功能单体结构对口腔正畸胶粘剂性能的影响

制备了一种口腔正畸胶粘剂,并研究了功能单体结构对其性能的影响。功能单体二甲基丙烯酸乙氧基均苯四甲酸酯(PMDM)结构中含有双甲基丙烯酸酯可聚合基团、双粘接性羧基及强极性羟基基团。研究结果表明,随着PMDM含量的增加,羧基浓度增加,胶粘剂的粘接强度也随之增大;当w(PMDM)=10%时,剪切强度达最大值(20.81MPa);与传统功能单体4-甲基丙烯酰氧乙基偏苯三酸酐(4-META)相比,PMDM的优点是可以通过聚合基团引发交联反应,并且易溶于基质树脂中,从而减少了稀释剂的用量,胶粘剂固化物的硬度提高至90.37N/mm2;PMDM中的极性基团可与填料羟基磷灰石(HAP)中的羟基形成次价键,从而提高了基质树脂与HAP的界面粘接力,使胶粘剂与牙釉质之间的破坏方式为粘接破坏,有利于正畸托槽的摘除。

功能单体结构对口腔正畸胶粘剂性能的影响研究

为探究功能单体结构对口腔正畸胶粘剂性能的影响,研究以N-二甲胺基甲基丙烯酸乙酯(DMAEMA)、樟脑醌等为原料,制备了功能单体二甲基丙烯酸乙氧基均苯四甲酸酯(PMDM),配制正畸胶粘剂,对其表征进行分析,并测试了剪切强度、硬度。结果表明,胶粘剂粘接强度会随着PMDM及4-META含量的增加而呈现出升高趋势;PMDM质量分数为10%时,剪切强度达到最高,为20.91 MPa;4-META质量分数为7%时,剪切强度可达到25.21 MPa;PMDM经聚合基团引发交联反应,与基质树脂相溶性好,能够减少稀释剂用量,提升胶粘剂固化物硬度及粘接效果。

功能单体结构对口腔正畸胶黏剂性能的影响效果分析

目的：对功能单体结构对口腔正畸胶黏荆性能的影响效果进行分析研究。方法：对功能单体二甲基丙烯酸乙氧基均苯四甲酸酯（PMDM）和传统功能单体4-甲基丙烯酰氧乙基偏苯三酸酐（4-META）对胶粘剂与牙釉质间剪切强度影响进行比较。结果：4－META比PMDM能更有效地提高胶粘剂／牙釉质体系的剪切强度。当PMDM含量相同时，不含TEGDMA的胶粘剂／牙釉质体系的剪切强度高于含TEGDMA的胶粘剂／牙釉质体系的剪切强度。结论：综合比较双酯功能单体PMDM在口腔正畸领域中有更好的应用前景。

不同功能的单体材料对口腔正畸胶粘剂粘接性能的影响

研究合成一定的功能单体二甲基丙烯酸乙氧基均苯四甲酸酯(PMDM),并通过实验测试方式,与以往临床应用较多的功能单体4-META的应用效果进行比较,分析不同功能单体对口腔正畸胶粘剂性能的影响效果。实验结果显示,随着所添加PMDM质量分数的不断增加,胶粘剂与牙釉质间剪切强度也呈现出不断增大的变化趋势。不同功能单体对胶粘剂与牙釉质间剪切强度均会产生一定的影响,且相应的影响存在一定的差异。4-META在增加胶粘剂与牙釉质间剪切强度方面的效果更为显著。双酯PMDM作为功能单体可满足临床应用要求,PMDM可以提高胶粘剂/牙釉质间粘接强度,并能够增加固化物的交联度。在选择PMDM作为功能单体的情况下,在一定黏度条件下,可以不添加稀释剂TEGDMA。

Polymers with complicated architectures constructed from the versatile, functional monomer 1-ethoxyethyl glycidyl ether

Because glycidyl(Gly) contains an epoxy and an active hydroxyl group, the Gly unit is difficult to introduce into certain polymeric chains in a controlled manner and usually yields hyperbranched polyglycidyl. Alternatively, the monomer 1-ethoxyethyl glycidyl ether(EEGE), derived from Gly and ethyl vinyl ether, has shown potential for application in polymer chemistry, and homopolymerization of this monomer directly produces linear poly(1-ethoxyethyl glycidyl ether) and further yields linear polyglycidyl. In this review, the initiation system of the EEGE monomer is first discussed in terms of chain transfer to monomers in ring-opening polymerization of epoxides with substituent groups. Then, random copolymerization of EEGE with other epoxides is considered. In addition, because the EEGE units on polymers can be transferred to Gly units and further used to construct copolymers with complicated architectures, the applications of EEGE monomers to block, graft, and hyperbranched copolymers are reviewed. Finally, the synthesis of main chain and terminal functional polyethers by transforming the hydroxyl groups at the polymer end or on the main chain into certain functional groups are also discussed. Chemistry based on EEGE has been proved to be an efficient, versatile route to constructing copolymers containing Gly units and ultimately yielding the target properties and applications.