3D打印图案化微结构氧化锆桩粘接性能及弯曲强度的研究

doi:10.7518/hxkq.2025.2025119

华西口腔医学杂志 ›› 2026, Vol. 44 ›› Issue (1): 106-112.doi: 10.7518/hxkq.2025.2025119

3D打印图案化微结构氧化锆桩粘接性能及弯曲强度的研究

江琦¹^,²^,³^,⁴(), 尹路¹^,³^,⁴()

^1.厦门医学院附属口腔医院，厦门市口腔疾病诊疗重点实验室，厦门 361003
^2.仓山区金山街道第二社区卫生服务中心（仓山区总医院金山街道第二分院），福州 350007
^3.厦门医学院，厦门 361023
^4.口腔生物材料福建省高校工程研究中心，厦门医学院，厦门 361023

收稿日期:2025-03-28 出版日期:2026-02-01 发布日期:2026-02-02
通讯作者: 尹路 E-mail:807764508@qq.com;516021929@qq.com
作者简介:江琦，医师，硕士，E-mail：807764508@qq.com
基金资助:
福建省医学创新课题(2022CXB022);厦门市科技计划项目(3502Z20224035)

Adhesive property and flexural strength of patterned microstructured zirconia posts fabricated by 3D printing

Jiang Qi¹^,²^,³^,⁴(), Yin Lu¹^,³^,⁴()

^1.Affiliated Stomatological Hospital of Xiamen Medical University, Xiamen Key Laboratory of Oral Disease Diagnosis and Treatment, Xiamen 361003, China
^2.Jinshan Second Community Healthcare Center of Cangshan District (Jinshan Second Branch of Cangshan District General Hospital), Fuzhou 350007, China
^3.Xiamen Medical University, Xiamen 361023, China
^4.Oral Biomaterials Engineering Research Center of Fujian University, Xiamen Medical University, Xiamen 361023, China

Received:2025-03-28 Online:2026-02-01 Published:2026-02-02
Contact: Yin Lu E-mail:807764508@qq.com;516021929@qq.com
Supported by:
Fujian Medical Innovation Project(2022CXB022);Xiamen Science and Technology Project(3502Z2022-4035)

摘要/Abstract

摘要：

目的使用集成化编程软件对3D打印氧化锆桩表面进行图案化微结构处理，研究图案化微结构处理对氧化锆桩粘接性能及弯曲强度的影响。方法以3号3M纤维桩为模型，使用编程软件HyperMill 2021由桩顶延伸至桩底，在桩表面设计直线型排溢沟，共设计5组图案化微结构处理氧化锆桩，另设3号3M纤维桩为对照组。然后进行微推出试验和三点弯曲试验，测量不同图案化微结构处理氧化锆桩的粘接强度和弯曲强度；体视显微镜分析粘接失效模式。结果图案化微结构处理显著增加了氧化锆桩的粘接强度（P<0.05），根颈部、根中部及根尖部的粘接强度范围分别为9.80 MPa±0.64 MPa~26.49 MPa±0.94 MPa，9.26 MPa±1.08 MPa~18.51 MPa±0.93 MPa，6.74 MPa±0.31 MPa~13.00 MPa±0.71 MPa。图案化微结构处理降低了氧化锆桩的弯曲强度（P<0.05），弯曲强度范围为378.3 MPa±24.18 MPa~587.4 MPa±36.60 MPa。图案化微结构处理的氧化锆桩粘接失效模式以混合失效为主。结论应用3D打印技术可制备出具有良好弯曲强度和粘接性能的表面图案化氧化锆桩，可满足临床对于个性化桩核设计的需求。

关键词: 3D打印, 氧化锆桩, 图案化处理, 粘接强度, 弯曲强度

Abstract:

Objective This study aims to design surface patterns using integrated programming software on zirconia posts fabricated through 3D printing. Methods A type 3 3M fiber post was built as a research model, and HyperMill 2021 software was applied to design linear overflow grooves extending from the apex to the base on the post surface. The design parameters included the number, depth, and width of the overflow grooves. Five groups of patterned microstructured zirconia posts were designed, with the 3M fiber post as the control group. Micro-push-out and three-point bending tests were used to measure the bon-ding and flexural strengths of the patterned microstructured zirconia posts. The failure mode of bonding was analyzed by using a stereomicroscope. Results The patterned microstructure significantly increased the bond strength of zirconia posts (P<0.05). Bonding strength ranged from 9.80 MPa±0.64 MPa to 26.49 MPa±0.94 MPa at the base of the root, from 9.26 MPa±1.08 MPa to 18.51 MPa±0.93 MPa at the center of the root, and from 6.74 MPa±0.31 MPa to 13.00 MPa±0.71 MPa at the apex of the root. The implementation of patterned microstructures reduced the flexural strength of the zirconia post (P<0.05), and flexural strength ranged from 378.3 MPa±24.18 MPa to 587.4 MPa±36.60 MPa. The failure mode of zirconia post adhesions treated with patterned microstructures was mainly mixed failure. Conclusion Patterned microstructured zirconia posts with improved flexural strength and adhesive properties could be produced by using 3D printing. The bonding and flexural strengths of the patterned zirconia posts can meet the clinical requirements for custom post-and-core design.

Key words: 3D printing, zirconia post, patterned treatment, bonding strength, flexural strength

中图分类号:

R783.2

江琦, 尹路. 3D打印图案化微结构氧化锆桩粘接性能及弯曲强度的研究[J]. 华西口腔医学杂志, 2026, 44(1): 106-112.

Jiang Qi, Yin Lu. Adhesive property and flexural strength of patterned microstructured zirconia posts fabricated by 3D printing[J]. West China Journal of Stomatology, 2026, 44(1): 106-112.

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组别	根颈部	根中部	根尖部
对照组	13.05±0.32	11.18±0.62	9.10±0.39
MZ0	9.94±0.58	8.79±0.63*	6.68±0.45*
MZ4	18.86±0.96*	15.81±0.47**	10.95±0.36**
MZ8	22.04±1.59*	17.67±0.61**	12.06±0.60**
MZ16	26.49±0.94*	18.51±0.93**	13.00±0.71**
MZ32	9.80±0.64	9.26±1.08	6.74±0.31*

3D打印图案化微结构氧化锆桩粘接性能及弯曲强度的研究

Adhesive property and flexural strength of patterned microstructured zirconia posts fabricated by 3D printing

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