石墨烯纳米复合材料在牙科诊所空气消毒中的效果：一项随机对照研究。

Efficacy of graphene nanocomposites for air disinfection in dental clinics: A randomized controlled study.

作者信息

Ju Ya-Qiong, Yu Xiang-Hua, Wu Jing, Hu Ying-Hui, Han Xiang-Yong, Fang Dan

机构信息

Department of Nursing, Minhang District Dental Clinic, Shanghai 201107, China.

Department of Medical Sciences, Minhang District Dental Clinic, Shanghai 201107, China.

出版信息

World J Clin Cases. 2024 Oct 6;12(28):6173-6179. doi: 10.12998/wjcc.v12.i28.6173.

DOI:10.12998/wjcc.v12.i28.6173

PMID:39371570

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11362895/

Abstract

BACKGROUND

Aerosols containing disease-causing microorganisms are produced during oral diagnosis and treatment can cause secondary contamination.

AIM

To investigate the use of graphene material for air disinfection in dental clinics by leveraging its adsorption and antibacterial properties.

METHODS

Patients who received ultrasonic cleaning at our hospital from April 2023 to April 2024. They were randomly assigned to three groups ( = 20 each): Graphene nanocomposite material suction group (Group A), ordinary filter suction group (Group B), and no air suction device group (Group C). The air quality and air colony count in the clinic rooms were assessed before, during, and after the procedure. Additionally, bacterial colony counts were obtained from the air outlets of the suction devices and the filter screens in Groups A and B.

RESULTS

Before ultrasonic cleaning, no significant differences in air quality PM and colony counts were observed among the three groups. However, significant differences in air quality PM and colony counts were noted among the three groups during ultrasonic cleaning and after ultrasonic treatment. Additionally, the number of colonies on the exhaust port of the suction device and the surface of the filter were significantly lower in Group A than in Group B ( = 0.000 and = 0.000, respectively).

CONCLUSION

Graphene nanocomposites can effectively sterilize the air in dental clinics by exerting their antimicrobial effects and may be used to reduce secondary pollution.

摘要

背景

口腔诊断和治疗过程中产生的含有致病微生物的气溶胶可导致二次污染。

目的

利用石墨烯材料的吸附和抗菌特性，研究其在牙科诊所空气消毒中的应用。

方法

选取2023年4月至2024年4月在我院接受超声洁治的患者。将他们随机分为三组（每组n = 20）：石墨烯纳米复合材料抽吸组（A组）、普通滤网抽吸组（B组）和无空气抽吸装置组（C组）。在操作前、操作期间和操作后评估诊室内的空气质量和空气菌落数。此外，还从A组和B组的抽吸装置出风口和滤网获取细菌菌落数。

结果

超声洁治前，三组空气质量PM和菌落数无显著差异。然而，在超声洁治期间和超声治疗后，三组空气质量PM和菌落数存在显著差异。此外，A组抽吸装置排气口和滤网表面的菌落数显著低于B组（分别为P = 0.000和P = 0.000）。

结论

石墨烯纳米复合材料可通过发挥抗菌作用有效对牙科诊所空气进行消毒，可用于减少二次污染。

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