Drug loading methods and kinetic release models using of mesoporous silica nanoparticles as a drug delivery system: A review

Q1 Social Sciences
Ali H. Khalbas , Talib M. Albayati , Nisreen S. Ali , Issam K. Salih
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引用次数: 0

Abstract

Oral drug administration remains one of the most convenient routes due to its Simplicity, high patient compliance, and cost-effectiveness. However, many medicinal products available on the market exhibit poor water solubility, which adversely affects the dissolution rate of drugs in biological fluids. Drug loading is a promising strategy to produce highly stable amorphous drugs with improved dissolution rates, solubility, and bioavailability. Mesoporous silica nanoparticles (MSNs) are particularly advantageous due to their tunable surface area, pore size, and pore volume, making them suitable to load various molecules such as drugs, genes, and proteins. The use of mathematical models is crucial for predicting and analyzing the release profile of active molecules and diffusion patterns within delivery systems. This enables the design and development of new systems with more desirable release patterns. This review provides an overview of MSNs and drug loading methods, discusses the mechanisms of drug release and release kinetic models using mesoporous carriers, and highlights critical considerations in designing MSNs, such as particle stability and cytotoxicity.

Abstract Image

使用介孔二氧化硅纳米颗粒作为给药系统的药物负载方法和动力学释放模型:综述
口服给药因其简便、患者依从性高和成本效益高而一直是最方便的给药途径之一。然而,市场上许多药品的水溶性较差,这对药物在生物液体中的溶解率产生了不利影响。药物负载是生产高度稳定的无定形药物的一种有前途的策略,可提高药物的溶解率、溶解度和生物利用率。介孔二氧化硅纳米颗粒(MSNs)因其可调的表面积、孔径和孔体积而特别具有优势,使其适合负载各种分子,如药物、基因和蛋白质。数学模型的使用对于预测和分析活性分子的释放曲线以及递送系统内的扩散模式至关重要。这有助于设计和开发具有更理想释放模式的新系统。本综述概述了 MSNs 和药物负载方法,讨论了药物释放机制和使用介孔载体的释放动力学模型,并强调了设计 MSNs 的关键考虑因素,如颗粒稳定性和细胞毒性。
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来源期刊
CiteScore
8.40
自引率
0.00%
发文量
100
审稿时长
33 weeks
期刊介绍: The journal has a particular interest in publishing papers on the unique issues facing chemical engineering taking place in countries that are rich in resources but face specific technical and societal challenges, which require detailed knowledge of local conditions to address. Core topic areas are: Environmental process engineering • treatment and handling of waste and pollutants • the abatement of pollution, environmental process control • cleaner technologies • waste minimization • environmental chemical engineering • water treatment Reaction Engineering • modelling and simulation of reactors • transport phenomena within reacting systems • fluidization technology • reactor design Separation technologies • classic separations • novel separations Process and materials synthesis • novel synthesis of materials or processes, including but not limited to nanotechnology, ceramics, etc. Metallurgical process engineering and coal technology • novel developments related to the minerals beneficiation industry • coal technology Chemical engineering education • guides to good practice • novel approaches to learning • education beyond university.
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