Shota Nakayama, Keishi Suga, Tatsuya Kamata, Kanako Watanabe, Hikaru Namigata, Tom A. J. Welling, Daisuke Nagao
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引用次数: 0
摘要
聚二乙炔(PDA)是一种可光聚合的聚合物,在热量、pH 值和溶剂等外界刺激下会呈现出独特的颜色转变。PDA 作为眼球探测刺激传感器具有极佳的时间性能,但其灵敏度有待提高。考虑到双乙炔(DA)囊泡具有类似生物膜的结构,通过加入膜脂质(如二酰基磷酸胆碱,PC)对其进行修饰可用于控制膜的流动性,从而控制囊泡中 DA 的分子排序。受生物膜系统的启发,我们利用脂质囊泡作为生成 PDA 的平台,并研究了影响 PDA 灵敏度的关键因素。通过降低聚合温度,PDA 的生成速度变慢,而灵敏度提高。通过以脂质:DA = 1:1 的摩尔比添加多氯化萘,可改变 PDA 的灵敏度:相变温度(Tm)较低的多氯化萘会使 PDA 变得不灵敏,而相变温度(Tm)较高的多氯化萘与纯聚 PCDA 相比则会提高灵敏度。结论是,膜流动性较低的 DAs 光聚合可诱导出高灵敏度的 PDA,而膜流动性较高的 DAs 光聚合可诱导出不灵敏的 PDA,并对刺激具有稳健性。
Bio‐Inspired Polydiacetylene Vesicles for Controlling Stimulus Sensitivity
Polydiacetylene (PDA) is a kind of photopolymerizable polymer, which exhibits a unique color transition in response to external stimuli such as heat, pH, and solvent. PDAs are attractive as eye‐detection stimulus sensors with excellent time performance; however, the sensitivity of PDAs should be improved. Considering the biological membrane‐like structure of diacetylene (DA) vesicles, their modification by incorporating membrane lipids (e.g., diacylphosphocholine, PC) can be used to control the membrane fluidity, and consequently molecular ordering of DAs in the vesicle. Inspired by biological membrane systems, lipid vesicles are employed as platforms to generate PDA, and essential factors that influence the sensitivity of PDA are investigated. By lowering the polymerization temperature, the generation of PDA becomes slower, while the sensitivity improves. By adding PCs at the molar ratio of lipid:DA = 1:1, the sensitivity of PDA can be varied: the PCs with lower phase transition temperatures (Tm) made PDA insensitive, while the PCs with higher Tm improved the sensitivity as compared to pure poly(PCDA). It is concluded that the photopolymerization of DAs with a lower membrane fluidity induces highly sensitive PDA, while the photopolymerization of DAs with a higher membrane fluidity induces insensitive PDA with robustness toward stimuli.
期刊介绍:
Macromolecular Reaction Engineering is the established high-quality journal dedicated exclusively to academic and industrial research in the field of polymer reaction engineering.