Design of a Zr-based metal–organic framework as an efficient fosfomycin carrier: a combined experimental and DFT study†

IF 2.5 3区化学 Q2 CHEMISTRY, MULTIDISCIPLINARY

New Journal of Chemistry Pub Date : 2022-12-01 DOI:10.1039/D2NJ05100A

Berna Topuz, Hakan Kayı, Toygun Şahin, Feriha Şevval Ersoy, Ayşe Günyaktı and Ayşe Karakeçili

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Abstract

Biomolecule carrier systems based on metal–organic frameworks (MOFs) are highly promising owing to a high degree of structural tunability, high surface area, porosity, and higher chemical/thermal stability. UiO-66, one of the most stable Zr_(IV)-based MOFs, has a pore aperture of 0.6 nm and a theoretical pore volume of 0.77 cm³ g^?1, ideal for high storage capacity of biomolecule cargo; however, its potential to be implemented as an efficient carrier for fosfomycin is yet to be investigated. The UiO-66 nanocrystal, synthesized at room temperature, as a fosfomycin carrier was reported. Drug modulated synthesis (in situ encapsulation) and post-synthesis (adsorption/impregnation) were applied to incorporate fosfomycin in and/or on UiO-66 nanocrystals. We determined the effect of room temperature synthesis conditions on the structural properties of the UiO-66 nanocrystals as a functional carrier for fosfomycin. The incorporation of fosfomycin either by encapsulation or adsorption did not change the inherent crystal structure and UiO-66 nanocrystals retained their morphology. The addition of fosfomycin into the reaction medium led to an increase in the particle size from 127 ± 45 nm to 203 ± 52 nm. Our FTIR results indicated the development of a Zr–O–P connection due to the capture of drug molecules by adsorption. Antibacterial activity studies unveiled the drug concentration dependent bactericidal and bacteriostatic activities towards S. aureus and E. coli for fosfomycin loaded UiO-66 nanocrystals. Investigations with the help of density functional theory were performed to reveal the interaction mechanism between fosfomycin and UiO-66. Our theoretical findings indicated that fosfomycin strongly interacts with the metal center in the defected UiO-66 through its oxygen atom in the phosphite group with a Zr–O distance of 2.087 ?. Additionally, the energy of interaction for the adsorption process was found to have a large negative value of ?74.3 kcal mol^?1, which supports the strong interaction between the two systems.

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zr基金属有机骨架作为磷霉素高效载体的设计:实验与DFT相结合的研究

基于金属-有机框架(mof)的生物分子载体系统具有高度的结构可调性、高表面积、孔隙度和更高的化学/热稳定性，因此具有很高的应用前景。UiO-66是最稳定的Zr(IV)基mof之一，孔径为0.6 nm，理论孔体积为0.77 cm3 g?1、适用于储存容量大的生物分子货物;然而，其作为磷霉素有效载体的潜力还有待研究。报道了室温合成的UiO-66纳米晶体作为磷霉素载体。采用药物调制合成(原位包封)和后合成(吸附/浸渍)将磷霉素掺入UiO-66纳米晶体中或表面。我们确定了室温合成条件对作为磷霉素功能载体的UiO-66纳米晶体结构性质的影响。无论是包封还是吸附，磷霉素的掺入都没有改变其固有的晶体结构，UiO-66纳米晶体保持原有的形态。在反应介质中加入磷霉素后，颗粒尺寸由127±45 nm增加到203±52 nm。我们的FTIR结果表明，由于吸附捕获药物分子，Zr-O-P连接的发展。抑菌活性研究揭示了磷霉素负载的UiO-66纳米晶体对金黄色葡萄球菌和大肠杆菌的抑菌活性与药物浓度有关。利用密度泛函理论研究磷霉素与UiO-66的相互作用机制。理论研究结果表明，磷霉素通过亚磷酸基上的氧原子与缺陷的UiO-66中的金属中心发生强烈的相互作用，其Zr-O距离为2.087 ?此外，吸附过程的相互作用能有一个很大的负值，为74.3 kcal mol?1，支持两个系统之间的强交互作用。

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