Research progress on surface treatment inhibiting bacterial biofilm formation on 3D printed resin surfaces

doi:10.3760/cma.j.issn.1007-1245.2024.11.001

International Medicine and Health Guidance News ›› 2024, Vol. 30 ›› Issue (11): 1761-1765.DOI: 10.3760/cma.j.issn.1007-1245.2024.11.001

• New Medical Advances • Next Articles

Research progress on surface treatment inhibiting bacterial biofilm formation on 3D printed resin surfaces

Ma Hong¹, Hu Meichun², Yu Liuping², Ding Zhuang¹, Gao Yufeng¹, Cao Yannan¹, Xu Yanhua³, Zhu Fangyong¹

¹Department of Stomatology, Affiliated Hospital of Jiangnan University, Wuxi 214000, China; ²Wuxi Medical College, Jiangnan University, Wuxi 214000, China; ³Department of Orthodontics, Yunnan Stomatological Hospital, Kunming 650101, China

Received:2024-02-21 Online:2024-06-01 Published:2024-06-25
Contact: Zhu Fangyong, Email: 4645056@163.com
Supported by:
National Natural Science Foundation (81960195); General Project of Wuxi Municipal Health and Family Planning Commission (M202240); Top Young and Middle aged Talents of Wuxi Health Commission (HB2023054); Research Project of Clinical Research and Translational Medicine at Affiliated Hospital of Jiangnan University (LCYJ202223 and LCYJ202346)

表面处理抑制3D打印树脂表面细菌生物膜形成的研究进展

马红¹ 胡美纯² 于刘平² 丁壮¹ 高宇峰¹ 曹彦南¹ 许艳华³ 朱房勇¹

¹江南大学附属医院口腔科，无锡　214000；²江南大学无锡医学院，无锡　214000；³云南省口腔医院正畸科，昆明　650101

通讯作者: 朱房勇，Email：4645056@163.com
基金资助:
国家自然科学基金（81960195）；无锡市卫计委面上项目（M202240）；无锡市卫生健康委中青年拔尖人才（HB2023054）；江南大学附属医院临床研究与转化医学研究项目（LCYJ202223、LCYJ202346）

Abstract

Abstract:

The plasticity and real-time performance of 3D printing resin are more advantageous than traditional resin and digital cutting resin, but its surface has inherent defects, such as graininess and stepped layers, and a rough surface is more conducive to bacterial colonization. How to effectively inhibit bacterial adhesion and reduce bacterial biofilm formation has become a clinical challenge, and this article provides a review on this.

Key words:

Surface modification, 3D printing resin, Antibacterial effect, Bacterial biofilm, Progress

摘要：

3D打印树脂的可塑性、即时性比传统树脂、数字切削树脂更有优势，但其表面存在颗粒感、阶梯层的先天缺陷，粗糙的表面更有利于细菌定植。如何有效抑制细菌黏附、减少细菌生物膜形成成了临床难点，本文就此作一综述。

关键词:

表面处理, 3D打印树脂, 抗菌作用, 细菌生物膜, 进展

Ma Hong, Hu Meichun, Yu Liuping, Ding Zhuang, Gao Yufeng, Cao Yannan, Xu Yanhua, Zhu Fangyong.

Research progress on surface treatment inhibiting bacterial biofilm formation on 3D printed resin surfaces [J]. International Medicine and Health Guidance News, 2024, 30(11): 1761-1765.

马红胡美纯于刘平丁壮高宇峰曹彦南许艳华朱房勇.

表面处理抑制3D打印树脂表面细菌生物膜形成的研究进展 [J]. 国际医药卫生导报, 2024, 30(11): 1761-1765.

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Research progress on surface treatment inhibiting bacterial biofilm formation on 3D printed resin surfaces

表面处理抑制3D打印树脂表面细菌生物膜形成的研究进展

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