Biomimetic nanomaterials for pulmonary infections: A prospective view in drug delivery systems

IF 3.674 4区 工程技术 Q1 Engineering
Nagarajan Usharani, Swarna V. Kanth, Natarajan Saravanan
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引用次数: 0

Abstract

Respiratory infections are quite challenging due to their complexity in ailments and composition of viral genetic material and their rate of proliferation. In particular, the eradication of viral illness is still a concern, irrespective of advancements in prevention and remedial procedures. The nature of the viral particle with the possibility of rapid transmission is prone to attach on the deposited surface for days together. This antigen expulses due to sneezing or coughing resulted in multiphase turbulent flow, contaminates the surroundings and is carried away by simple touch or inhalation and find newer hosts for instance, SARSCoV-2 aerosols remain viable for about an hour leading to infection. The present review focuses on the remedial aspects of respiratory infections through a knowledge-based approach towards nanosystems. The complete understanding of standard antiviral drugs and the remodelling of these drugs through nanosystems still is the need of the hour. The genetic material and epidemiology of viral antigen, help in redefining standard drugs along with nanocarriers to achieve more feasible and hour-based approach. The main goal of this review is to elaborate on the repurposing of existing standard antiviral drugs and ways to accelerate their mode of action to promote a feasible and hour-based approach. The consolidated three-dimensional approaches aimed at sustained, targeted and optimized levels of drug concentration in the circulating system along with bioactive nanocarriers which could effectively pass the cell membrane were reported. The platforms for nanomaterial evolution depend on nature of source, size, structure, and their unique functionalities (Stable, speedy, and long-lasting recovery procedure). However, the research activities and literature on coronavirus have been overwhelming but the information on the sustainability of nanotherapy in SARS-CoV-2 is still in the developmental stage. Hereby, the clinical aspects of SARS-CoV-2 and the eradication strategy developed for antiviral infections through nanotechnology will pave the way ahead for treating upcoming new variants or other pandemics.

Abstract Image

用于肺部感染的仿生纳米材料:药物输送系统的前瞻性观点
呼吸道感染由于其疾病和病毒遗传物质的组成及其增殖速度的复杂性而具有相当的挑战性。特别是,尽管预防和补救程序取得了进展,但根除病毒性疾病仍然是一个令人关切的问题。具有快速传播可能性的病毒颗粒的性质是易于在沉积表面附着数天。这种抗原因打喷嚏或咳嗽而排出,导致多相湍流,污染周围环境,并通过简单的触摸或吸入被带走,并找到新的宿主。例如,SARSCoV-2气溶胶可存活约一个小时,导致感染。目前的综述主要集中在通过基于知识的纳米系统治疗呼吸道感染方面。完全了解标准抗病毒药物和通过纳米系统重塑这些药物仍然是当务之急。病毒抗原的遗传物质和流行病学,有助于重新定义标准药物以及纳米载体,以实现更可行和基于小时的方法。本综述的主要目的是阐述现有标准抗病毒药物的再利用和加速其作用方式的方法,以促进可行的和基于小时的方法。本文报道了针对循环系统中持续、靶向和优化的药物浓度水平以及可有效通过细胞膜的生物活性纳米载体的综合三维方法。纳米材料进化的平台取决于来源的性质、大小、结构和它们独特的功能(稳定、快速和持久的恢复过程)。然而,关于冠状病毒的研究活动和文献已经铺天盖地,但关于纳米疗法在SARS-CoV-2中的可持续性的信息仍处于发展阶段。因此,SARS-CoV-2的临床方面和通过纳米技术为抗病毒感染制定的根除策略将为治疗即将到来的新变种或其他大流行病铺平道路。
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来源期刊
Applied Nanoscience
Applied Nanoscience Materials Science-Materials Science (miscellaneous)
CiteScore
7.10
自引率
0.00%
发文量
430
期刊介绍: Applied Nanoscience is a hybrid journal that publishes original articles about state of the art nanoscience and the application of emerging nanotechnologies to areas fundamental to building technologically advanced and sustainable civilization, including areas as diverse as water science, advanced materials, energy, electronics, environmental science and medicine. The journal accepts original and review articles as well as book reviews for publication. All the manuscripts are single-blind peer-reviewed for scientific quality and acceptance.
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