上颌前部倾斜基牙的生物力学分析:基于有限元分析的骨质量和加载条件的影响
Biomechanical Analysis of Angled Abutments in the Anterior Maxilla: Impact of Bone Quality and Loading Conditions Using Finite Element Analysis.
作者信息
Kaur Jaspinder, Kumar Sandeep, Aggarwal Rajnish, Singh Ashutosh R, Sharma Mansi, Sharma Rahul, Jenthuilu Pamei, Nandalur Kulashekar Reddy
机构信息
Department of Prosthodontics, Surendera Dental College and Research Institute, Sri Ganganagar, IND.
Department of Oral and Maxillofacial Surgery, Dr. S.S. Tantia Medical College, Hospital and Research Centre, Sri Ganganagar, IND.
出版信息
Cureus. 2025 May 18;17(5):e84329. doi: 10.7759/cureus.84329. eCollection 2025 May.
OBJECTIVE
This in vitro study utilized three-dimensional (3D) finite element analysis (FEA) to investigate the stress distribution around dental implants in the anterior maxilla, focusing on the interplay between 15 angled abutments, bone quality (D1-D4), and loading conditions (axial and oblique).
METHODOLOGY
Anatomically accurate 3D models of the anterior maxilla, a titanium Internal-Hex implant system (Touareg(S), Adin Dental Implants, Chile), a 15 angled abutment, and a porcelain-fused-to-metal crown were developed using cone-beam computed tomographic (CBCT) scans and CATIA V5 software (Dassault Systèms, Vélizy-Villacoublay, France) and then analyzed in ANSYS Workbench (ANSYS Inc., Canonsburg, Pennsylvania, USA). Four bone types (D1-D4) were modeled with varying cortical and cancellous proportions. Axial (178 N) and oblique (100 N at 120) loads were applied to eight models, and the stress and strain distributions were evaluated at the implant-bone and implant-abutment interfaces using tetrahedral elements. Mesh convergence ensured computational accuracy, and the material properties reflected clinical data.
RESULTS
Axial loading showed uniform stress at the implant neck, with cortical bone stress increasing from 12.023 MPa (D1) to 26.438 MPa (D4) and implant stress increasing from 67.319 MPa to 72.291 MPa. Oblique loading amplified stress asymmetrically, with cortical bone stress increasing from 20.005 to 30.704 MPa and implant stress from 97.910 to 102.458 MPa. D3 and D4 exhibit significantly higher stresses, particularly under oblique loading.
CONCLUSION
Bone quality and loading type critically influenced stress distribution. The stresses were higher in the D3 and D4 bones under oblique loading. Bone D1 and D2 provided robust support, whereas bones D3 and D4 required enhanced implant designs or augmentation. The 15 angled abutment increased stress, necessitating careful prosthetic planning to ensure biomechanical stability and esthetic outcomes in anterior maxillary implant dentistry.
目的
本体外研究利用三维(3D)有限元分析(FEA)来研究上颌前部牙种植体周围的应力分布,重点关注15种角度基台、骨质量(D1 - D4)和加载条件(轴向和斜向)之间的相互作用。
方法
使用锥形束计算机断层扫描(CBCT)扫描和CATIA V5软件(法国达索系统公司,维利齐 - 维拉库布莱)构建上颌前部、钛制内六角种植体系统(图阿雷格(S),阿迪恩牙科种植体,智利)、15种角度基台以及烤瓷熔附金属冠的解剖学精确3D模型,然后在ANSYS Workbench(美国宾夕法尼亚州卡农斯堡的ANSYS公司)中进行分析。对四种骨类型(D1 - D4)进行建模,其皮质骨和松质骨比例各不相同。对八个模型施加轴向(178 N)和斜向(与轴向成120°,100 N)载荷,并使用四面体单元在种植体 - 骨界面和种植体 - 基台界面评估应力和应变分布。网格收敛确保了计算精度,材料属性反映了临床数据。
结果
轴向加载时,种植体颈部应力均匀,皮质骨应力从12.023 MPa(D1)增加到26.438 MPa,种植体应力从67.319 MPa增加到72.291 MPa。斜向加载不对称地放大了应力,皮质骨应力从20.005 MPa增加到30.704 MPa,种植体应力从97.910 MPa增加到102.458 MPa。D3和D4显示出明显更高的应力,特别是在斜向加载下。
结论
骨质量和加载类型对应力分布有至关重要的影响。在斜向加载下,D3和D4骨中的应力更高。D1和D2骨提供了强大的支撑,而D3和D4骨需要改进种植体设计或进行骨增量。15种角度的基台增加了应力,因此在前上颌种植修复中需要仔细的修复计划,以确保生物力学稳定性和美学效果。
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