高速激光钻牙种植:消融过程和应用技术

Christina Giesen, Lazar Bochvarov, Marcel Bogdoll, Simon Vervoort, Achim Lenenbach, Yong-Min Yo
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引用次数: 0

摘要

传统的机械钻孔种植体植入受限于特定的几何形状和方向,导致定位不正确,在薄骨或多孔骨中锚定不足。本研究提出了一种基于激光消融的工艺和应用技术,用于在口腔中进行精确和快速的激光钻孔。在工艺开发中,使用波长为10.6 μm的CO2激光器。研究了在10 μs ~ 400 μs范围内进行低热冲击快速激光钻孔的脉冲持续时间。为了有效地消融和冷却骨组织,我们使用了精细的水喷雾。激光喷射器设计有一个集成的扫描模块,聚焦光学和一个紧凑的水喷射系统,在喷射器尖端有三个喷嘴。使用数字显微镜和扫描电子显微镜分析腔体的几何形状,可以测量消融的体积和深度,并研究骨的微观结构。本研究展示了一种激光烧蚀工艺,能够产生1.75mm3/s的烧蚀速率,比先前报道的高约80%。在此烧蚀速率下,熔化区域小于30 μm。本文介绍了一种具有快速消融过程和高度集成应用器的口腔激光钻孔系统的概念。
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High-Speed Laser Drilling for Dental Implantation: Ablation Process and Applicator Technology
Abstract Conventional mechanical drilling for implant placement is limited to specific geometry and orientation, resulting in incorrect positioning and inadequate anchoring in thin or porous bone. This study presents the development of a laser-based ablation process and an applicator technology for precise and fast laser drilling in the oral cavity. For the process development, a CO2 laser with a wavelength of 10.6 μm was used. Pulse durations between 10 μs and 400 μs were investigated for fast laser drilling with low thermal impact. For efficient ablation and cooling of the bone tissue, we applied a fine water spray. The laser applicator is designed with an integrated scanning module, focusing optics and a compact water spray system with three spray nozzles in the applicator tip. The geometry of the cavities was analyzed using digital microscopy and scanning electron microscopy, allowing to measure the ablated volume and depth as well as investigating the bone microstructure. This study demonstrates a laser ablation process capable to generate cavities with an ablation rate of 1.75mm3/s which is about 80% higher than previously reported. At this ablation rate the melted zones were smaller than 30 μm. This paper demonstrates a concept for a dental laser drilling system with a fast ablation process and a highlyintegrated applicator for treatment in the oral cavity.
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来源期刊
Current Directions in Biomedical Engineering
Current Directions in Biomedical Engineering Engineering-Biomedical Engineering
CiteScore
0.90
自引率
0.00%
发文量
239
审稿时长
14 weeks
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