氟醚磷酸胆碱的合成及性能研究

doi:10.6023/A23090430

摘要/Abstract

磷酸胆碱是一类两性型表面活性剂, 在生物领域被广泛应用. 当把它的疏水部分由碳氢链段替换为含氟链段时, 磷酸胆碱表面活性剂的界面性质会呈现出明显差异. 将含氟链段引入到磷酸胆碱中丰富了它的种类拓展了它的应用. 本工作合成了一种氟醚磷酸胆碱表面活性剂, 在含氟链段中插入氧原子, 使含氟链段更加多样化. 对氟醚磷酸胆碱的表面活性、泡沫性能及润湿性能进行了一系列探究, 实验结果表明, 氟醚磷酸胆碱具有低表面张力、泡沫性能好、可在聚四氟乙烯(PTFE)上润湿等优点, 是一类具有良好应用前景的表面活性剂.

关键词: 氟醚表面活性剂, 磷酸胆碱, 表面张力, 临界胶束浓度, 泡沫, 接触角

Amphoteric phosphocholine as a family of mild surfactants are widely used in biology due to their phosphate structure related to naturally occurring membrane lipids. Changing its hydrophobic part to the fluorocarbon counterparts, it was found that the interfacial properties of phosphocholine surfactants exhibit significant differences. Currently, the research on fluorinated phosphocholine surfactants is limited and lacks types of fluorinated hydrophobic structures. We found that oxygen atoms exhibit specificity in fluorinated surfactants in our previous works. In this work, a kind of phosphocholine containing a fluoroether hydrophobic chain was synthesized, and its interfacial properties, foam properties, and wetting properties were studied. At the beginning, we conducted a substitution reaction using fluoroether alcohols and 2-chloro-2-oxo-1,3,2-dioxaphospholane as raw materials, triethylamine as a base, and tetrahydrofuran (THF) as a solvent under ice bath. Then, the intermediate C72-P is obtained through distillation, which is a transparent viscous liquid with a yield of 70%. The next step is to dissolve the C72-P with trimethylamine (2 mol/L in THF) in acetonitrile at 70 ℃ for 48 h. Finally, a fluoroether phosphocholine surfactant was obtained and purified through column chromatography to give C72-MPB in 90% yield. Under the same conditions, a fluorinated linear phosphocholine surfactant 6:2-MPB was prepared using perfluorohexyl ethanol, which is a white solid with a overall yield of 60%. The phosphocholine fluorinated surfactants C72-MPB and 6:2-MPB were diluted with distilled water to obtain various concentrations of solutions, the surface properties were measured by surface tension instrument Krüss K100C, and the surface tension was measured by Wilhelmy platinum plate method. On the other hand, the performance of foam under two different concentrations of C72-MPB was tested by bubbling method, and the morphology of foam was observed. C72-MPB solution was dropped onto the surface of polytetrafluoroethylene (PTFE), contact angle on PTFE was measured, and its wettability at different time was recorded. The results show that the new fluoroether phosphocholine surfactant has good solubility, low surface tension, good wettability, good foam stability. Fluoroether phosphocholine surfactants have potential utility value in the field of life sciences and medicine. It is a kind of surfactant with excellent application prospects.

Key words: fluoroether surfactants, phosphocholine, surface tension, critical micelle concentration, foam, contact angle

引用此文

廖晨宇, 郭山巍, 黄美薇, 郭勇, 陈庆云, 刘超, 张运文. 氟醚磷酸胆碱的合成及性能研究[J]. 化学学报, 2024, 82(1): 46-52.

Chenyu Liao, Shanwei Guo, Meiwei Huang, Yong Guo, Qing-Yun Chen, Chao Liu, Yunwen Zhang. Synthesis and Properties of Fluoroether Phosphocholine[J]. Acta Chimica Sinica, 2024, 82(1): 46-52.

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图/表 12

图1. 代表性磷酸胆碱和本文合成的氟醚磷酸胆碱的结构

Figure 1. Structure of representative phosphocholine and fluoroether phosphocholine synthesized in this work

图2. C72-MPB磷酸胆碱的合成

Figure 2. Synthesis of C72-MPB phosphocholine

Entry^a	n(1)∶n(C72-OH) (molar ratio)	Time/h	Conversion of 1^b/%
1	1∶1	2	50
2	1.5∶1	2	78
3	2∶1	2	100
4	2∶1	1	72

表1. 第一步反应条件筛选

Table 1. Selection of the optimum condition of the first step reaction

Compound	γ_cmc/(mN•m^-1)	cmc/		Ref.
Compound	γ_cmc/(mN•m^-1)	(mmol•L^-1)	(g•L^-1)	Ref.
	22.6	2.1	1.1	本文
	28.7	21.0	9.6	[2]
	22.1	0.6	0.3	[2]
	18.1	0.11	0.07	[2]

表2. 文献中报道的磷酸胆碱表面活性剂

Table 2. Phosphocholine surfactants reported in literature

图3. 6:2-MPB和C72-MPB的γ-lg c曲线

Figure 3. γ-lg c curves for 6:2-MPB and C72-MPB

Compound	γ_cmc/(mN•m^-1)	cmc/		Γ_max/(×10^-10 mol•cm^-2)	A_min/nm²	T/℃
Compound	γ_cmc/(mN•m^-1)	(mmol•L^-1)	(g•L^-1)	Γ_max/(×10^-10 mol•cm^-2)	A_min/nm²	T/℃
6:2-MPB	22.6	2.1	1.1	4.5	0.4	25.0
C72-MPB	17.1	2.0	1.1	1.6	1.1	25.0

表3. 磷酸胆碱氟表面活性剂的表面活性数据

Table 3. Surface activity data of phosphocholine fluorosurfactants

浓度/(g•L^-1)	α	t_FLS75%/s	t_FVS50%/s	F/(mL•s)	M̅B̅A̅_initial/µm²	M̅B̅A̅_{10000 s}/µm²
1	3.27	40.1	11775 (54%)	1.9×10⁶	1.6×10⁴	2.4×10⁶
2	3.47	45.3	8215	1.4×10⁶	1.1×10⁴	2.9×10⁶

表4. C72-MPB的泡沫性能参数

Table 4. Foam performance parameters of C72-MPB

图4. 表面活性剂水溶液中泡沫性能的表征. (a)泡沫高度的比较. (b)泡沫体积比较. (c)表面活性剂中液体含量的比较. (d)平均气泡面积的比较

Figure 4. Characterization of foam properties in aqueous surfactant solutions. (a) Comparison of foam heights. (b) Comparison of foam volumes. (c) Comparison of liquid content in surfactants. (d) Comparison of the average bubble area

图5. (a) 1 g/L C72-MPB和(b) 2 g/L C72-MPB表面活性剂溶液从泡沫峰值高度后的不同时间的泡沫形态

Figure 5. Foam morphology of (a) 1 g/L C72-MPB and (b) 2 g/L C72-MPB surfactant solutions at different times after the foam peak height

图6. 1 g/L的C72-MPB水溶液在PTFE上不同时间的润湿状态

Figure 6. Wetting image of 1 g/L C72-MPB aqueous solution on PTFE at different time

图7. C72-MPB热通量随温度的变化

Figure 7. The heat flow of the C72-MPB varies with temperature

图8. C72-MPB重量百分比随温度的变化

Figure 8. The weight percentage of the C72-MPB changes with temperature

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