Exploring Dynamics and Structure of Biomolecules, Cryoprotectants, and Water Using Molecular Dynamics Simulations: Implications for Biostabilization and Biopreservation.

IF 12.8 1区 工程技术 Q1 ENGINEERING, BIOMEDICAL
Lindong Weng, Shannon L Stott, Mehmet Toner
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引用次数: 48

Abstract

Successful stabilization and preservation of biological materials often utilize low temperatures and dehydration to arrest molecular motion. Cryoprotectants are routinely employed to help the biological entities survive the physicochemical and mechanical stresses induced by cold or dryness. Molecular interactions between biomolecules, cryoprotectants, and water fundamentally determine the outcomes of preservation. The optimization of assays using the empirical approach is often limited in structural and temporal resolution, whereas classical molecular dynamics simulations can provide a cost-effective glimpse into the atomic-level structure and interaction of individual molecules that dictate macroscopic behavior. Computational research on biomolecules, cryoprotectants, and water has provided invaluable insights into the development of new cryoprotectants and the optimization of preservation methods. We describe the rapidly evolving state of the art of molecular simulations of these complex systems, summarize the molecular-scale protective and stabilizing mechanisms, and discuss the challenges that motivate continued innovation in this field.

Abstract Image

Abstract Image

Abstract Image

利用分子动力学模拟探索生物分子、冷冻保护剂和水的动力学和结构:对生物稳定和生物保存的影响。
成功的稳定和保存生物材料通常利用低温和脱水来阻止分子运动。冷冻保护剂通常用于帮助生物实体在寒冷或干燥引起的物理化学和机械应力中生存。生物分子、冷冻保护剂和水之间的分子相互作用从根本上决定了保存的结果。使用经验方法的分析优化通常受到结构和时间分辨率的限制,而经典的分子动力学模拟可以提供具有成本效益的原子水平结构和单个分子的相互作用,这些相互作用决定了宏观行为。对生物分子、冷冻保护剂和水的计算研究为开发新的冷冻保护剂和优化保存方法提供了宝贵的见解。我们描述了这些复杂系统的分子模拟技术的快速发展状态,总结了分子尺度的保护和稳定机制,并讨论了激励该领域持续创新的挑战。
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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来源期刊
Annual Review of Biomedical Engineering
Annual Review of Biomedical Engineering 工程技术-工程:生物医学
CiteScore
18.80
自引率
0.00%
发文量
14
期刊介绍: Since 1999, the Annual Review of Biomedical Engineering has been capturing major advancements in the expansive realm of biomedical engineering. Encompassing biomechanics, biomaterials, computational genomics and proteomics, tissue engineering, biomonitoring, healthcare engineering, drug delivery, bioelectrical engineering, biochemical engineering, and biomedical imaging, the journal remains a vital resource. The current volume has transitioned from gated to open access through Annual Reviews' Subscribe to Open program, with all articles published under a CC BY license.
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