Puengpaiboon Usanee, Rattanapan Nichapat, Pasam Vamsi Krishna, Sukjamsri Chamaiporn
Department of General Dentistry, Faculty of Dentistry, Srinakharinwirot University, Bangkok, Thailand.
Department of Biomedical Engineering, Faculty of Engineering, Srinakharinwirot University, Nakhon Nayok, Thailand.
Eur J Dent. 2025 Feb;19(1):37-47. doi: 10.1055/s-0044-1785532. Epub 2024 May 14.
Due to the lack of literature concerning the selection of crown materials for the restoration of anterior teeth, this study aimed to investigate the effects of six distinct computer-aided design and computer-aided manufacturing (CAD-CAM) crown materials on stress and strain distribution within implant-supported maxillary central incisor restorations, employing finite element analysis (FEA). Furthermore, a comparative analysis was conducted between models that incorporated adjacent natural teeth and those that did not, intending to guide the selection of the most suitable modeling approach.
Crown materials, including Lava Ultimate, Enamic, Emax CAD, Suprinity, Celtra Duo, and Cercon xt ML, were the subjects of the investigation. FEA models incorporating Coulomb friction were developed. These models were subjected to an oblique load, simulating the average maximum bite force experienced by anterior teeth. The potential for failure in titanium implant components and the prosthesis crown was evaluated through von Mises and principal stress, respectively. Furthermore, the failure of crestal bone was assessed through principal strain values.
Stress values for each implant component and strain values of the bone were extracted from the models. To assess the impact of the six groups of crown materials, Kruskal-Wallis analysis of variance and post-hoc comparisons were conducted. Additionally, a statistical comparison between the two groups with Lava Ultimate and Cercon xt ML was performed using the Mann-Whitney U test to determine the difference in the two modeling approaches.
Higher crown material stiffness led to decreased stress in the abutment, fixture, and retaining screw, along with reduced strain in the surrounding bone. However, the decrease in stress and strain values became less significant with increasing crown stiffness. Additionally, the model with adjacent teeth showed significantly lower stress and strain concentrations compared to the model without adjacent teeth.
Crowns with a high elastic modulus were the optimal choice for anterior teeth restoration. Constructing FEA models with adjacent teeth was highly recommended to gain a deeper understanding of the mechanical behavior of dental implant restorations.
由于缺乏关于前牙修复体冠材料选择的文献,本研究旨在采用有限元分析(FEA)研究六种不同的计算机辅助设计和计算机辅助制造(CAD-CAM)冠材料对种植体支持的上颌中切牙修复体内应力和应变分布的影响。此外,对包含相邻天然牙的模型和不包含相邻天然牙的模型进行了对比分析,旨在指导最合适建模方法的选择。
研究对象为冠材料,包括Lava Ultimate、Enamic、Emax CAD、Suprinity、Celtra Duo和Cercon xt ML。开发了包含库仑摩擦的有限元分析模型。这些模型承受斜向载荷,模拟前牙所经历的平均最大咬合力。分别通过冯·米塞斯应力和主应力评估钛种植体部件和修复体冠的失效可能性。此外,通过主应变值评估牙槽嵴骨的失效情况。
从模型中提取每个种植体部件的应力值和骨的应变值。为评估六组冠材料的影响,进行了Kruskal-Wallis方差分析和事后比较。此外,使用曼-惠特尼U检验对Lava Ultimate和Cercon xt ML两组进行统计比较,以确定两种建模方法的差异。
较高的冠材料刚度导致基台、种植体和固位螺钉中的应力降低,以及周围骨中的应变减小。然而,随着冠刚度的增加,应力和应变值的降低变得不那么显著。此外,与不包含相邻牙的模型相比,包含相邻牙的模型显示出明显更低的应力和应变集中。
高弹性模量的冠是前牙修复的最佳选择。强烈建议构建包含相邻牙的有限元分析模型,以更深入地了解牙种植体修复体的力学行为。
