A review on potential drug delivery system as a treatment of intercellular bacterial infection

Journal of Pharmacovigilance and Drug Research Pub Date : 2020-12-01 DOI:10.53411/jpadr.2020.1.2.3

M. Manna, A. Shil

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Abstract

Introduction: Intracellular bacterial pathogens are hard to treat because of the inability of conventional antimicrobial agents belonging to widely used classes, like aminoglycosides and β-lactams, fluoroquinolones, or macrolides to penetrate, accumulate, or be retained in the mammalian cells. The increasing problem of antibiotic resistance complicates more the treatment of the diseases caused by these agents. Objectives: The purpose of this chapter is to present the limitations of each class of antibiotics in targeting intracellular pathogens and the main research directions for the development of drug delivery systems for the intracellular release of antibiotics. Methods: Different improved drug carriers have been developed for treating intracellular pathogens, including antibiotics loaded into liposomes, microspheres, polymeric carriers, and nanoplexes. Results: In many cases, the increase in therapeutic doses and treatment duration is accompanied by the occurrence of severe side effects. Taking into account the huge financial investment associated with bringing a new antibiotic to the market and the limited lifetime of antibiotics, the design of drug delivery systems to enable the targeting of antibiotics inside the cells, to improve their activity in different intracellular niches at different pH and oxygen concentrations, and to achieve a reduced dosage and frequency of administration could represent a prudent choice. An ideal drug delivery system should possess several properties, such as antimicrobial activity, biodegradability, and biocompatibility, making it suitable for use in biomedical and pharmaceutical formulations. Conclusions: This approach allow reviving old antibiotics rendered useless by resistance or toxicity, rescuing the last line therapy antibiotics by increasing the therapeutic index, widening the antimicrobial spectrum of antibiotics scaffolds that failed due to membrane permeability problems, and thus reducing the gap between increasingly drug-resistant pathogens and the development of new antibiotics.

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治疗细胞间细菌感染的潜在药物传递系统研究进展

细胞内细菌性病原体很难治疗，因为广泛使用的氨基糖苷类和β-内酰胺类、氟喹诺酮类或大环内酯类等常规抗菌药物无法渗透、积聚或保留在哺乳动物细胞中。日益严重的抗生素耐药性问题使这些药物引起的疾病的治疗更加复杂化。目的:本章的目的是介绍各类抗生素靶向细胞内病原体的局限性，以及抗生素细胞内释放给药系统发展的主要研究方向。方法:不同的改良药物载体已被开发用于治疗细胞内病原体，包括载于脂质体、微球、聚合物载体和纳米复合物中的抗生素。结果:在许多病例中，治疗剂量和治疗时间的增加伴随着严重副作用的发生。考虑到将新抗生素推向市场所需的巨额资金投入和抗生素有限的使用寿命，设计药物输送系统，使抗生素能够靶向细胞内的抗生素，在不同的pH值和氧浓度下提高其在不同细胞内生态位中的活性，并减少给药剂量和频率，可能是一种谨慎的选择。理想的药物传递系统应具有若干特性，如抗菌活性、生物降解性和生物相容性，使其适合用于生物医学和药物制剂。结论:该方法可以使因耐药或毒性而失效的旧抗生素复活，通过提高治疗指数挽救最后一线治疗抗生素，拓宽因膜透性问题而失效的抗生素支架的抗菌谱，从而缩短日益耐药的病原体与新抗生素开发之间的差距。

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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Journal of Pharmacovigilance and Drug Research

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