基于多两性离子的药物输送平台建模:当前最先进的观点和未来

IF 4.3 Q2 ENGINEERING, CHEMICAL ACS Engineering Au Pub Date : 2022-05-03 DOI:10.1021/acsengineeringau.2c00008
Sousa Javan Nikkhah*,  and , Matthias Vandichel, 
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引用次数: 8

摘要

药物输送平台预计具有生物相容性和生物惰性表面。药物载体的聚乙二醇化是最被认可的方法,因为它提高了水溶性和胶体稳定性,减少了药物载体与血液成分的相互作用。虽然这种方法扩展了它们的生物相容性,但生物识别机制阻止了它们的生物分布,从而阻碍了有效的药物转移。近年来的研究表明,(聚)两性离子是聚乙二醇的替代品,具有良好的生物相容性。(聚)两性离子具有超亲水性,以刺激反应为主,易于功能化,对蛋白质的吸附极低,生物分布时间长。这些独特的特性使它们成为药物输送载体的候选者。此外,由于它们具有具有相反符号的高密度带电基团,(聚)两性离子在生理条件下是高度水合的。这种特殊的水合电位使其成为设计具有防污能力的治疗载体的理想选择,即防止在药物输送载体中从人体吸收不需要的生物制剂。因此,(多)两性离子材料以其优异的生物相容性、低细胞毒性、不显著的免疫原性、高稳定性、循环时间长等优点,广泛应用于刺激反应型“智能”给药系统以及肿瘤靶向载体。为了定制(聚)两性离子药物载体,解释这种类型的聚合物的结构和刺激响应行为是必不可少的。为此,需要对(多)两性离子的分子水平相互作用、取向、构型和物理化学性质进行直接研究,这可以通过分子建模来实现,这已经成为发现新材料和理解各种材料现象的重要工具。分子模拟作为科学与工程之间的重要桥梁,使我们能够对智能载药(聚)两性离子纳米颗粒的包封和释放行为有基本的了解,并有助于我们系统地设计下一代纳米颗粒。当与实验相结合时,建模可以进行定量预测。这篇前瞻性的文章旨在说明(多)两性离子为基础的药物输送系统的最新进展。我们总结了如何使用预测多尺度分子建模技术来成功地促进智能多功能(多)两性离子系统的发展。
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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Modeling Polyzwitterion-Based Drug Delivery Platforms: A Perspective of the Current State-of-the-Art and Beyond

Drug delivery platforms are anticipated to have biocompatible and bioinert surfaces. PEGylation of drug carriers is the most approved method since it improves water solubility and colloid stability and decreases the drug vehicles’ interactions with blood components. Although this approach extends their biocompatibility, biorecognition mechanisms prevent them from biodistribution and thus efficient drug transfer. Recent studies have shown (poly)zwitterions to be alternatives for PEG with superior biocompatibility. (Poly)zwitterions are super hydrophilic, mainly stimuli-responsive, easy to functionalize and they display an extremely low protein adsorption and long biodistribution time. These unique characteristics make them already promising candidates as drug delivery carriers. Furthermore, since they have highly dense charged groups with opposite signs, (poly)zwitterions are intensely hydrated under physiological conditions. This exceptional hydration potential makes them ideal for the design of therapeutic vehicles with antifouling capability, i.e., preventing undesired sorption of biologics from the human body in the drug delivery vehicle. Therefore, (poly)zwitterionic materials have been broadly applied in stimuli-responsive “intelligent” drug delivery systems as well as tumor-targeting carriers because of their excellent biocompatibility, low cytotoxicity, insignificant immunogenicity, high stability, and long circulation time. To tailor (poly)zwitterionic drug vehicles, an interpretation of the structural and stimuli-responsive behavior of this type of polymer is essential. To this end, a direct study of molecular-level interactions, orientations, configurations, and physicochemical properties of (poly)zwitterions is required, which can be achieved via molecular modeling, which has become an influential tool for discovering new materials and understanding diverse material phenomena. As the essential bridge between science and engineering, molecular simulations enable the fundamental understanding of the encapsulation and release behavior of intelligent drug-loaded (poly)zwitterion nanoparticles and can help us to systematically design their next generations. When combined with experiments, modeling can make quantitative predictions. This perspective article aims to illustrate key recent developments in (poly)zwitterion-based drug delivery systems. We summarize how to use predictive multiscale molecular modeling techniques to successfully boost the development of intelligent multifunctional (poly)zwitterions-based systems.

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ACS Engineering Au
ACS Engineering Au 化学工程技术-
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期刊介绍: )ACS Engineering Au is an open access journal that reports significant advances in chemical engineering applied chemistry and energy covering fundamentals processes and products. The journal's broad scope includes experimental theoretical mathematical computational chemical and physical research from academic and industrial settings. Short letters comprehensive articles reviews and perspectives are welcome on topics that include:Fundamental research in such areas as thermodynamics transport phenomena (flow mixing mass & heat transfer) chemical reaction kinetics and engineering catalysis separations interfacial phenomena and materialsProcess design development and intensification (e.g. process technologies for chemicals and materials synthesis and design methods process intensification multiphase reactors scale-up systems analysis process control data correlation schemes modeling machine learning Artificial Intelligence)Product research and development involving chemical and engineering aspects (e.g. catalysts plastics elastomers fibers adhesives coatings paper membranes lubricants ceramics aerosols fluidic devices intensified process equipment)Energy and fuels (e.g. pre-treatment processing and utilization of renewable energy resources; processing and utilization of fuels; properties and structure or molecular composition of both raw fuels and refined products; fuel cells hydrogen batteries; photochemical fuel and energy production; decarbonization; electrification; microwave; cavitation)Measurement techniques computational models and data on thermo-physical thermodynamic and transport properties of materials and phase equilibrium behaviorNew methods models and tools (e.g. real-time data analytics multi-scale models physics informed machine learning models machine learning enhanced physics-based models soft sensors high-performance computing)
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