In vitro antimicrobial activity of silver nanoparticles against selected Gram-negative and Gram-positive pathogens.

Q2 Medicine
Medicine and Pharmacy Reports Pub Date : 2024-07-01 Epub Date: 2024-07-30 DOI:10.15386/mpr-2750
Michaela Corina Crisan, Stanca Lucia Pandrea, Luminita Matros, Teodora Mocan, Lucian Mocan
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By combining silver nanoparticles with different classes of antibiotics, the antibacterial effect is evidenced by increased values of the inhibition zone compared to the values obtained for some antibiotics commonly used in the treatment of bacterial infections. This study focuses on comparing the antibacterial activity of antibiotics versus antibiotics combined with silver nanoparticles against various bacteria, by comparing inhibition zones obtained for both. We aim to prove that the size of the inhibition zone for antibiotics combined with silver nanoparticles is greater, thus confirming the improved antibacterial effect.</p><p><strong>Metods: </strong>In this study we tested the antibacterial activity of solutions of silver nanoparticles alone or in combination with different antibiotics. 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引用次数: 0

Abstract

Background and aim: Infections caused by pathogenic bacteria increase patient morbidity and mortality and significantly raise treatment costs. The use of silver nanoparticles as an alternative treatment for S aureus, E coli, MRSA, E faecalis, K pneumoniae and P aeruginosa indicates their antibacterial effect and prompts medical research to consider the next generation of antibacterial drugs that could change antibiotic therapy. By combining silver nanoparticles with different classes of antibiotics, the antibacterial effect is evidenced by increased values of the inhibition zone compared to the values obtained for some antibiotics commonly used in the treatment of bacterial infections. This study focuses on comparing the antibacterial activity of antibiotics versus antibiotics combined with silver nanoparticles against various bacteria, by comparing inhibition zones obtained for both. We aim to prove that the size of the inhibition zone for antibiotics combined with silver nanoparticles is greater, thus confirming the improved antibacterial effect.

Metods: In this study we tested the antibacterial activity of solutions of silver nanoparticles alone or in combination with different antibiotics. We used standard bacterial strains, ATCC, both Gram positive bacteria Staphylococcus aureus ATCC 29213, Enterococcus faecalis ATCC 29212, as well as Gram negative bacteria Escherichia coli ATCC 25922, Pseudomonas aeruginosa ATCC 27853, but also on clinical isolates: a strain MRSA (Methicillin Resistant Staphylococcus aureus) and a PDR strain (pan drug resistant) of Klebsiella pneumoniae. Bacterial identification was performed using Vitek MS analyzer (bioMerieux). Antibiotic susceptibility determination was performed with VITEK2 COMPACT SYSTEM (bio Merieux, Inc Durham NC) with ready to use VITEK AST cards. The interpretation of the results was done in compliance with EUCAST 2023-2024 standards. Testing was performed for several classes of antibiotics, silver nanoparticle solutions in 2 concentrations (10 μg/mL and 100 μg/mL) and for combinations of antibiotics with silver nanoparticle solutions. The diameter of the inhibition zone (ZOI) for silver nanoparticles, antibiotics and silver nanoparticles combined with antibiotic against each bacterium was expressed in millimeters. The Kirby-Bauer disk-diffusion method, in accordance with current EUCAST standards, was used to analyze the antibacterial effect of antibiotics, silver nanoparticles, and antibiotics combined with silver nanoparticles at biocompatible doses of 10 and 100 μg/mL. The experiments were conducted in triplicate, and the results were almost identical.

Results: The results of this study show that the silver nanoparticles displayed antibacterial activity, proven by the appearance of the inhibition zone, in various sizes, for all bacteria studied. The antibiotic classes tested were beta-lactamins, first, second, third and fourth generation cephalosporins, macrolides, fluoroquinolones, lincosamides, aminoglycosides, glycopeptides, tetracyclines, oxazolidinones, sulfonamides, rifamycins, amphenicols. Testing S aureus ATCC 29213, the highest zone of inhibition was demonstrated for cephalosporins (32.6667 ± 0.701 mm), macrolides (31.6667 ± 0.701 mm, and lincosamides (29.6667 ± 0.701 mm). Testing MRSA (internal code GR0333), the highest zone of inhibition for combination of silver nanoparticles and antibiotics was demonstrated for fluoroquinolones (36.3333 ± 0.701 mm), lincosamides (32.3333 ± 0.701 mm), Fusid acid (32.3333 ± 0.701 mm) and aminoglicosides (31.3333 ± 0.701 mm). Testing E coli ATCC 25922 the highest zone of inhibition was for Fosfomycine, 39 mm and for E faecalis ATCC 29212 for aminoglicosides was 19 mm. For K pneumoniae (internal code GQ8575) the inhibition zone for silver nanoparticles 100 μg/mL was 12.3333 ± 0.701 mm and for P aeruginosa ATCC 27253 was 16 ± 1.214 mm.

