口腔内装置用热塑性丙烯酸材料挤出:技术可行性和评价。

G. Ankit, Frank Alifui-Segbaya, S. Hasanov, Alan R. White, K. E. Ahmed, Robert M. Love, I. Fidan
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引用次数: 1

摘要

随着全球对3D打印医疗设备的需求不断上升,寻找更安全、廉价和可持续的方法是及时的。在此,我们评估了丙烯酸义齿基托材料挤压工艺的实用性,其成功的结果可以扩展到种植手术导向、正畸夹板、印模托盘、记录基托和腭裂或其他上颌缺陷的闭孔器。采用不同的打印方向(pd)、层高(LHs)和短玻璃纤维增强(RFs),用内部聚甲基丙烯酸甲酯长丝设计和构建具有代表性的材料,包括义齿原型和测试样品。该研究对材料进行了全面的评估,以确定其弯曲、断裂和热性能。对于具有最佳参数的部件,完成了拉伸和压缩性能、化学成分、残留单体和表面粗糙度(Ra)的附加分析。显微分析表明,复合材料具有良好的纤维-基体相容性,其力学性能随着RFs和LHs的降低而提高。纤维增强也提高了材料的整体导热性。另一方面,Ra随着RFs和LHs的降低而明显改善,并且原型可以毫不费力地抛光并使用贴面复合材料模拟牙龈组织。在化学稳定性方面,残留的甲基丙烯酸甲酯单体含量远低于生物反应的标准阈值。值得注意的是,在z轴0°方向上以0.05 mm LH构建的5 vol%丙烯酸复合材料的性能优于传统丙烯酸、研磨丙烯酸和3D打印光聚合物。有限元模型成功地复制了原型的拉伸性能。可以很好地争辩说,材料挤压工艺是具有成本效益的;然而,制造的速度可能比现有方法要长。虽然平均Ra在可接受范围内,但长期口内使用仍需要强制手工精加工和美观色素沉着。在概念验证层面,很明显,材料挤压工艺可以应用于构建廉价、安全、坚固的热塑性丙烯酸装置。这项新研究的广泛结果同样值得学术反思,并进一步转化为临床。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Material extrusion of thermoplastic acrylic for intraoral devices: Technical feasibility and evaluation.
With global demand for 3D printed medical devices on the rise, the search for safer, inexpensive, and sustainable methods is timely. Herein, we assessed the practicality of the material extrusion process for acrylic denture bases of which successful outcomes can be extended to implant surgical guides, orthodontic splints, impression trays, record bases and obturators for cleft palates or other maxillary defects. Representative materials comprising denture prototypes and test samples were designed and built with in-house polymethylmethacrylate filaments using varying print directions (PDs), layer heights (LHs) and reinforcements (RFs) with short glass fiber. The study undertook a comprehensive evaluation of the materials to determine their flexural, fracture, and thermal properties. Additional analyses for tensile and compressive properties, chemical composition, residual monomer, and surface roughness (Ra) were completed for parts with optimum parameters. Micrographic analysis of the acrylic composites revealed adequate fiber-matrix compatibility and predictably, their mechanical properties improved simultaneously with RFs and decreased LHs. Fiber reinforcement also improved the overall thermal conductivity of the materials. Ra, on the other hand, improved visibly with decreased RFs and LHs and the prototypes were effortlessly polished and characterized with veneering composites to mimic gingival tissues. In terms of chemical stability, the residual methyl methacrylate monomer contents are well below standards threshold for biological reactions. Notably, 5 vol% acrylic composites built with 0.05 mm LH in 0° on z-axis produced optimum properties that are superior to those of conventional acrylic, milled acrylic and 3D printed photopolymers. Finite element modeling successfully replicated the tensile properties of the prototypes. It may well be argued that the material extrusion process is cost-effective; however, the speed of manufacturing could be longer than that of established methods. Although the mean Ra is within an acceptable range, mandatory manual finishing and aesthetic pigmentation are required for long-term intraoral use. At a proof-of-concept level, it is evident that the material extrusion process can be applied to build inexpensive, safe, and robust thermoplastic acrylic devices. The broad outcomes of this novel study are equally worthy of academic reflection, and further translation to the clinic.
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