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用于规避生物膜以有效治疗念珠菌性外阴阴道炎的计算机辅助纳米制剂策略

In Silico Guided Nanoformulation Strategy for Circumvention of Biofilm for Effective Therapy of Candidal Vulvovaginitis.

作者信息

Hassan Nazia, Farooq Uzma, Das Ayan Kumar, Sharma Kalicharan, Mirza Mohd Aamir, Fatima Suhail, Singh Omana, Ansari Mohammad Javed, Ali Asgar, Iqbal Zeenat

机构信息

Department of Pharmaceutics, School of Pharmaceutical Education & Research (SPER), Jamia Hamdard, New Delhi 110062, India.

Hamdard Institute of Medical Sciences & Research, Jamia Hamdard, New Delhi 110062, India.

出版信息

ACS Omega. 2023 Feb 10;8(7):6918-6930. doi: 10.1021/acsomega.2c07718. eCollection 2023 Feb 21.

DOI:10.1021/acsomega.2c07718
PMID:36844532
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9947946/
Abstract

Candidal vulvovaginitis involving multispecies of and epithelium-bound biofilm poses a drug-resistant pharmacotherapeutic challenge. The present study aims for a disease-specific predominant causative organism resolution for the development of a tailored vaginal drug delivery system. The proposed work fabricates a luliconazole-loaded nanostructured lipid carrier-based transvaginal gel for combating biofilm and disease amelioration. The interaction and binding affinity of luliconazole against the proteins of and biofilm were assessed using in silico tools. A systematic QbD analysis was followed to prepare the proposed nanogel using a modified melt emulsification-ultrasonication-gelling method. The DoE optimization was logically implemented to ascertain the effect of independent process variables (excipients concentration; sonication time) on dependent formulation responses (particle size; polydispersity index; entrapment efficiency). The optimized formulation was characterized for final product suitability. The surface morphology and dimensions were spherical and ≤300 nm, respectively. The flow behavior of an optimized nanogel (semisolid) was non-Newtonian similar to marketed preparation. The texture pattern of a nanogel was firm, consistent, and cohesive. The release kinetic model followed was Higuchi (nanogel) with a % cumulative drug release of 83.97 ± 0.69% in 48 h. The % cumulative drug permeated across a goat vaginal membrane was found to be 53.148 ± 0.62% in 8 h. The skin-safety profile was examined using a vaginal irritation model (in vivo) and histological assessments. The drug and proposed formulation(s) were checked against the pathogenic strains of (vaginal clinical isolates) and in vitro established biofilms. The visualization of biofilms was done under a fluorescence microscope revealing mature, inhibited, and eradicated biofilm structures.

摘要

涉及多种念珠菌以及上皮细胞结合生物膜的念珠菌性外阴阴道炎带来了耐药性药物治疗挑战。本研究旨在确定疾病特异性的主要致病生物体,以开发定制的阴道给药系统。拟开展的工作制备了一种负载卢立康唑的基于纳米结构脂质载体的经阴道凝胶,用于对抗生物膜并改善病情。使用计算机工具评估了卢立康唑与念珠菌及生物膜蛋白质的相互作用和结合亲和力。采用改良的熔融乳化 - 超声 - 胶凝法,遵循系统的质量源于设计(QbD)分析来制备拟议的纳米凝胶。合理实施实验设计(DoE)优化,以确定独立工艺变量(辅料浓度;超声时间)对相关制剂响应(粒径;多分散指数;包封率)的影响。对优化后的制剂进行最终产品适用性表征。其表面形态为球形,尺寸分别≤300 nm。优化后的纳米凝胶(半固体)的流动行为与市售制剂类似,呈非牛顿流体。纳米凝胶的质地模式紧实、一致且有粘性。遵循的释放动力学模型为Higuchi模型(纳米凝胶),48小时内药物累积释放率为83.97±0.69%。8小时内发现跨山羊阴道膜渗透的药物累积率为53.148±0.62%。使用阴道刺激模型(体内)和组织学评估检查皮肤安全性。针对念珠菌(阴道临床分离株)的致病菌株和体外建立的生物膜对药物和拟议的制剂进行检测。在荧光显微镜下观察生物膜,揭示成熟、受抑制和被根除的生物膜结构。

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Front Pharmacol. 2021 Sep 20;12:713616. doi: 10.3389/fphar.2021.713616. eCollection 2021.
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Design of experiments (DoE) to develop and to optimize nanoparticles as drug delivery systems.
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