通过3D打印和氧化锌纳米花实现的耐用抗菌微结构表面(DAMS)
Durable Antimicrobial Microstructure Surface (DAMS) Enabled by 3D-Printing and ZnO Nanoflowers.
作者信息
Yuqing Fnu, Zhang Shuhuan, Peng Ruonan, Silva Justin, Ernst Olivia, Lapizco-Encinas Blanca H, Liu Rui, Du Ke
机构信息
Department of Chemical and Environmental Engineering, University of California, Riverside, California 92521, United States.
Department of Mechanical Engineering, University of California, Riverside, California 92521, United States.
出版信息
Langmuir. 2025 Feb 11;41(5):3027-3032. doi: 10.1021/acs.langmuir.4c02764. Epub 2024 Nov 25.
Numerous studies have been trying to create nanomaterial-based antimicrobial surfaces to prevent infections due to bacterial growth. One major challenge in real-world applications of these surfaces is their mechanical durability. In this study, we introduce durable antimicrobial microstructure surface (DAMS), which integrates DLP 3D-printed microstructures with zinc oxide (ZnO) nanoflowers. The microstructures function as protection armor for the nanoflowers during abrasion. The antimicrobial ability was evaluated by immersing in 2E8 CFU/mL () suspension and then evaluated using electron microscopy. Our results indicated that DAMS reduced bacterial coverage by more than 90% after 12 h of incubation and approximately 50% after 48 h of incubation before abrasion. More importantly, bacterial coverage was reduced by approximately 50% after 2 min of abrasion with a tribometer, and DAMS remains effective even after 6 min of abrasion. These findings highlight the potential of DAMS as an affordable, scalable, and durable antimicrobial surface for various biomedical applications.
众多研究一直致力于制造基于纳米材料的抗菌表面,以防止因细菌生长而导致的感染。这些表面在实际应用中的一个主要挑战是其机械耐久性。在本研究中,我们引入了耐用抗菌微结构表面(DAMS),它将数字光处理(DLP)3D打印微结构与氧化锌(ZnO)纳米花相结合。在磨损过程中,这些微结构起到保护纳米花的铠甲作用。通过将其浸入2E8 CFU/mL()悬浮液中来评估抗菌能力,然后使用电子显微镜进行评估。我们的结果表明,在磨损前,DAMS在孵育12小时后细菌覆盖率降低了90%以上,孵育48小时后降低了约50%。更重要的是,用摩擦计摩擦2分钟后,细菌覆盖率降低了约50%,即使在摩擦6分钟后,DAMS仍然有效。这些发现凸显了DAMS作为一种适用于各种生物医学应用的经济实惠、可扩展且耐用的抗菌表面的潜力。
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