抗菌化疗药物的纳米制剂

RAN Pub Date : 2016-04-01 DOI:10.11159/NDDTE16.2
J. Jampílek
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引用次数: 0

摘要

细菌感染是日益严重的世界性威胁。20世纪50年代以后,由于抗菌剂的引入,无法治愈的疾病的数量减少了。然而,自20世纪80年代以来,发病率再次上升,呼吸道感染、艾滋病和结核病造成的死亡率目前约占世界感染死亡率的85%[1,2]。新感染人数的增加是由于普遍免疫抑制(主要是肿瘤治疗、使用免疫抑制剂、广谱抗生素和皮质激素)、糖尿病或艾滋病毒阳性患者人数的显著增加以及对常用药物产生耐药性造成的。在过去十年中,常见病原体对首选药物的耐药性增加了100%。此外,可以发现一些菌株对第二或第三选择药物具有耐药性。交叉耐药或多重耐药菌株(分枝杆菌、葡萄球菌、肠球菌、沙门氏菌、假单胞菌、克雷伯氏菌、念珠菌、曲霉和隐球菌)的产生是一个很大的问题[3,4]。耐药微生物的产生主要是由于人类、兽药和农业中不合理和无效地使用抗菌药物造成的[1,5 - 8]。细菌耐药性可能会使感染的治疗复杂化,无论这些感染在早期是多么轻微[9]。这些耐多药菌株引起的感染造成了额外医疗费用的增加和生产力损失[3,4,7,10]。虽然发现杀微生物剂并不困难,但设计适合合理开发的新型抗菌化合物变得越来越复杂[11],因此新型抗菌药物的研发意味着风险,因此许多制药公司继续开发仿制药物。细菌耐药性的增加是设计新的有效抗菌药物的紧迫性[12-14]。纳米技术的应用是改进现有抗菌药物的一个很好的选择。纳米材料是治疗和减轻耐药菌株引起的感染的另一种方法。微生物细胞不太可能对纳米材料产生耐药性,因为与传统抗生素相比,纳米材料通过多种机制发挥毒性[15]。利用纳米系统/纳米制剂,可以提高活性物质的生物利用度,并且可以修改给药途径。特定的纳米制剂也提供了一个受控的释放系统或目标生物分布。由于这些事实,可以使用更少的物质,即剂量依赖性毒性和各种副作用减少。可以通过固定剂量的药物组合或抗微生物活性基质来确保提高单个药物的效力,这些基质是物理上破坏生物体细胞膜并使其失效的聚合物,可用于预防产生耐药微生物。此外,许多配方还保护药物免受降解[16-22]。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Nanoformulations of Antimicrobial Chemotherapeutics
Bacterial infections represent an increasing worldwide threat. The number of untreatable diseases decreased after the 1950s due to the introduction of antimicrobial agents. However, since the 1980s, morbidity has risen again, and mortality due to respiratory infections, AIDS and tuberculosis now represents about 85% of world mortality from infections [1,2]. The increase in the number of new infections is caused by general immunosuppression (primarily by tumour treatment, administration of immunosuppressive agents, wide-spectrum antibiotics and corticoids), a significant increase in the number of diabetic or HIV-positive patients and development of resistance to commonly used drugs. The resistance of common pathogens to first-choice drugs increased by up to 100% during the last decade. Moreover, the resistance of some strains to secondor third-choice drugs can be found. Development of cross-resistant or multidrug-resistant strains (Mycobacterium spp., Staphylococcus, Enterococcus, Salmonella, Pseudomonas, Klebsiella, Candida spp., Aspergillus spp. and Cryptococcus spp.) is a great problem [3,4]. Selection of resistant microorganisms is especially caused by irrational and unavailing application of antimicrobial agents in human, veterinary medicine and in agriculture [1,5–8]. Bacterial resistance may complicate the treatment of infections regardless of how mild these infections were at the early stage [9]. Infections caused by these MDR bacterial strains have been responsible for the increase in additional healthcare costs and productivity losses [3,4,7,10]. Although it is not difficult to discover microbicidal agents, it is increasingly complicated to design new classes of antimicrobial compounds suitable for following rational development [11], therefore R&D of new antimicrobials imply risks, and thus many pharmaceutical originators have continued in development of me-too drugs. Increasing bacterial resistance refers to the urgency to design new effective antibacterial drugs [12–14]. Application of nanotechnology represents an excellent alternative for improvement of existing antimicrobial drugs. Nanomaterials are an alternative approach to treatment and mitigation of infections caused by resistant strains. Microbial cells are unlikely to develop resistance to nanomaterials, because, in contrast to conventional antibiotics, they exert toxicity through various mechanisms [15]. Using nanosystems/nanoformulations, enhanced bioavailability of active substance can be ensured, and the route of administration can be modified. Specific nanoformulations also provide a controlled released system or targeted biodistribution. Due to these facts, smaller amount of substance can be used, i.e. dose-dependent toxicity and various side effects decrease. An increase in the efficacy of individual agents can be ensured by fixed-dose drug combinations or antimicrobially active matrices – polymers physically destroying cell membranes of the organism and rendering them ineffective that could be applied in the prevention of developing drug-resistance microbes. In addition, many formulations also protect drugs from degradation [16–22].
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