海藻酸钠/POSS有机-无机杂化中空微囊的制备与性能
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摘要
以一种水溶性的阳离子型多面体低聚倍半硅氧烷(POSS)代替传统的氯化钙凝固浴,通过滴制法与海藻酸钠(SA)制备了SA/POSS有机-无机杂化微囊,并对其结构与性能进行了表征。FT-IR、XRD、SEM、TG及溶胀实验结果表明:POSS和SA之间存在较强的静电作用力,POSS的引入降低了SA分子排列的有序性,SA/POSS有机-无机杂化微囊为非晶态结构。微囊的外壁最为致密,从外到内结构逐渐变得疏松直至内部中空;微囊的热稳定性优于海藻酸钠。SA/POSS中空微囊在去离子水和HCl溶液中很快达到溶胀平衡,平衡溶胀比分别为17.2%~33.1%和15.9%~20.3%;而在PBS缓冲液中会破碎直至溶解。
A water-soluble cationic polyhedral oligomeric silsesquioxane(POSS) instead of the traditional calcium chloride coagulation bath was employed together with sodium alginate(SA) to prepare a series of hybrid organic and inorganic microcapsules(SA/POSS) via dropping method. The structure and properties of the obtained SA/POSS microcapsules were also characterized. It could be found from the results of FT-IR, XRD, SEM, TG and swelling experiment that a strong electrostatic interaction exist between POSS and SA. The introduction of POSS wea-kened the ordered arrangement of SA molecules, and SA/POSS organic-inorganic hybrid microcapsules presented amorphous structure. Speci-fically, the microcapsules possessed a compact outer wall and a hollow interior, with the structure gradually become looser from outside to inside. In addition, SA/POSS microcapsules show superior thermal stability to SA. The SA/POSS hollow microcapsules could reach swelling equilibrium in deionized water and HCl solution quickly, with the equilibrium swelling ratios of 17.2%—33.1% and 15.9%—20.3%, respectively, while they would break in PBS buffer and finally dissolved.
A water-soluble cationic polyhedral oligomeric silsesquioxane(POSS) instead of the traditional calcium chloride coagulation bath was employed together with sodium alginate(SA) to prepare a series of hybrid organic and inorganic microcapsules(SA/POSS) via dropping method. The structure and properties of the obtained SA/POSS microcapsules were also characterized. It could be found from the results of FT-IR, XRD, SEM, TG and swelling experiment that a strong electrostatic interaction exist between POSS and SA. The introduction of POSS wea-kened the ordered arrangement of SA molecules, and SA/POSS organic-inorganic hybrid microcapsules presented amorphous structure. Speci-fically, the microcapsules possessed a compact outer wall and a hollow interior, with the structure gradually become looser from outside to inside. In addition, SA/POSS microcapsules show superior thermal stability to SA. The SA/POSS hollow microcapsules could reach swelling equilibrium in deionized water and HCl solution quickly, with the equilibrium swelling ratios of 17.2%—33.1% and 15.9%—20.3%, respectively, while they would break in PBS buffer and finally dissolved.
引文
1 Lu W,Gao S,Wang J.Journal of Physical Chemistry C,2008,112(43),16792.
2 Taqieddin E,Amiji M.Biomaterials,2004,25(10),1937.
3 Mazumder M A,Burke N A,Shen F,et al.Biomacromolecules,2009,10(6),1365.
4 Chen H R,Zou X H,Min-Zhi M A.Chinese Journal of Applied Chemistry,2007,24(12),1354.
5 Hua S,Wang A.Carbohydrate Polymers,2009,75(1),79.
6 M?rch A,Donati I,Strand B L.Biomacromolecules,2006,7(5),1471.
7 G?ser?d O,Smidsr?d O,Skj?k-Br?k G.Biomaterials,1998,19(20),1815.
8 Lee K Y,Park W H,Ha W S.Journal of Applied Polymer Science,2015,63(4),425.
9 Chandy T,Mooradian D L,Rao G H R.Journal of Applied Polymer Science,2015,70(11),2143.
10 Zhao Q,Han B,Wang Z,et al.Nanomedicine Nanotechnology Biology & Medicine,2007,3(1),63.
11 Feher F J,Wyndham K D.Chemical Communications,1998,3(3),323.
12 Gravel M C,Zhang C,Dinderman M,et al.Applied Organometallic Chemistry,2010,13(4),329.
2 Taqieddin E,Amiji M.Biomaterials,2004,25(10),1937.
3 Mazumder M A,Burke N A,Shen F,et al.Biomacromolecules,2009,10(6),1365.
4 Chen H R,Zou X H,Min-Zhi M A.Chinese Journal of Applied Chemistry,2007,24(12),1354.
5 Hua S,Wang A.Carbohydrate Polymers,2009,75(1),79.
6 M?rch A,Donati I,Strand B L.Biomacromolecules,2006,7(5),1471.
7 G?ser?d O,Smidsr?d O,Skj?k-Br?k G.Biomaterials,1998,19(20),1815.
8 Lee K Y,Park W H,Ha W S.Journal of Applied Polymer Science,2015,63(4),425.
9 Chandy T,Mooradian D L,Rao G H R.Journal of Applied Polymer Science,2015,70(11),2143.
10 Zhao Q,Han B,Wang Z,et al.Nanomedicine Nanotechnology Biology & Medicine,2007,3(1),63.
11 Feher F J,Wyndham K D.Chemical Communications,1998,3(3),323.
12 Gravel M C,Zhang C,Dinderman M,et al.Applied Organometallic Chemistry,2010,13(4),329.