Faculty of Odontology, Federal University of Santa Maria - UFSM, Santa Maria, Rio Grande do Sul, Brazil.
Faculty of Odontology, Federal University of Santa Maria - UFSM, Santa Maria, Rio Grande do Sul, Brazil; School of Dentistry, Meridional Faculty - IMED, Passo Fundo, Rio Grande do Sul, Brazil.
J Mech Behav Biomed Mater. 2018 Nov;87:288-295. doi: 10.1016/j.jmbbm.2018.07.041. Epub 2018 Jul 31.
This study aims to evaluate the flexural fatigue strength and survival estimates of an Y-TZP monolithic ceramic after grinding and aging. Ceramic discs (1.2 mm thickness × 15.0 mm diameter - ISO, 6872, 2015) of zirconia (Zirlux FC2 - Ardent; Ivoclar Vivadent) were made and randomly allocated into 6 groups (n = 10), according to grinding and aging factors: Ctrl - as-sintered; Ctrl Sto - as-sintered and dry stored at room temperature for 2 years; Ctrl Aut Sto - as-sintered, submitted to autoclaved aging (134 °C, 2 bar, 20 h) and then dry stored for 2 years; and similar conditions for ground samples (Ground; Ground Sto; Ground Aut Sto). Grinding was performed with diamond burs (#3101G, KG Sorensen) coupled to a contra-angle torque multiplier attached to a low speed motor under constant irrigation. Fatigue testing followed a step-stress approach. Data from strength and number of cycles until fracture were recorded and analyzed through Kaplan-Meier and Mantel-Cox tests. Both grinding and aging increase monoclinic phase content. The topography was altered by grinding but not by aging procedures. Grinding did not alter the fatigue strength (Ctrl = Ground), while aging increase it only for ground groups (Ground Sto, Ground Aut Sto). Aged conditions (Ctrl Sto; Ground Sto; Ctrl Aut Sto; Ground Aut Sto) showed increased survival probabilities for both flexural fatigue strength and cycles for failure. Therefore, despite promoting monoclinic phase increase, aging and grinding did not deleteriously affect the fatigue behavior of Y-TZP ceramics.
本研究旨在评估研磨和老化后 Y-TZP 整体陶瓷的弯曲疲劳强度和存活率估计。制备了氧化锆(Zirlux FC2-Ardent;Ivoclar Vivadent)陶瓷圆盘(1.2mm 厚×15.0mm 直径 - ISO,6872,2015),并根据研磨和老化因素将其随机分为 6 组(n=10):Ctrl-烧结后;Ctrl Sto-烧结后,在室温下干燥储存 2 年;Ctrl Aut Sto-烧结后,进行高压釜老化(134°C,2bar,20h),然后在室温下干燥储存 2 年;类似条件下对研磨后的样品进行处理(Ground;Ground Sto;Ground Aut Sto)。研磨使用金刚石磨头(#3101G,KG Sorensen)与角向扭矩倍增器耦合,连接到低速电机上,在持续冲洗的情况下进行。疲劳测试采用逐步应力法进行。记录了强度和断裂前循环次数的数据,并通过 Kaplan-Meier 和 Mantel-Cox 检验进行分析。研磨和老化均增加了单斜相含量。研磨改变了形貌,但老化程序没有改变。研磨未改变疲劳强度(Ctrl=Ground),而老化仅增加了研磨组的疲劳强度(Ground Sto,Ground Aut Sto)。老化条件(Ctrl Sto;Ground Sto;Ctrl Aut Sto;Ground Aut Sto)增加了弯曲疲劳强度和失效循环的存活率。因此,尽管促进了单斜相的增加,但老化和研磨并未对 Y-TZP 陶瓷的疲劳行为产生有害影响。