Conclusions: The use of metallic nanoparticles, especially silver ones, as antimicrobial agents with definite bactericidal activity has led medical specialists to consider this new treatment which may change antibacterial therapy. Studies of in vitro combinations between silver nanoparticles and different classes of antibiotics represent a highly efficient and effective new antibacterial treatment against multidrug-resistant bacteria. To avoid the problem of antimicrobial resistance associated with conventional antibiotics, it is necessary to understand the adaptive mechanisms of bacteria under the action of metal nanoparticles, which could be exploited in future studies. Further in vitro and in vivo studies that would assess specify the biocompatibility and toxicity of silver nanoparticles will make these super nanomaterials the medicines of the future.

银纳米粒子对某些革兰氏阴性和革兰氏阳性病原体的体外抗菌活性。
背景和目的:病原菌引起的感染会增加患者的发病率和死亡率,并大幅提高治疗成本。使用银纳米粒子作为金黄色葡萄球菌、大肠杆菌、MRSA、粪大肠杆菌、肺炎双球菌和铜绿假单胞菌的替代治疗方法,表明了其抗菌效果,并促使医学研究考虑下一代抗菌药物,从而改变抗生素疗法。通过将纳米银粒子与不同种类的抗生素相结合,与治疗细菌感染常用的一些抗生素相比,纳米银粒子的抑菌区值增大,从而证明了其抗菌效果。本研究的重点是通过比较抗生素和抗生素与纳米银粒子的抑菌区,比较两者对各种细菌的抗菌活性。我们的目的是证明抗生素与纳米银粒子结合后的抑菌区更大,从而证实其抗菌效果更好:在这项研究中,我们测试了银纳米粒子溶液单独或与不同抗生素结合的抗菌活性。我们使用了 ATCC 标准细菌菌株,包括革兰氏阳性菌金黄色葡萄球菌 ATCC 29213 和粪肠球菌 ATCC 29212,以及革兰氏阴性菌大肠埃希菌 ATCC 25922 和铜绿假单胞菌 ATCC 27853,还使用了临床分离菌株:耐甲氧西林金黄色葡萄球菌 MRSA 菌株和肺炎克雷伯菌 PDR 菌株(泛耐药菌)。细菌鉴定使用 Vitek MS 分析仪(生物梅里埃)进行。抗生素敏感性测定使用 VITEK2 COMPACT 系统(bio Merieux, Inc Durham NC)和即用型 VITEK AST 卡进行。检测结果的解释符合 EUCAST 2023-2024 标准。测试对象包括几类抗生素、两种浓度的纳米银溶液(10 μg/mL 和 100 μg/mL)以及抗生素与纳米银溶液的组合。银纳米粒子、抗生素以及银纳米粒子与抗生素的组合对每种细菌的抑菌区直径(ZOI)以毫米为单位。根据现行的欧盟标准,采用柯比-鲍尔盘扩散法分析抗生素、纳米银微粒以及抗生素与纳米银微粒复配在生物相容性剂量为 10 和 100 μg/mL 时的抗菌效果。实验一式三份,结果基本一致:研究结果表明,银纳米粒子具有抗菌活性,对所有研究细菌都有不同大小的抑制区。测试的抗生素种类包括:β-内酰胺类,第一、第二、第三和第四代头孢菌素类,大环内酯类,氟喹诺酮类,林可酰胺类,氨基糖苷类,糖肽类,四环素类,噁唑烷酮类,磺胺类,利福霉素类,安非他酮类。在检测金黄色葡萄球菌 ATCC 29213 时,头孢菌素类(32.6667 ± 0.701 毫米)、大环内酯类(31.6667 ± 0.701 毫米)和林可霉素类(29.6667 ± 0.701 毫米)的抑菌区最大。在检测 MRSA(内部代码 GR0333)时,氟喹诺酮类(36.3333 ± 0.701 毫米)、林可酰胺类(32.3333 ± 0.701 毫米)、夫西地酸(32.3333 ± 0.701 毫米)和氨基糖苷类(31.3333 ± 0.701 毫米)的银纳米颗粒与抗生素的组合抑制区最大。在检测大肠杆菌 ATCC 25922 时,福斯明的抑菌区最大,为 39 毫米;在检测粪肠杆菌 ATCC 29212 时,氨基糖苷的抑菌区为 19 毫米。对于肺炎双球菌(内部代码 GQ8575),银纳米粒子 100 μg/mL 的抑制区为 12.3333 ± 0.701 毫米,对于铜绿假单胞菌 ATCC 27253 的抑制区为 16 ± 1.214 毫米:使用金属纳米粒子,尤其是银纳米粒子作为具有明确杀菌活性的抗菌剂,促使医学专家考虑采用这种可能改变抗菌疗法的新疗法。对纳米银粒子与不同种类抗生素的体外组合研究表明,这是一种高效、有效的新型抗菌疗法,可用于抗击耐多药细菌。为了避免与传统抗生素相关的抗菌药耐药性问题,有必要了解细菌在金属纳米粒子作用下的适应机制,以便在今后的研究中加以利用。进一步的体外和体内研究将明确评估银纳米粒子的生物相容性和毒性,这将使这些超级纳米材料成为未来的药物。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Medicine and Pharmacy Reports
Medicine and Pharmacy Reports Medicine-Medicine (all)
CiteScore
3.10
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