将疏水性作为一种工具,对酶响应性聚合物双亲化合物的顺序介相转变进行编程。

Shahar Tevet, Roey J Amir
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引用次数: 0

摘要

在自然界的许多系统中,聚合物组装体都具有可编程的级联介相转换能力,其结构和功能特征紧密结合,从而最大限度地提高了活性。在这项研究中,我们考察了通过微调两亲性成分的疏水性来编程共组装酶响应型聚合物胶束的介相转变速率的能力。我们利用二嵌段和三嵌段两亲化合物对酶降解的不同反应活性,将其作为一种工具,对配方进行编程,使其在酶诱导下依次从胶束过渡到水凝胶,最后过渡到溶解聚合物。通过改变 PEG-dendron双嵌段和三嵌段双亲化合物的脂肪族末端基团,我们可以证明对双嵌段双亲化合物的结构和疏水性稍加改动就能显著影响不同介相之间的转变速度,从几小时到一周不等。此外,该研究还揭示了改变其两亲成分的相对疏水性如何影响配方比例和酶选择性,以及所得水凝胶的稳定性和降解率。研究结果强调了分子结构和疏水性作为设计可编程酶响应聚合物组合物关键参数的重要性,为精确控制多步介相转变以实现定制功能提供了见解。
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Hydrophobicity as a tool for programming sequential mesophase transitions of enzyme-responsive polymeric amphiphiles.

The ability of polymeric assemblies to undergo programmable cascades of mesophase transitions is prevalent in many systems in nature, where structural and functional features are tightly bound to maximize activity. In this study, we have examined the ability to program the mesophase transition rates of co-assembled enzyme-responsive polymeric micelles, through fine adjustments of the hydrophobicity of their amphiphilic components. We have utilized the different reactivities of di- and tri-block amphiphiles toward enzymatic degradation as a tool for programming formulations to undergo sequential enzymatically induced transitions from micelles to hydrogels and finally to dissolved polymers. By varying the aliphatic end-groups of PEG-dendron di-block and tri-block amphiphiles, we could demonstrate the remarkable impact of minor modifications to the di-block amphiphiles' structure and hydrophobicity on the transition rates between the different mesophases, ranging from a few hours to a week. Additionally, the study reveals how altering the relative hydrophobicity of its amphiphilic components influences the formulation ratio and enzymatic selectivity, as well as the stability and degradation rate of the resulting hydrogels. The findings underscore the importance of molecular architecture and hydrophobicity as key parameters in the design of programmable enzyme-responsive polymeric assemblies, offering insights into the ability to precisely control multi-step mesophase transitions for tailored functionality.

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来源期刊
Journal of materials chemistry. B
Journal of materials chemistry. B 化学科学, 工程与材料, 生命科学, 分析化学, 高分子组装与超分子结构, 高分子科学, 免疫生物学, 免疫学, 生化分析及生物传感, 组织工程学, 生物力学与组织工程学, 资源循环科学, 冶金与矿业, 生物医用高分子材料, 有机高分子材料, 金属材料的制备科学与跨学科应用基础, 金属材料, 样品前处理方法与技术, 有机分子功能材料化学, 有机化学
CiteScore
12.00
自引率
0.00%
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审稿时长
1 months
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