Liquid-liquid phase separated microdomains of an amphiphilic graft copolymer in a surfactant-rich medium

凝聚 共聚物 乙二醇 两亲性 肺表面活性物质 化学工程 材料科学 胶束 PEG比率 离子键合 相(物质) 高分子化学 化学 色谱法 聚合物 有机化学 水溶液 复合材料 离子 工程类 经济 财务
作者
Xavier Castellvi Corrons,Jérémie Gummel,Johan Smets,Debora Berti
出处
期刊:Journal of Colloid and Interface Science [Elsevier BV]
卷期号:615: 807-820 被引量:3
标识
DOI:10.1016/j.jcis.2022.02.020
摘要

The liquid-liquid phase separation (LLPS) of amphiphilic thermoresponsive copolymers can lead to the formation of micron-sized domains, known as simple coacervates. Due to their potential to confine active principles, these copolymer-rich droplets have gained interest as encapsulating agents. Understanding and controlling the conditions inducing this LLPS is therefore essential for applicative purposes and requires thorough fundamental studies on self-coacervation. In this work, we investigate the LLPS of a comb-like graft copolymer (PEG-g-PVAc) consisting of a poly(ethylene glycol) backbone (6 kDa) with ∼2–3 grafted poly(vinyl acetate) chains, and a PEG/PVAc weight ratio of 40/60. Specifically, we report the effect of various water-soluble additives on its phase separation behavior. Kosmotropes and non-ionic surfactants were found to decrease the phase separation temperature of the copolymer, while chaotropes and, above all, ionic surfactants increased it. We then focus on the phase behavior of PEG-g-PVAc in the presence of sodium citrate and a C14-15 E7 non-ionic surfactant (N45-7), defining the compositional range for the generation of LLPS microdomains at room temperature and monitoring their formation with fluorescence confocal microscopy. Finally, we determine the composition of the microdomains through confocal Raman microscopy, demonstrating the presence of PEG-g-PVAc, N45-7, and water. These results expand our knowledge on polymeric self-coacervation, clarifying the optimal conditions and composition needed to obtain LLPS microdomains with encapsulation potential at room temperature in surfactant-rich formulations.
最长约 10秒,即可获得该文献文件

科研通智能强力驱动
Strongly Powered by AbleSci AI
科研通是完全免费的文献互助平台,具备全网最快的应助速度,最高的求助完成率。 对每一个文献求助,科研通都将尽心尽力,给求助人一个满意的交代。
实时播报
1秒前
执着的海发布了新的文献求助10
1秒前
科目三应助佳雪儿采纳,获得10
1秒前
专注雁桃发布了新的文献求助10
1秒前
格格巫发布了新的文献求助10
2秒前
Samuel应助阿标采纳,获得20
2秒前
赘婿应助科研通管家采纳,获得10
2秒前
2秒前
隐形曼青应助科研通管家采纳,获得10
2秒前
2秒前
香蕉觅云应助科研通管家采纳,获得10
2秒前
2秒前
2秒前
Kao应助科研通管家采纳,获得10
2秒前
ding应助科研通管家采纳,获得10
2秒前
天天快乐应助科研通管家采纳,获得10
2秒前
思源应助科研通管家采纳,获得10
3秒前
molihuakai应助科研通管家采纳,获得10
3秒前
英姑应助科研通管家采纳,获得10
3秒前
3秒前
ding应助科研通管家采纳,获得10
3秒前
思源应助科研通管家采纳,获得30
3秒前
在水一方应助科研通管家采纳,获得10
3秒前
英俊的铭应助科研通管家采纳,获得10
3秒前
3秒前
SciGPT应助科研通管家采纳,获得10
3秒前
搜集达人应助科研通管家采纳,获得10
3秒前
3秒前
3秒前
4秒前
FashionBoy应助科研通管家采纳,获得10
4秒前
Avalonx应助科研通管家采纳,获得10
4秒前
英俊的铭应助科研通管家采纳,获得10
4秒前
JamesPei应助科研通管家采纳,获得10
4秒前
大模型应助lllll采纳,获得10
4秒前
满意青曼完成签到,获得积分10
4秒前
开放元灵发布了新的文献求助10
5秒前
5秒前
机智访琴发布了新的文献求助10
6秒前
专注雁桃完成签到,获得积分10
6秒前
高分求助中
(应助此贴封号)【重要!!请各用户(尤其是新用户)详细阅读】【科研通的精品贴汇总】 10000
48V Low-voltage Power Distribution Network (PDN) Architecture Industry Report, 2024 800
Fundamentals of Pharmaceutical and Biologics Regulations: A Global Perspective, Second Edition 700
Matrix Methods in Data Mining and Pattern Recognition Second Edition 610
适配Micro-LED色转换的高兼容性量子点负性光刻胶制备与工艺研究 500
Direct and Iterative Linear System Solvers 500
Vander's Renal Physiology第10版 500
热门求助领域 (近24小时)
化学 材料科学 医学 生物 纳米技术 工程类 有机化学 化学工程 生物化学 计算机科学 内科学 物理 复合材料 催化作用 细胞生物学 无机化学 光电子学 物理化学 电极 基因
热门帖子
关注 科研通微信公众号,转发送积分 7306601
求助须知:如何正确求助?哪些是违规求助? 8924480
关于积分的说明 18909193
捐赠科研通 6969558
什么是DOI,文献DOI怎么找? 3212451
关于科研通互助平台的介绍 2381085
邀请新用户注册赠送积分活动 2189985