Modifications of Glass Ionomer Cements Using Nanotechnology: Recent Advances

Recent progress in materials Pub Date : 2022-05-01 DOI:10.21926/rpm.2202011

D. Dionysopoulos, O. Gerasimidou, C. Papadopoulos

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Abstract

Glass ionomer cements (GICs) are dental materials that were invented by Wilson & Kent in 1972. They can chemically bond to enamel and dentin and can exhibit anti-cariogenic activity that allows the release and uptake of fluoride ions. They also possess the ability to render color. The setting reaction of GICs is a neutralization reaction that results in the formation of polycarboxylate salts. The most important GIC modification process involves the addition of resin components, resulting in the development of resin-modified glass ionomer cements (RMGICs), which contain self-and photo-curing systems. Modification of conventional GICs and RMGICs can be achieved by the incorporation of nano-sized fillers into the materials. This helps reduce the size of RMGICs. Conventional GICs and RMGICs can also be modified by introducing nano-sized bioceramics to the glass powder. It has been previously reported that the incorporation of nano-sized particles helps improve the mechanical properties of conventional GICs. Conversely, the commercially available nano-filled RMGICs do not hold any significant advantage over conventional RMGICs as far as the mechanical and adhesive properties are concerned. Glass carbomer is a novel glass ionomer material, and the bioactivity of which is better than the bioactivity of the conventional GICs. However, it is more brittle and less strong than the modern conventional GICs. Additionally, clinical techniques that can be used to transfer external energy on the surface of a GIC have also been used for modification. These techniques can be used to reduce the duration of the initial setting stage and improve the rate of the setting reactions, resulting in faster development of the mechanical properties. Premature failure of the restorations can be avoided under these conditions. The lack of long-term clinical studies limits the use of nano-modified glass ionomers and glass carbomers in daily clinical practice. More randomized clinical trials are required to justify the use of these modern modified materials.

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纳米技术改性玻璃离子水门合剂的研究进展

玻璃离子水泥(gic)是1972年由Wilson & Kent公司发明的牙科材料。它们可以化学结合到牙釉质和牙本质上，并且可以表现出抗龋齿的活性，允许氟化物离子的释放和吸收。它们还具有着色的能力。GICs的固化反应是一种中和反应，其结果是形成聚羧酸盐。最重要的GIC改性过程涉及树脂组分的添加，从而导致树脂改性玻璃离子聚合物水泥(rmgic)的发展，其中包含自固化和光固化系统。通过在材料中加入纳米级填料，可以实现对常规GICs和RMGICs的改性。这有助于减少rmgic的大小。传统的GICs和RMGICs也可以通过在玻璃粉中引入纳米级生物陶瓷来修饰。此前有报道称，纳米级颗粒的掺入有助于改善传统GICs的机械性能。相反，就机械和粘合性能而言，商用的纳米填充rmgic并不比传统的rmgic具有任何显著的优势。玻璃卡波姆是一种新型的玻璃离聚体材料，其生物活性优于传统玻璃离聚体的生物活性。然而，它比现代传统的gic更脆弱，强度也更低。此外，临床技术可用于转移GIC表面的外部能量，也已用于修改。这些技术可以减少初始凝固阶段的持续时间，提高凝固反应的速度，从而使机械性能更快地发展。在这些条件下，可以避免修复体的过早失效。长期临床研究的缺乏限制了纳米改性玻璃离聚体和玻璃卡波姆在日常临床实践中的应用。需要更多的随机临床试验来证明使用这些现代改良材料的合理性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Recent progress in materials

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