Shemtov-Yona Keren, Rittel Daniel, Machtei Eli E, Levin Liran
Faculty of Medicine, Technion, Israel Institute of Technology, Haifa, Israel.
Clin Implant Dent Relat Res. 2014 Apr;16(2):178-84. doi: 10.1111/j.1708-8208.2012.00476.x. Epub 2012 Jul 10.
The purpose of this study was to perform fracture mode analysis for in vitro failed implants in order to evaluate the relation between the fracture mode obtained and the implants' fatigue behavior.
Eighty fractured dental implants were analyzed after being tested for fatigue performance. A macroscopic failure analysis was performed, which evaluated and located the fracture modes obtained, followed by a microscopic failure analysis comprising a detailed scanning electron microscopy (SEM) fractographic analysis.
Four distinctive fracture loci were identified and macrofracture mode analysis was performed, showing that all 5-mm implants that fractured were fractured at the abutment neck and screw. In the 3.75-mm group, 44.4% were fractured at the implant neck and 55.5% at the implants second thread. Fifty-two percent of the 3.3-mm fractured implants had it at the implants second tread and 48% at the implants third thread. The implant's metallographic sections revealed that the different fracture loci were located where thin metal cross sections and sharp notches coexist. Using SEM, we were able to characterize the failure micromechanisms and fatigue characterization as transgranular fracture and arrays of secondary parallel microcracks at relatively low magnifications and classic fatigue striations at much higher magnifications.
The results of this study indicate that proper implant design is crucial to ensure long-term fatigue performance for dental implants. The combination of sharp notches (thread) and narrow metal cross section is quite deleterious for fatigue resistance.
本研究的目的是对体外失效种植体进行断裂模式分析,以评估所获得的断裂模式与种植体疲劳行为之间的关系。
对80颗断裂的牙科种植体进行疲劳性能测试后进行分析。进行了宏观失效分析,评估并确定所获得的断裂模式,随后进行微观失效分析,包括详细的扫描电子显微镜(SEM)断口分析。
确定了四个不同的断裂部位并进行了宏观断裂模式分析,结果显示所有断裂的5毫米种植体均在基台颈部和螺钉处断裂。在3.75毫米组中,44.4%在种植体颈部断裂,55.5%在种植体第二螺纹处断裂。3.3毫米断裂种植体中有52%在种植体第二螺纹处断裂,48%在种植体第三螺纹处断裂。种植体的金相切片显示,不同的断裂部位位于薄金属横截面和尖锐缺口共存的地方。使用SEM,我们能够在相对低倍率下将失效微观机制和疲劳特征表征为穿晶断裂和次生平行微裂纹阵列,在高得多的倍率下表征为经典疲劳条纹。
本研究结果表明,合适的种植体设计对于确保牙科种植体的长期疲劳性能至关重要。尖锐缺口(螺纹)和狭窄金属横截面的组合对疲劳抗性非常有害。
