增材制造技术在种植牙科中制造金属的应用综述。

A Review of the Applications of Additive Manufacturing Technologies Used to Fabricate Metals in Implant Dentistry.

机构信息

Comprehensive Dentistry Department, College of Dentistry, Texas A&M University, Dallas, TX.

Gradute Prosthodontics, Department of Restorative Dentistry, School of Dentistry, University of Washington, Seattle, WA.

出版信息

J Prosthodont. 2020 Aug;29(7):579-593. doi: 10.1111/jopr.13212. Epub 2020 Jun 25.

DOI:10.1111/jopr.13212

PMID:32548890

Abstract

PURPOSE

To review the primary additive manufacturing (AM) technologies used to fabricate metals in implant dentistry and compare them to conventional casting and subtractive methods.

METHODS

The literature on metal AM technologies was reviewed, and the AM procedures and their current applications in implant dentistry were collated and described. Collection of published articles about metal AM in dental field data sources: MEDLINE, EMBASE, EBSCO, and Web of Science searched. All studies related to AM technology description, analysis, and evaluation of applications in implant dentistry, including AM titanium (Ti) dental implants, customized Ti mesh for bone grafting techniques, cobalt-chromium (Co-Cr) frameworks for implant impression procedures, and Co-Cr and Ti frameworks for dental implant-supported prostheses were reviewed.

RESULTS

Literature has demonstrated the potential of AM technologies to fabricate dental implants, root-analog implants, and functionally graded implants; as well as the ability to fabricate customized meshes for bone grafting procedures. Metal AM technologies provide a reliable method to manufacture frameworks for implant impression procedures. Co-Cr and Ti AM frameworks for implant-supported prostheses provide a clinically acceptable discrepancy at the implant-prostheses interface.

CONCLUSIONS

Additional clinical studies are required to assess the long-term clinical performance, biological and mechanical complications, and prosthetic restoration capabilities of additively manufactured dental implants. Moreover, further studies are needed to evaluate their long-term success and survival rates and biological and mechanical complications of AM implant-supported prostheses.

摘要

目的

综述用于口腔种植修复的金属增材制造（AM）技术，并将其与传统铸造和减材制造方法进行比较。

方法

综述了金属 AM 技术的文献，整理并描述了 AM 工艺及其在口腔种植修复中的当前应用。在 MEDLINE、EMBASE、EBSCO 和 Web of Science 等口腔领域数据来源中检索关于金属 AM 的文献。纳入所有关于 AM 技术描述、分析以及在口腔种植修复中应用评估的研究，包括 AM 钛（Ti）牙科种植体、用于骨移植技术的定制 Ti 网、用于种植体印模程序的钴铬（Co-Cr）框架以及用于牙种植体支持修复体的 Co-Cr 和 Ti 框架。

结果

文献表明 AM 技术有潜力制造牙科种植体、根模拟种植体和功能梯度种植体；以及制造用于骨移植程序的定制网的能力。金属 AM 技术为种植体印模程序制造框架提供了可靠的方法。Co-Cr 和 Ti AM 框架用于牙种植体支持修复体，在种植体-修复体界面处提供了临床可接受的差异。

结论

需要进一步的临床研究来评估增材制造牙科种植体的长期临床性能、生物和机械并发症以及修复体的修复能力。此外，还需要进一步研究来评估其长期成功率和存活率以及 AM 种植体支持修复体的生物和机械并发症。

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增材制造技术在种植牙科中制造金属的应用综述。

A Review of the Applications of Additive Manufacturing Technologies Used to Fabricate Metals in Implant Dentistry.

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSIONS

目的

方法

结果

结论

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