, 等. 石英纤维根管桩复合材料的力学性能研究[J]. 上海口腔医学, 2006, 15(3): 304-307.
	WU Y M, ZHANG F Q, SONG N, et al. Study on the mechanical properties of quartz fiber-reinforced composite for canal post[J]. Shanghai J Stomatol, 2006, 15(3): 304-307.
32	ELSAKA S E, ELNAGHY A M. Bonding durability of titanium tetrafluoride treated glass fiber post with resin cement[J]. Dent Mater J, 2019, 38(2): 189-195.
33	CARDOSO G C, NAKANISHI L, ISOLAN C P, et al. Bond stability of universal adhesives applied to dentin using etch-and-rinse or self-etch strategies[J]. Braz Dent J, 2019, 30(5): 467-475.

Component	Elastic modulus/MPa	Poisson ratio
Cancellous bone^［20-21］	1 370	0.30
Cortical bone^［20-21］	13 700	0.30
Dentin^［20-21］	18 600	0.31
Gutta-percha^［22］	141.9	0.45
Periodontal ligament^［21］	68.9	0.45
Resin cement （crown） ^［23］	18 300	0.30
Resin composite （direct restoration） ^［23-24］	12 000	0.33
Resin core build-up/Resin cement （post） ^［22］	16 440	0.26
Zirconia ceramic crown ^{［20，24］}	200 000	0.33
Quartz fiber-reinforced composite post ^［25］	E_x =50 000， E_y =E_z =15 000	0.30

Component	Elastic modulus/MPa	Poisson ratio
Cancellous bone^［20-21］	1 370	0.30
Cortical bone^［20-21］	13 700	0.30
Dentin^［20-21］	18 600	0.31
Gutta-percha^［22］	141.9	0.45
Periodontal ligament^［21］	68.9	0.45
Resin cement （crown） ^［23］	18 300	0.30
Resin composite （direct restoration） ^［23-24］	12 000	0.33
Resin core build-up/Resin cement （post） ^［22］	16 440	0.26
Zirconia ceramic crown ^{［20，24］}	200 000	0.33
Quartz fiber-reinforced composite post ^［25］	E_x =50 000， E_y =E_z =15 000	0.30

Group		PO defect						DO defect
		Vertical loading			Lateral loading			Vertical loading			Lateral loading
		P	DB	MB	P	DB	MB	P	DB	MB	P	DB	MB
NP
C		25.89	16.22	14.72	13.62	12.97	24.17	24.47	16.85	14.83	11.75	13.83	23.48
M		24.27	16.22	13.68	16.97	19.13	25.85	22.81	15.96	13.25	16.15	19.97	26.08
A		24.07	23.12	23.82	11.83	23.93	26.11	23.67	23.75	16.61	11.25	22.56	26.11
PP
C		18.62	16.11	14.90	11.15	12.90	24.95	18.35	15.98	14.96	11.51	12.67	23.76
M		35.04	16.11	13.76	19.53	19.54	26.94	36.52	15.98	12.73	19.19	19.11	24.89
A		26.66	24.17	17.32	11.22	24.84	17.51	23.73	20.75	31.70	10.84	20.37	33.79
PDP
	C	18.47	15.47	14.70	11.44	13.46	23.43	18.31	18.70	14.59	11.11	13.51	23.61
	M	36.84	27.37	13.48	20.51	19.60	24.94	35.39	26.77	13.01	19.19	20.41	25.85
	A	26.84	22.85	12.90	11.50	22.61	17.46	23.59	21.49	24.29	12.01	21.05	31.21
PMP
	C	18.58	15.87	15.13	10.82	12.82	20.57	18.46	15.80	14.59	11.43	12.37	22.23
	M	33.87	15.73	21.63	19.10	19.45	34.06	33.98	15.80	20.06	18.14	20.20	32.36
	A	31.43	18.36	26.53	14.27	21.01	27.90	27.72	20.44	31.63	11.97	20.37	37.53
PDMP
	C	18.25	15.23	13.22	11.15	13.50	21.49	18.48	14.59	15.20	11.39	13.46	20.86
	M	36.16	29.99	22.22	19.02	21.60	35.26	34.94	28.26	20.43	19.33	19.73	33.10
	A	23.90	23.81	30.73	10.98	20.02	35.45	23.72	22.31	15.32	11.63	22.73	20.00

Group		PO defect						DO defect
		Vertical loading			Lateral loading			Vertical loading			Lateral loading
		P	DB	MB	P	DB	MB	P	DB	MB	P	DB	MB
NP
C		25.89	16.22	14.72	13.62	12.97	24.17	24.47	16.85	14.83	11.75	13.83	23.48
M		24.27	16.22	13.68	16.97	19.13	25.85	22.81	15.96	13.25	16.15	19.97	26.08
A		24.07	23.12	23.82	11.83	23.93	26.11	23.67	23.75	16.61	11.25	22.56	26.11
PP
C		18.62	16.11	14.90	11.15	12.90	24.95	18.35	15.98	14.96	11.51	12.67	23.76
M		35.04	16.11	13.76	19.53	19.54	26.94	36.52	15.98	12.73	19.19	19.11	24.89
A		26.66	24.17	17.32	11.22	24.84	17.51	23.73	20.75	31.70	10.84	20.37	33.79
PDP
	C	18.47	15.47	14.70	11.44	13.46	23.43	18.31	18.70	14.59	11.11	13.51	23.61
	M	36.84	27.37	13.48	20.51	19.60	24.94	35.39	26.77	13.01	19.19	20.41	25.85
	A	26.84	22.85	12.90	11.50	22.61	17.46	23.59	21.49	24.29	12.01	21.05	31.21
PMP
	C	18.58	15.87	15.13	10.82	12.82	20.57	18.46	15.80	14.59	11.43	12.37	22.23
	M	33.87	15.73	21.63	19.10	19.45	34.06	33.98	15.80	20.06	18.14	20.20	32.36
	A	31.43	18.36	26.53	14.27	21.01	27.90	27.72	20.44	31.63	11.97	20.37	37.53
PDMP
	C	18.25	15.23	13.22	11.15	13.50	21.49	18.48	14.59	15.20	11.39	13.46	20.86
	M	36.16	29.99	22.22	19.02	21.60	35.26	34.94	28.26	20.43	19.33	19.73	33.10
	A	23.90	23.81	30.73	10.98	20.02	35.45	23.72	22.31	15.32	11.63	22.73	20.00

Post	Group	PO defect		DO defect
Post	Group	Vertical loading	Lateral loading	Vertical loading	Lateral loading
Palatal canal	PP	69.18	25.84	69.34	25.69
	PDP	60.75	25.49	66.95	25.63
	PMP	65.00	25.22	71.29	25.37
	PDMP	65.50	25.43	63.78	25.44
Distobuccal canal	PDP	42.50	26.29	39.73	27.50
	PDMP	44.65	28.16	39.85	27.06
Mesiobuccal canal	PMP	39.39	51.82	35.17	45.91
	PDMP	36.27	49.31	27.06	48.91