Department of Dental Materials, University of São Paulo, São Paulo, SP, Brazil.
Dent Mater. 2010 Dec;26(12):1144-50. doi: 10.1016/j.dental.2010.08.003. Epub 2010 Sep 15.
To compare currently available low-shrinkage composites with others regarding polymerization stress, volumetric shrinkage (total and post-gel), shrinkage rate and elastic modulus.
Seven BisGMA-based composites (Durafill/DU, Filtek Z250/FZ, Heliomolar/HM, Aelite LS Posterior/AP, Point 4/P4, Filtek Supreme/SU, ELS/EL), a silorane-based (Filtek LS, LS), a urethane-based (Venus Diamond, VD) and one based on a dimethacrylate-derivative of dimer acid (N'Durance, ND) were tested. Polymerization stress was determined in 1-mm high specimens inserted between two PMMA rods attached to a universal testing machine. Total volumetric shrinkage was measured using a mercury dilatometer. Maximum shrinkage rate was used as a parameter of the reaction speed. Post-gel shrinkage was measured using strain-gages. Elastic modulus was obtained by three-point bending. Data were submitted to one-way ANOVA/Tukey test (p=0.05), except for elastic modulus (Kruskal-Wallis).
Composites ranked differently for total and post-gel shrinkage. Among the materials considered as "low-shrinkage" by the respective manufacturers, LS, EL and VD presented low post-gel shrinkage, while AP and ND presented relatively high values. Polymerization stress showed a strong correlation with post-gel shrinkage except for LS, which presented high stress. Elastic modulus and shrinkage rate showed weak relationships with polymerization stress.
Not all low-shrinkage composites demonstrated reduced polymerization shrinkage. Also, in order to effectively reduce polymerization stress, a low post-gel shrinkage must be associated to a relatively low elastic modulus.
比较目前可用的低收缩复合材料与其他材料在聚合应力、总体积收缩(总收缩和胶凝后收缩)、收缩率和弹性模量方面的性能。
测试了七种 BisGMA 基复合材料(Durafill/DU、Filtek Z250/FZ、Heliomolar/HM、Aelite LS Posterior/AP、Point 4/P4、Filtek Supreme/SU、ELS/EL)、一种硅烷酯基(Filtek LS、LS)、一种尿烷基(Venus Diamond、VD)和一种基于二聚酸二甲酯衍生物的复合材料(N'Durance、ND)。聚合应力通过插入到附接到万能试验机的两个 PMMA 棒之间的 1mm 高的试件来确定。总体积收缩使用汞膨胀计测量。最大收缩率用作反应速度的参数。胶凝后收缩使用应变计测量。弹性模量通过三点弯曲获得。数据采用单向方差分析/图基检验(p=0.05)进行处理,除了弹性模量(Kruskal-Wallis)。
复合材料在总收缩和胶凝后收缩方面的排名不同。在所考虑的“低收缩”材料中,LS、EL 和 VD 表现出低胶凝后收缩,而 AP 和 ND 表现出相对较高的收缩。聚合应力与胶凝后收缩呈强相关性,除了 LS,LS 表现出高应力。弹性模量和收缩率与聚合应力呈弱相关性。
并非所有低收缩复合材料都表现出降低的聚合收缩。此外,为了有效降低聚合应力,必须将低胶凝后收缩与相对较低的弹性模量相关联。
