Cruz Ronaldo S, Fernandes E Oliveira Hiskell Francine, Lemos Cleidiel Aparecido Araújo, de Souza Batista Victor Eduardo, Capalbo da Silva Rodrigo, Verri Fellippo R
Department of Dental Materials and Prosthodontics, Araçatuba Dental School (UNESP), Univ Estadual Paulista, Araçatuba, Brazil.
Department of Dentistry (Division of Prosthodontics), Federal University of Juiz de Fora (UFJF)-Campus Governador Valadares, Governador Valadares, Minas Gerais, Brazil.
J Prosthodont. 2024 Feb;33(2):180-187. doi: 10.1111/jopr.13667. Epub 2023 Mar 10.
To evaluate the tendency of movement, stress distribution, and microstrain of single-unit crowns in simulated cortical and trabecular bone, implants, and prosthetic components of narrow-diameter implants with different lengths placed at the crestal and subcrestal levels in the maxillary anterior region using 3D finite element analysis (FEA).
Six 3D models were simulated using Invesalius 3.0, Rhinoceros 4.0, and SolidWorks software. Each model simulated the right anterior maxillary region including a Morse taper implant of Ø2.9 mm with different lengths (7, 10, and 13 mm) placed at the crestal and subcrestal level and supporting a cement-retained monolithic single crown in the area of tooth 12. The FEA was performed using ANSYS 19.2. The simulated applied force was 178 N at 0°, 30°, and 60°. The results were analyzed using maps of displacement, von Mises (vM) stress, maximum principal stress, and microstrain.
Models with implants at the subcrestal level showed greater displacement. vM stress increased in the implant and prosthetic components when implants were placed at the subcrestal level compared with the crestal level; the length of the implants had a low influence on the stress distribution. Higher stress and strain concentrations were observed in the cortical bone of the subcrestal placement, independent of implant length. Non-axial loading influenced the increased stress and strain in all the evaluated structures.
Narrow-diameter implants positioned at the crestal level showed a more favorable biomechanical behavior for simulated cortical bone, implants, and prosthetic components. Implant length had a smaller influence on stress or strain distribution than the other variables.
使用三维有限元分析(FEA)评估在上颌前部区域不同长度的窄直径种植体置于嵴顶和嵴下水平时,单单位冠在模拟皮质骨和松质骨、种植体及修复组件中的运动趋势、应力分布和微应变。
使用Invesalius 3.0、Rhinoceros 4.0和SolidWorks软件模拟六个三维模型。每个模型模拟右上颌前部区域,包括一个直径为Ø2.9 mm、不同长度(7、10和13 mm)的莫氏锥度种植体,置于嵴顶和嵴下水平,并在12号牙区域支持一个粘结固位的整体单冠。使用ANSYS 19.2进行有限元分析。模拟施加的力在0°、30°和60°时为178 N。使用位移图、冯·米塞斯(vM)应力、最大主应力和微应变对结果进行分析。
种植体置于嵴下水平的模型显示出更大的位移。与嵴顶水平相比,种植体置于嵴下水平时,种植体和修复组件中的vM应力增加;种植体长度对应力分布影响较小。在嵴下种植的皮质骨中观察到更高的应力和应变集中,与种植体长度无关。非轴向加载影响所有评估结构中应力和应变的增加。
置于嵴顶水平的窄直径种植体对模拟皮质骨、种植体和修复组件显示出更有利的生物力学行为。种植体长度对应力或应变分布的影响小于其他变量。
