Antibiotics Coupled with Photothermal Therapy for the Enhanced Killing of Bacteria.

IF 0.5
Journal of Biochemical Technology Pub Date : 2023-01-01 Epub Date: 2023-09-26 DOI:10.51847/nplvoycg9u
Amanda Jalihal, Armin Mortazi, Mavis Forson, Mujeebat Bashiru, Thuy Le, Adeniyi Oyebade, Noureen Siraj
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Abstract

In this study, the application of ionic materials as a combination antibiotic drug was investigated. The fluoroquinolone, Norfloxacin, was converted into the ionic form and combined with the cationic dye, IR780+, using an ion-exchange reaction. The resulting ionic combination drug possesses two killing mechanisms in one compound. The antibiotic chemical mechanism along with the photothermal mechanism that was acquired by adding IR780 to the compound led to the development of a combination antibiotic drug. This ionic combination drug consisting of Norfloxacin anion and IR780 cation is easily dispersed in water using sonication waves. The parent compounds and ionic combination drug, dissolved in organic solvent and dispersed in water, were characterized, and the photophysical properties were studied in detail. It was discovered that the aqueous ionic combination drugs exhibited significant changes in absorbance and photoluminescent properties. In aqueous media, the dispersed ionic combination drug exhibited a very broad absorbance with an additional peak around 1000 nm which is advantageous in photothermal. A significant decrease in the quantum yield along with enhanced non-radiative rate constant was observed for the combination drug in the aqueous. The photothermal mechanism is present in both the parent IR780 dye and the ionic combination drug. The ionic combination drug displayed a high light-to-heat conversion efficiency and temperature increase similar to the parent dye. The combination of both killing mechanisms in the ionic combination drug resulted in enhanced antibacterial activity against Escherichia coli as compared to the parent Norfloxacin and IR780-I individually.

抗生素与光热疗法相结合,增强杀灭细菌的效果。
本研究探讨了离子材料作为复合抗生素药物的应用。利用离子交换反应将氟喹诺酮诺氟沙星转化为离子形式,并与阳离子染料 IR780+ 结合。由此产生的离子组合药物在一个化合物中具有两种杀菌机制。抗生素化学机制以及通过在化合物中添加 IR780 而获得的光热机制,促成了抗生素复方药物的开发。这种由诺氟沙星阴离子和 IR780 阳离子组成的离子组合药物很容易通过超声波分散在水中。研究人员对溶解在有机溶剂中并分散在水中的母体化合物和离子组合药物进行了表征,并详细研究了其光物理性质。研究发现,水性离子组合药物的吸光度和光致发光特性发生了显著变化。在水介质中,分散的离子组合药物表现出非常宽的吸光度,并在 1000 纳米附近出现一个额外的峰值,这在光热方面具有优势。在水介质中,组合药物的量子产率明显下降,非辐射速率常数增强。母体 IR780 染料和离子组合药物都存在光热机制。离子组合药物显示出较高的光热转换效率,温度升高与母体染料相似。与母体诺氟沙星和 IR780-I 相比,离子组合药物中两种杀菌机制的结合增强了对大肠杆菌的抗菌活性。
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
Journal of Biochemical Technology
Journal of Biochemical Technology BIOCHEMISTRY & MOLECULAR BIOLOGY-
自引率
40.00%
发文量
18
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