应用微流控技术和纳米胶囊技术增强克林霉素对食源性病原菌的抑菌活性。

IF 3.9 2区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Scientific Reports Pub Date : 2025-02-13 DOI:10.1038/s41598-025-89955-5

Zinab Moradi Alvand, Masoud Rahimi, Liana Parseghian, Fatemeh Haji, Hasan Rafati

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引用次数: 0

摘要

食源性疾病通常是由制备或储存过程中的微生物污染引起的。以薄荷精油（MEO）为纳米载体，制备了稳定的克林霉素纳米乳。采用响应面法优化克林霉素纳米乳配方的关键变量，分别为表面活性剂用量为4.83、2.83和0.14%w/w、精油用量为0.14%w/w、克林霉素用量为0.14%w/w。对平均粒径为75.46±3.2 nm的MEO/克林霉素纳米乳（MEO/C NE）的稳定性进行了3个月的监测。采用常规方法和微流控芯片对MEO/C NE和散装化合物对大肠杆菌的抑菌活性进行了比较。与传统技术相比，微流控芯片的抗菌活性有显著差异，这可能是由于纳米液滴与细菌膜之间的高接触面积。在微流控芯片中，大肠杆菌在30 min内被完全抑制，而传统方法需要3 h才能完全抑制。本研究结果强调了纳米乳传递系统对提高克林霉素的抗菌活性的重要性，以及微流控技术作为一种快速可靠的技术来检测抗生素和纳米传递系统对微生物的作用。

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Application of microfluidic technology and nanoencapsulation to amplify the antibacterial activity of clindamycin against a food born pathogen.

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Application of microfluidic technology and nanoencapsulation to amplify the antibacterial activity of clindamycin against a food born pathogen.

Foodborne illnesses are often caused by microbial contamination during preparation or storage. In this work, stable nanoemulsions of clindamycin were prepared using Mentha piperita essential oil (MEO) as a nanocarrier delivery system. Response Surface Methodology was used to optimize the key variables for clindamycin nanoemulsion formulation, including 4.83, 2.83, and 0.14%w/w surfactant, essential oil, and clindamycin, respectively. The stability of MEO/clindamycin nanoemulsion (MEO/C NE) with a mean droplet size of 75.46 ± 3.2 nm was monitored over 3 months. The antibacterial activity of MEO/C NE and bulk compounds against E. coli bacterium was compared using a conventional method and a microfluidic chip. A significant difference in the antibacterial activity was observed by employing a microfluidic chip as compared to the conventional technique, probably due to a high contact surface area between the nanodroplets and bacterial membrane. In the microfluidic chip, the E. coli was completely inhibited in 30 min, whereas 3 h was needed for complete inhibition using the conventional method. The results of this study highlight the significance of nanoemulsion delivery systems to improve the antimicrobial activity of clindamycin and also microfluidic technology as a fast and reliable technique for examining antibiotics and nano delivery systems against microorganisms.

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来源期刊

Scientific Reports Natural Science Disciplines-

CiteScore

7.50

自引率

4.30%

发文量

19567

审稿时长

3.9 months

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