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碳纳米管复合微球修饰L-色氨酸及其对LDL的吸附性能 被引量:2

Modification Carbon Nanotubes Composite Beads by L-Tryptophan and Their Adsorption Capacity for Low Density Lipoprotein
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摘要 本文以多孔碳纳米管/活性炭复合微球为载体,以L-色氨酸为配基,采用环氧氯丙烷偶联法,制得修饰L-色氨酸的碳纳米管/活性炭复合微球(L-CNTs/AC).采用扫描电镜、氮气吸附、傅立叶红外光谱、热分析、X射线光电子能谱等对复合微球进行表征;通过体外静态吸附法对其低密度脂蛋白(LDL)吸附能力进行初步研究.结果表明:环氧氯丙烷偶联法可接枝上L-色氨酸.复合微球中碳纳米管加入量越多,对LDL的吸附能力越强;当碳纳米管加入量为45wt%时,对LDL的吸附量达4.623 mg·g-1,是未添加碳纳米管的2.3倍多.这是因为碳纳米管不仅可促进复合微球中20~100 nm孔的形成,而且还可促进复合微球配基修饰量的增多,从而大大增强了复合微球对LDL的吸附能力.此复合微球可望开发成一种新型的血液灌流LDL吸附剂. The porous carbon nanotubes (CNTs)/activated carbon composite beads were modified by L-tryptophan using epichlorohydrin coupling method. The composite beads were characterized by SEM, N2 adsorption, FTIR, TGA and XPS etc. Then these composite beads were applied to adsorb low density lipoprotein (LDL) by static adsorption experiment in vitro. The results show that the composite beads could be modified by L-tryptophan using epichlorohydrin coupling method. With the increase CNTs mass ratio, the adsorption capacity of LDL increase. When CNTs ratio is 45wt%, the adsorption amount of LDL reaches 4.623 mg-g-1, is 2.3 times as great as that of beads without CNTs. These should be ascribed to the highly developed 20-100 nm porous structures and the increase of L-tryptophan amount on the composite beads mainly brought about by CNTs, enhancing the LDL adsorption ability onto the composite beads greatly. So the composite beads have good prospects as LDL adsorbent in hemoperfusion.
作者 卢月美 巩前明 梁吉 聂庆东
机构地区 福州大学机械工程及自动化学院 清华大学机械工程系 清华大学校医院
出处 《无机化学学报》 SCIE CAS CSCD 北大核心 2013年第10期2034-2042,共9页 Chinese Journal of Inorganic Chemistry
基金 国家自然科学基金(No.50602026)资助项目
关键词 碳纳米管 复合微球 L-色氨酸 低密度脂蛋白 吸附 carbon nanotubes composite beads L-tryptophan low density lipoprotein adsorption
分类号 O613.71 [理学—无机化学] TQ424.2 [化学工程]
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参考文献45

  • 1Brown M S,Goldstein J L.Science,2006,311:1721-1723.
  • 2Rizzo M,Berneis K.Eur.J.Inter.Med.,2006,17:77-80.
  • 3WANG Jun-Jun(汪俊军),ZHANG Chun-Ni(张春妮),ZHUANG Yi-Yi(庄一义).Zhongguo DongmaiYinghua Zazhi,2007,15(6):473-475.
  • 4Bambauer R.Ther.Apher.Dial.,2005,9:142-147.
  • 5Thompson G R.A therosclerosis,2008,198:247-255.
  • 6Hevonoja T,Pentikinen M O,Hyvnen M T,et al.Biochim.Biophys.A ata,2000,1488:189-210.
  • 7Tasaki H,Yamashita K,Saito Y,et al.Ther.Apher.Dial.,2006,10(1):32-41.
  • 8Julius U,Parhofer K G,Heibges A,et al.J.Clin.Apher.,2007,22(4):215-223.
  • 9Wendler T,Schilling R,Lennertz A,et al.J.Clin.Apher.,2003,18(4):157-166.
  • 10Bosch T,Gahr S,Belschner U,et al.Ther.Apher.Dial.,2006,10(3):210-218.

共引文献1

同被引文献33

  • 1Yang S L, Chen C Y, Yan Z H, Cai Q Y, Yao S Z. Evaluation of metal-organic framework 5 as a new SPE material for the determination of polycyclic aromatic hydrocarbons in environmental waters [ J ]. Journal of Separation Science ,2013,36 ( 7 ) : 1283 - 1290.
  • 2Chert X F, Zang H, Wang X, Cheng J G, Zhao R S, Cheng C G, Lu X Q. Metal-organic framework MIL-53 (A1) as a soli&phase microextraction adsorbent for the determination of 16 polycyclic aromatic hydrocarbons in water samples by gas chromatography-tandem mass spectrometry[ J ]. Analyst, 2012, 137 ( 22 ) : 5411 - 5419.
  • 3Ge D, Lee H K. Water stability of zeolite imidazolate framework 8 and application to porous membrane- protected micro-solid-phase extraction of polycyclic aromatic hydrocarbons from environmental water samples [ J ]. Journal of Chromatography A, 2011,1218 ( 47 ): 8490 - 8495.
  • 4Zhou Y Y, Yan X P, Kim K N, Wang S W, Liu M G. Exploration of coordination polymer as sorbent for flow injection solid-phase extraction on-line coupled with high-performance liquid chromatography for determination of polycyclie aromatic hydrocarbons in environmental materials [ J 1. Journal of Chromatography A,2006, 1116(1 -2) :172 - 178.
  • 5Ahmad R, Wong-Foy A G, Matzger A J. Microporous coordination polymers as selective sorbents for liquid chromatography [ J ]. Langmuir, 2009, 25 ( 20 ) : 11977 - 11979.
  • 6Lee C Y, Bae Y S, Jeong N C, Farha O K, Sarjeant A A, Stern C L, Niekias P, Snurr R Q, Hupp J T, Nguyen S T. Kinetic separation of propene and propane in metal-organic frameworks: Controlling diffusion rates in plate-shaped crystals via tuning of pore apertures and crystallite aspect ratios [ J 1. Journal of American Chemistry Society, 2011, 133 (14) :5228 - 5231.
  • 7Erxleben A. Structures and properties of Zn ( II ) coord- ination polymers [ J ]. Coordination Chemistry Reviews, 2003, 246( 1 -2) :203 -228.
  • 8Couck S, Denayer J F M, Baron G V, Remy T, Gascon J, Kapteijn F. An amine-functionalized MIL-53 metal organic framework with large separation power for CO2 and CH4 [ J ]. Journal of American Chemistry Society, 2009, 131 (18) :6326 -6327.
  • 9Stuart L J. Metal-organic frameworks [ J ]. Chemistry Society Review, 2003,32(2):276-288.
  • 10Wu C D, Lu C Z, Yang W B, Zhuang H H, Huang J S. Hydrothermal synthesis, structures, and magnetic properties of three novel 5-aminoisophthalic acid ligand bridged transition metal cation polymers [ J ]. Inorganic Chemistry, 2002, 41 (12) :3302 - 3307.

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无机化学学报
2013年 第10期

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