有针对性地开发和优化用于生物系统低温保存的小分子冰重结晶抑制剂(IRIs)。

IF 1 4区 生物学 Q3 BIOLOGY Cryo letters Pub Date : 2024-03-01
L E McMunn, E M Walsh, R N Ben
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引用次数: 0

摘要

尽管生物材料的冷冻保存已成为常规储存方法,但由于不受控制的冰生长所造成的损害,其结果往往并不理想(包括解冻后的存活率、恢复能力和功能性降低)。包括二甲基亚砜(DMSO)在内的传统冷冻保护剂(CPAs)无法防止冰生长造成的损害,而对 CPA 细胞毒性的担忧又促使人们对开发改良型 CPAs 和冷冻保护策略的兴趣与日俱增。天然抗冻(糖)蛋白[AF(G)Ps]可抑制冰的再结晶,从而改善低温保存效果,但这些物质的冰结合特性及其大规模生产的挑战性使其成为不理想的 CPA 候选物质。因此,开发和应用生物相容性小分子冰重结晶抑制剂(IRIs)作为 CPAs 是一个值得实现的目标。对 AF(G)Ps 的广泛结构-活性关系研究发现,简单的碳水化合物衍生物可以抑制冰的再结晶。后来人们发现,这种活性可以通过微妙地平衡分子的疏水性和亲水性来进行微调。新一代小分子 IRI 经过精心设计,可避免与冰表面结合,随后进行的生物测试(细胞毒性和低温保存效果)表明,几种细胞类型的低温保存效果显著改善。然而,要充分发挥 IRIs 作为 CPA 的潜力,还需要一种针对特定细胞的个性化方法来同时评估多种低温保存结果。本文详细概述了基于碳水化合物的小分子 IRIs 的发展情况,并强调了在评估冷冻结果时必须考虑的关键细胞特异性生物学因素。https://doi.org/10.54680/fr24210110112。
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Targeted development and optimization of small-molecule ice recrystallization inhibitors (IRIs) for the cryopreservation of biological systems.

Despite the routine use of cryopreservation for the storage of biological materials, its outcomes are often sub-optimal (including reduced post-thaw viability, recovery, and functionality) due to the damage caused by uncontrolled ice growth. Traditional cryoprotective agents (CPAs), including dimethyl sulfoxide (DMSO), fail to prevent damage caused by ice growth and concerns over CPA cytotoxicity have fostered an increased interest in developing improved CPAs and cryoprotection strategies. The inhibition of ice recrystallization by natural antifreeze (glyco)proteins [AF(G)Ps] to improve cryopreservation outcomes has been examined; however, the ice binding properties of these substances and their challenging large-scale production make them poor CPA candidates. Therefore, the development and deployment of biocompatible, small-molecule ice recrystallization inhibitors (IRIs) for use as CPAs is a worthwhile objective. Extensive structure-activity relationship studies on AF(G)Ps revealed that simple carbohydrate derivatives could inhibit ice recrystallization. It was later discovered that this activity could be fine-tuned by delicately balancing the molecule's hydrophobicity and hydrophilicity. Current generation small-molecule IRIs have been meticulously designed to avoid binding to the surface of ice and subsequent biological testing (for both cytotoxicity and cryopreservation efficacy) has demonstrated significant improvements to the cryopreservation outcomes of several cell types. However, an individualized cell-specific approach for the simultaneous assessment of multiple cryopreservation outcomes is necessary to realize the full potential of IRIs as CPAs. This article provides a detailed overview of the development of small-molecule carbohydrate-based IRIs and highlights the crucial cell-specific biological considerations that must be taken into account when assessing cryopreservation outcomes. https://doi.org/10.54680/fr24210110112.

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来源期刊
Cryo letters
Cryo letters 生物-生理学
CiteScore
1.80
自引率
10.00%
发文量
50
审稿时长
1 months
期刊介绍: A bimonthly international journal for low temperature sciences, including cryobiology, cryopreservation or vitrification of cells and tissues, chemical and physical aspects of freezing and drying, and studies involving ecology of cold environments, and cold adaptation The journal publishes original research reports, authoritative reviews, technical developments and commissioned book reviews of studies of the effects produced by low temperatures on a wide variety of scientific and technical processes, or those involving low temperature techniques in the investigation of physical, chemical, biological and ecological problems.
期刊最新文献
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