Research on mechanical properties of 3D printed titanium mesh with hyperbolic paraboloid morphology and traditional approximate alveolar ridge morphology

doi:10.12337/zgkqzzxzz.2024.06.011

Abstract

Abstract: Objective To investigate the influence of hyperbolic paraboloid spatial structure on the mechanical properties of personalized titanium mesh. Methods Virtual bone augmentations were performed using 3-Matic 15 software on 3D models of the mandibles of patients with alveolar ridge resorption. The bone augmentations were performed with hyperbolic paraboloid structure and approximate alveolar ridge structure, respectively. Personalized titanium meshes with pore shapes of circular, triangular, quadrilateral, and hexagonal, and thicknesses of 0.2 mm, 0.3 mm, and 0.4 mm were fabricated. Finite element analysis models were constructed, applying the forces and constraints. The stress and displacement of titanium mesh in each group were analyzed. Results Under the same thickness, the stresses and displacements of the hyperbolic paraboloid titanium mesh with different pore structures were significantly lower than those of the approximate alveolar ridge titanium mesh; as the thickness decreased, the stress and displacement of titanium mesh in each group significantly increased. Conclusion This spatial structure of hyperbolic paraboloid can distribute the stress uniformly, reduce the stress concentration of the personalized titanium mesh, decrease displacement of the titanium mesh after loading, allowing the titanium mesh to combine good mechanical properties and thinner thickness, reducing irritation to soft tissues and the risk of titanium mesh exposure.

Key words: Hyperbolic paraboloid, Personalized titanium mesh, Guided bone regeneration, 3D finite element analysis, Bone augmentation

Wang Huaisheng, Wang Xinyu, Han Zekui, Jiang Tingting, Chen He, Liu Lu. Research on mechanical properties of 3D printed titanium mesh with hyperbolic paraboloid morphology and traditional approximate alveolar ridge morphology[J]. Chinese Journal of Oral Implantology, 2024, 29(3): 258-265.

References

[1] 邹多宏, 杨驰, 张志愿. 牙槽骨骨增量技术新进展[J].精准医学杂志,2020,35(5):377-382,388. DOI: 10.13362/j.jpmed.202005001.
[2] Elgali I, Omar O, Dahlin C, et al.Guided bone regeneration: materials and biological mechanisms revisited[J]. Eur J Oral Sci, 2017,125(5):315-337. DOI: 10.1111/eos.12364.
[3] Rakhmatia YD, Ayukawa Y, Furuhashi A, et al.Current barrier membranes: titanium mesh and other membranes for guided bone regeneration in dental applications[J]. J Prosthodont Res, 2013,57(1):3-14. DOI: 10.1016/j.jpor.2012.12.001.
[4] Xie Y, Li S, Zhang T, et al.Titanium mesh for bone augmentation in oral implantology: current application and progress[J]. Int J Oral Sci, 2020,12(1):37. DOI: 10.1038/s41368-020-00107-z.
[5] 周立波, 宿玉成, 李昕茹, 等. 比较个性化钛网与传统钛网在引导骨再生后暴露的系统综述[J].中国口腔种植学杂志, 2022,27(2):112-118. DOI: 10.12337/zgkqzzxzz.2022.04.011.
[6] 王凌旭, 王芳芳, 王鹏来. 个性化增材制造钛网在口腔种植骨增量中的应用及研究进展[J].中国口腔种植学杂志, 2023,28(5):364-370. DOI: 10.12337/zgkqzzxzz.2023.10.012.
[7] 白丽云, 季平, 李显, 等. 不同厚度的3D打印个性化钛网的三维有限元分析[J].口腔医学研究,2019,35(1):75-79. DOI: 10.13701/j.cnki.kqyxyj.2019.01.018.
[8] 董伟强. 双曲抛物面网壳结构动力性能研究[D]. 青岛:山东科技大学, 2009.
[9] Sarrafpour B, Swain M, Li Q, et al.Tooth eruption results from bone remodelling driven by bite forces sensed by soft tissue dental follicles: a finite element analysis[J]. PLoS One, 2013,8(3):e58803. DOI: 10.1371/journal.pone.0058803.
[10] Benic GI, Hämmerle CH.Horizontal bone augmentation by means of guided bone regeneration[J]. Periodontol 2000, 2014,66(1):13-40. DOI: 10.1111/prd.12039.
[11] Majewski P.The Ti-mesh technique: guided bone regeneration for three-dimensional augmentations. clinical aspects: a case series[J]. Int J Periodontics Restorative Dent. 2022,42(2):145-153. DOI: 10.11607/prd.5692.
[12] Gutta R, Baker RA, Bartolucci AA, et al.Barrier membranes used for ridge augmentation: is there an optimal pore size?[J]. J Oral Maxillofac Surg, 2009,67(6):1218-1225. DOI: 10.1016/j.joms.2008.11.022.
[13] Li S, Zhang T, Zhou M, et al.A novel digital and visualized guided bone regeneration procedure and digital precise bone augmentation: a case series[J]. Clin Implant Dent Relat Res, 2021,23(1):19-30. DOI: 10.1111/cid.12959.
[14] Stamp R, Fox P, O'Neill W, et al. The development of a scanning strategy for the manufacture of porous biomaterials by selective laser melting[J]. J Mater Sci Mater Med, 2009,20(9):1839-1848. DOI: 10.1007/s10856-009-3763-8.
[15] Pellegrino G, Lizio G, Corinaldesi G, et al.Titanium mesh technique in rehabilitation of totally edentulous atrophic maxillae: a retrospective case series[J]. J Periodontol, 2016,87(5):519-528. DOI: 10.1902/jop.2016.150432.
[16] 张亮, 韩泽奎, 臧旖欣, 等. 仿生蛛网孔隙结构3D打印个性化钛网设计及三维有限元分析[J].中国组织工程研究,2023,27(30):4796-4801.
[17] Haden CV, Collins PC, Harlow DG.Yield strength prediction of titanium alloys[J]. JOM, 2015,67(6):1357-1361.DOI: 10.1007/s11837-015-1436-2.
[18] Ciocca L, Lizio G, Baldissara P, et al.Prosthetically CAD-CAM-guided bone augmentation of atrophic jaws using customized Titanium mesh: preliminary results of an open prospective study[J]. J Oral Implantol, 2018,44(2):131-137. DOI: 10.1563/aaid-joi-D-17-00125.
[19] Lee SH, Moon JH, Jeong CM, et al.The mechanical properties and biometrical effect of 3D preformed titanium membrane for guided bone regeneration on alveolar bone defect[J]. Biomed Res Int, 2017,2017:7102123. DOI: 10.1155/2017/7102123.
[20] 桂国祥, 刘雅芸. 双曲抛物面在实际生活中的应用[J].产业与科技论坛, 2018,17(16):52-53. DOI: 10.3969/j.issn.1673-5641.2018.16.027.
[21] 王宁. 双曲抛物面网壳结构静力性能研究与模型试验[D]. 青岛:山东科技大学, 2009.