Investigating the optimal design of all-on-four technique adopting finite element analysis: the aspect of framework material, kind and position of implants

Antonio Lanza , Marco De Stefano , Alessandro Ruggiero
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Abstract

Nowadays, the dental implant surgery is a sophisticate and accurate sector with techniques increasingly innovative such as rapid prototyping, guided implant surgery and stem cell-based approaches. An example is certainly the use of multiple implants (4–6), instead of several prosthesis in case of human edentulous condition. The aim of this research is to investigate the mechanical behavior of the All-on-Four technique for different boundary conditions such as the value of load, framework material, type and position of implant. The goal was essentially trying to find out, by the application of structural static Finite Element Analysis (FEM), the best design for this specific treatment. After that, a stress-life fatigue numerical analysis was conducted for the optimal configuration in order to estimate the fatigue life in accordance with both Gerber and Goodman mean stress theory. The coupling involved the implants supported by an arch and a human mandible composed of cortical and cancellous part. After the simulations, it was found that the stress/strain field was very sensitive to the boundary conditions imposed. In particular, the position of the implants and the material framework yielded different responses depending on the implant design. Finally the use of ultrashort implants provided a significant decrease in the developed efforts than the long ones if the first premolar position was assumed. More specific, the stress peaks were in the range 100–225MPa for the implants, 300–537MPa for the framework, 50–124MPa for the cortical bone and 3–35MPa for the cancellous bone and they were located essentially in the abutment-framework connection as much as in implant neck-bone coupling. The best design saw the presence of ultra-short implant, first premolar position and Co-Cr alloy as framework material. The fatigue test confirmed the stability of the structure even with dynamic loads, but critical spots were present in the framework. In conclusion, the All-on-Four technique is a valid and safe alternative, even in case of ultrashort implants, for human edentulism care.

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采用有限元分析方法从框架材料、种植体种类和位置等方面探讨了全对四技术的优化设计
如今,随着快速成型、引导种植手术和基于干细胞的方法等技术的不断创新,牙科种植手术是一个复杂和精确的领域。一个例子当然是使用多个种植体(4-6),而不是在人类无牙的情况下使用几个假体。本研究的目的是研究All-on-Four技术在不同边界条件下的力学行为,如载荷值、框架材料、种植体类型和位置。目标基本上是通过结构静力有限元分析(FEM)的应用,找出这种特殊处理的最佳设计。然后,对最优结构进行应力-寿命疲劳数值分析,根据Gerber和Goodman平均应力理论估计疲劳寿命。该耦合包括由弓支撑的种植体与由皮质和松质部分组成的人下颌骨。模拟结果表明,应力应变场对边界条件非常敏感。特别是,种植体的位置和材料框架根据种植体的设计产生不同的反应。最后,如果采用第一前磨牙位置,使用超短种植体比长种植体提供了显着减少发展的努力。更具体地说,种植体的应力峰值范围为100-225 MPa,框架为300-537 MPa,皮质骨为50-124 MPa,松质骨为3-35 MPa,它们主要位于基台-框架连接处以及种植体颈骨连接处。最佳设计为超短种植体,第一前磨牙位置和Co-Cr合金作为框架材料。疲劳试验证实了结构在动荷载作用下的稳定性,但框架内存在临界点。综上所述,All-on-Four技术是一种有效且安全的替代方法,即使在超短种植体的情况下,也适用于人类全牙保健。
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来源期刊
Biomedical engineering advances
Biomedical engineering advances Bioengineering, Biomedical Engineering
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59 days
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