Leonny Dwi Rizkita, Rachma Greta Perdana Putri, Muhammad Farid, Muflihah Rizkawati, Pratiwi Wikaningtyas
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Abstract
Background
The increasing trend of antibiotic resistance has posed challenges for scientists, especially in developing better drug formulations. The discovery of new antibiotics could take years. Therefore, the management of an ideal drug delivery system has become a primary focus nowadays.
Main body of abstract
Almost all skin diseases could be treated with the administration of topical drugs, especially infectious skin diseases. The increasing cases of antimicrobial resistance require innovative strategies and actions. In dermatokinetics, achieving optimal drug concentrations in the deepest layers of skin tissue is a significant challenge. Human skin has remarkably complex characteristics, presenting a major obstacle in efficiently maintaining drug efficacy. Nanocarriers are an important part of nanomedicine which provide excellent drug penetration through various drug delivery systems. Lipid-based nanovesicles, such as liposome, are the oldest and most potential nanovesicles for such a purpose. Several studies have shown the efficacy of liposome-contained antibiotics and offered the lowest microbial inhibition concentration (MIC). It is suggested that liposome also delivers greater drug accumulation compared to blank drugs.
Short conclusion
Liposome is a flexible lipid-based drug delivery that enhances drug permeation through skin tissue by mimicking the lipid bilayer system of the organ. It is non-toxic, less immunogenic, and easily degraded by enzyme. The incorporation of liposome into antibiotics may reduce the inefficient drug dosage since the encapsulation will protect the active compounds prior to being released from the vehicle. Thus, the lowest MIC and less clinical side effects will be obtained.
背景抗生素耐药性不断增加的趋势给科学家带来了挑战,尤其是在开发更好的药物制剂方面。新抗生素的发现可能需要数年时间。摘要正文几乎所有皮肤病都可以通过局部用药治疗,尤其是传染性皮肤病。抗菌药耐药性的不断增加需要创新的策略和行动。在皮肤动力学中,如何在皮肤组织深层达到最佳药物浓度是一项重大挑战。人体皮肤具有非常复杂的特性,是有效保持药物疗效的一大障碍。纳米载体是纳米医学的重要组成部分,可通过各种给药系统提供出色的药物渗透性。脂质体等脂基纳米载体是最古老、最具潜力的纳米载体。多项研究表明,含有脂质体的抗生素疗效显著,微生物抑制浓度(MIC)最低。简短结论脂质体是一种基于脂质的灵活给药方式,它通过模拟器官的脂质双分子层系统来增强药物在皮肤组织中的渗透。它无毒、免疫原性低、易被酶降解。在抗生素中加入脂质体可以减少药物的低效用量,因为在活性化合物从载体中释放出来之前,脂质体的封装会对其起到保护作用。因此,可获得最低的 MIC 值和较少的临床副作用。
期刊介绍:
Beni-Suef University Journal of Basic and Applied Sciences (BJBAS) is a peer-reviewed, open-access journal. This journal welcomes submissions of original research, literature reviews, and editorials in its respected fields of fundamental science, applied science (with a particular focus on the fields of applied nanotechnology and biotechnology), medical sciences, pharmaceutical sciences, and engineering. The multidisciplinary aspects of the journal encourage global collaboration between researchers in multiple fields and provide cross-disciplinary dissemination of findings.
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