纳米凝胶载体系统的研究进展

李霏霏, 张娜

中国药学杂志 ›› 2016, Vol. 51 ›› Issue (3) : 177-182.

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中国药学杂志
PDF(1174 KB)
中国药学杂志 ›› 2016, Vol. 51 ›› Issue (3) : 177-182. DOI: 10.11669/cpj.2016.03.005
综 述

纳米凝胶载体系统的研究进展

  • 李霏霏, 张娜*
作者信息 +

Research Progress in Nanogel Carrier Systems

  • LI Fei-fei, ZHANG Na*
Author information +
文章历史 +

摘要

纳米凝胶具有粒径小、血液循环时间长、生物相容性好、生物可降解、载药量高等优点。通常用于制备纳米凝胶的载体材料有聚丙烯酸及聚丙烯酰胺类、普朗尼克类、聚多糖类高分子材料及其衍生物,可通过基于氨基的交联、“click”反应交联、物理交联、光交联、多相单体聚合等方法形成纳米凝胶。纳米凝胶作为一种理想的新型给药系统在化疗药物、蛋白类药物及基因的递送等方面显示出广阔的应用前景。笔者参考近期相关文献,对纳米凝胶的常用载体材料,制备方法及应用进行整理与总结。

Abstract

Nanogels combine the advantages of hydrogels and nanoparticles, such as small particle size, prolonged blood circulation time, biocompatibility, biodegradation and high drug loading. Common carrier materials is used for the preparation of nanogels include polyacrylic acid, polyacrylamide, pluronic, polysaccharide and their derivates. They can be cross-linked based on amine reaction, “click” chemistry, photo-induced cross-linking, physical cross-linking or heterogeneous polymerization of monomers to form nanogel carrier systems. Nanogels, as ideal and novel drug delivery systems, have great promise in the delivery of chemotherapeutic drugs, proteins and genes.The carrier materials, preparation methods and applications of nanogels were reviewed based on relevant articles published in recent years.

关键词

纳米凝胶 / 载体材料 / 制备方法 / 药物递送

Key words

nanogel / carrier material / preparation method / drug delivery

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导出引用
李霏霏, 张娜. 纳米凝胶载体系统的研究进展[J]. 中国药学杂志, 2016, 51(3): 177-182 https://doi.org/10.11669/cpj.2016.03.005
LI Fei-fei, ZHANG Na. Research Progress in Nanogel Carrier Systems[J]. Chinese Pharmaceutical Journal, 2016, 51(3): 177-182 https://doi.org/10.11669/cpj.2016.03.005
中图分类号: R944   

