Pathogen‐binding nanoparticles to inhibit host cell infection by heparan sulfate and sialic acid dependent viruses and protozoan parasites

A. Najer
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Abstract

Global health faces an immense burden from infectious diseases caused by viruses and intracellular protozoan parasites such as the coronavirus disease (COVID‐19) and malaria, respectively. These pathogens propagate through the infection of human host cells. The first stage of this host cell infection mechanism is cell attachment, which typically involves interactions between the infectious agent and surface components on the host cell membranes, specifically heparan sulfate (HS) and/or sialic acid (SA). Hence, nanoparticles (NPs) which contain or mimic HS/SA that can directly bind to the pathogen surface and inhibit cell infection are emerging as potential candidates for an alternative anti‐infection therapeutic strategy. These NPs can be prepared from metals, soft matter (lipid, polymer, and dendrimer), DNA, and carbon‐based materials among others and can be designed to include aspects of multivalency, broad‐spectrum activity, biocidal mechanisms, and multifunctionality. This review provides an overview of such anti‐pathogen nanomedicines beyond drug delivery. Nanoscale inhibitors acting against viruses and obligate intracellular protozoan parasites are discussed. In the future, the availability of broadly applicable nanotherapeutics would allow early tackling of existing and upcoming viral diseases. Invasion inhibitory NPs could also provide urgently needed effective treatments for protozoan parasitic infections.
病原体结合纳米粒子,抑制硫酸肝素和硅铝酸依赖性病毒和原生动物寄生虫对宿主细胞的感染
全球健康面临着由病毒和细胞内原生动物寄生虫(如冠状病毒病(COVID-19)和疟疾)引起的传染性疾病所带来的巨大负担。这些病原体通过感染人类宿主细胞进行传播。这种宿主细胞感染机制的第一阶段是细胞附着,通常涉及感染病原体与宿主细胞膜表面成分(特别是硫酸肝素(HS)和/或硅酸(SA))之间的相互作用。因此,含有或模拟 HS/SA 的纳米粒子(NPs)可直接与病原体表面结合并抑制细胞感染,正在成为另一种抗感染治疗策略的潜在候选药物。这些 NPs 可由金属、软物质(脂质、聚合物和树枝状聚合物)、DNA 和碳基材料等制备而成,其设计可包括多价性、广谱活性、杀菌机制和多功能性等方面。本综述概述了此类抗病原纳米药物在药物递送之外的作用。文中讨论了对病毒和细胞内原生动物寄生虫起作用的纳米级抑制剂。未来,广泛适用的纳米治疗药物的出现将有助于尽早解决现有和即将出现的病毒性疾病。抑制入侵的 NPs 还能为原生动物寄生虫感染提供急需的有效治疗。
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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