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使用带有减压装置的定制化三维打印下颌假体:不同咀嚼位置的有限元分析、生物力学测试和利用兰屿猪进行的体内动物研究。

The Use of Customized Three-Dimensionally Printed Mandible Prostheses with a Pressure-Reducing Device: A Finite Element Analysis in Different Chewing Positions, Biomechanical Testing, and In Vivo Animal Study Using Lanyu Pigs.

机构信息

School of Dentistry, College of Dental Medicine, Kaohsiung Medical University, Kaohsiung, Taiwan.

Department of Oral and Maxillofacial Surgery, Kaohsiung Veterans General Hospital, Kaohsiung, Taiwan.

出版信息

Biomed Res Int. 2022 Mar 16;2022:9880454. doi: 10.1155/2022/9880454. eCollection 2022.

DOI:10.1155/2022/9880454
PMID:35342763
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8942632/
Abstract

Segmental bony defects of the mandible constitute a complete loss of the regional part of the mandible. Although several types of customized three-dimension-printed mandible prostheses (CMPs) have been developed, this technique has yet to be widely used. We used CMP with a pressure-reducing device (PRD) to investigate its clinical applicability. First, we used the finite element analysis (FEA). We designed four models of CMP (P1 to P4), and the result showed that CMP with posterior PRD deployment (P4 group) had the maximum total deformation in the protrusion and right excursion positions, and in clenching and left excursion positions, posterior screws had the minimum von Mises stress. Second, the P4 CMP-PRD was produced using LaserCUSING from titanium alloy (Ti-6Al-4V). The fracture test result revealed that the maximum static pressure that could be withstood was 189 N, and a fatigue test was conducted for 5,000,000 cycles. Third, animal study was conducted on five male 4-month-old Lanyu pigs. Four animals completed the experiment. Two animals had CMP exposure in the oral cavity, but there was no significant inflammation, and one animal had a rear wing fracture. According to a CT scan, the lingual cortex of the mandible crawled along the CMP surface, and a bony front-to-back connection was noted in one animal. A histological examination indicated that CMP was significantly less reactive than control materials ( = 0.0170). Adequate PRD deployment in CMP may solve a challenge associated with CMP, thus promoting its use in clinical practice.

摘要

下颌骨节段性骨缺损是下颌骨区域性完全缺失。尽管已经开发出几种类型的定制三维打印下颌假体(CMP),但该技术尚未得到广泛应用。我们使用带有减压装置(PRD)的 CMP 来研究其临床适用性。首先,我们使用有限元分析(FEA)。我们设计了四种 CMP 模型(P1 至 P4),结果表明,带有后 PRD 部署的 CMP(P4 组)在突出和右侧外展位置的总变形最大,在咬合和左侧外展位置,后螺丝的 von Mises 应力最小。其次,使用 LaserCUSING 从钛合金(Ti-6Al-4V)生产 P4 CMP-PRD。断裂试验结果表明,可承受的最大静态压力为 189N,并进行了 500 万次循环的疲劳试验。第三,对五只 4 月龄的兰屿猪进行了动物研究。四只动物完成了实验。两只动物的 CMP 在口腔中暴露,但没有明显的炎症,一只动物的后翼骨折。根据 CT 扫描,下颌舌骨皮质沿着 CMP 表面爬行,一只动物的骨前-后连接。组织学检查表明,CMP 的反应性明显低于对照材料(=0.0170)。CMP 中适当的 PRD 部署可能会解决与 CMP 相关的挑战,从而促进其在临床实践中的应用。

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