参考文献

[1] MERINO S,MARTIN C,KOSTARELOS K,et al. Nanocomposite hydrogels:3D Polymer-nanoparticle synergies for on-demand drug delivery [J]. ACS Nano,2015,9 (5):4686-4697.
[2] HAMIDI M,AZADI A,RAFIEI P. Hydrogel nanoparticles in drug delivery [J]. Adv Drug Deliv Rev,2008,60 (15):1638-1649.
[3] AHMED E M. Hydrogel:Preparation,characterization,and applications:A review [J]. J Adv Res,2015,6 (2):105-121.
[4] GAO Y,XIE J,CHEN H,et al. Nanotechnology-based intelligent drug design for cancer metastasis treatment [J]. Biotechnol Adv,2014,32 (4):761-777.
[5] DESALE S S,RAJA S M,KIM J O,et al. Polypeptide-based nanogels co-encapsulating a synergistic combination of doxorubicin with 17-AAG show potent anti-tumor activity in ErbB2-driven breast cancer models [J]. J Controlled Release,2015,208(12):59-66.
[6] YALLAPU M M,JAGGI M,CHAUHAN S C. Design and engineering of nanogels for cancer treatment [J]. Drug Discov Today,2011,16 (9-10):457-463.
[7] LOU S,GAO S,WANG W,et al. Galactose-functionalized multi-responsive nanogels for hepatoma-targeted drug delivery [J]. Nanoscale,2015,7 (7):3137-3146.
[8] HE H,CATTRAN A W,NGUYEN T,et al. Triple-responsive expansile nanogel for tumor and mitochondria targeted photosensitizer delivery [J]. Biomaterials,2014,35 (35):9546-9553.
[9] SWAIN J,MISHRA A K. 1-Naphthol as an ESPT fluorescent molecular probe for sensing thermotropic microenvironmental changes of pluronic F127 in aqueous media [J]. Phys Chem Chem Phys,2015,17 (26):16752-16759.
[10] JOUNG Y K,JANG J Y,CHOI J H,et al. Heparin-conjugated pluronic nanogels as multi-drug nanocarriers for combination chemotherapy [J]. Mol Pharm,2013,10 (2):685-693.
[11] KIM J Y,CHOI W I,KIM M,et al. Tumor-targeting nanogel that can function independently for both photodynamic and photothermal therapy and its synergy from the procedure of PDT followed by PTT [J]. J Controlled Release,2013,171 (2):113-121.
[12] LEMARCHAND C,GREF R,PASSIRANI C,et al. Influence of polysaccharide coating on the interactions of nanoparticles with biological systems [J]. Biomaterials,2006,27 (1):108-118.
[13] LIU Z,CHEN K,DAVIS C,et al. Drug delivery with carbon nanotubes for in vivo cancer treatment [J]. Cancer Res,2008,68 (16):6652-6660.
[14] LIU L K,FINZEL B C. Fragment-based identification of an inducible binding site on cell surface receptor CD44 for the design of protein-carbohydrate interaction inhibitors [J]. J Med Chem,2014,57 (6):2714-2725.
[15] YANG C,WANG X,YAO X,et al. Hyaluronic acid nanogels with enzyme-sensitive cross-linking group for drug delivery [J]. J Controlled Release,2015,205(9):206-217.
[16] WANG X,LI J,WANG Y,et al. A folate receptor-targeting nanoparticle minimizes drug resistance in a human cancer model [J]. ACS Nano,2011,5 (8):6184-6194.
[17] WU W,YAO W,WANG X, et al. Bioreducible hepariN-based nanogel drug delivery system [J]. Biomaterials,2015,39(4):260-268.
[18] HE L,LIANG H,LIN L,et al. Green-step assembly of low density lipoprotein/sodium carboxymethyl cellulose nanogels for facile loading and pH-dependent release of doxorubicin [J]. Colloids Surf B Biointerfaces,2015,126(2):288-296.
[19] LIN L,XU W,LIANG H,et al. Construction of pH-sensitive lysozyme/pectin nanogel for tumor methotrexate delivery [J]. Colloids Surf B Biointerfaces,2015,126(2):459-466.
[20] CHEN W,ACHAZI K,SCHADE B,et al. Charge-conversional and reduction-sensitive poly(vinyl alcohol) nanogels for enhanced cell uptake and efficient intracellular doxorubicin release [J]. J Controlled Release,2015,205(9):15-24.
[21] CHACKO R T,VENTURA J,ZHUANG J,et al. Polymer nanogels:A versatile nanoscopic drug delivery platform [J]. Adv Drug Deliv Rev,2012,64 (9):836-851.
[22] NUKOLOVA N V,OBEROI H S,COHEN S M,et al. Folate-decorated nanogels for targeted therapy of ovarian cancer [J]. Biomaterials,2011,32 (23):5417-5426.
[23] PARK J H,CHO H J,TERMSARASAB U,et al. Interconnected hyaluronic acid derivative-based nanoparticles for anticancer drug delivery [J]. Colloids Surf B Biointerfaces,2014,121(9):380-387.
[24] KOLB H C,FINN M G,SHARPLESS K B. Click chemistry:Diverse chemical function from a few good reactions[J]. Angew Chem Int Ed Engl,2001,40 (11):2004-2021.
[25] MA N,WANG Y,ZHAO B X,et al. The application of click chemistry in the synthesis of agents with anticancer activity [J]. Drug Des Devel Ther,2015,9(1):1585-1599.
[26] JORALEMON M J,O′REILLY R K,HAWKER C J,et al. Shell click-crosslinked (SCC) nanoparticles:A new methodology for synthesis and orthogonal functionalization [J]. J Am Chem Soc,2005,127 (48):16892-16899.
[27] IL CHOI W,TAE G,KIM Y H. One pot,single phase synthesis of thermo-sensitive nano-carriers by photo-crosslinking of a diacrylated pluronic [J]. J Mater Chem,2008,18 (24):2769-2774.
[28] CHOI W I,LEE J H,KIM J Y,et al. Efficient skin permeation of soluble proteins via flexible and functional nano-carrier [J]. J Controlled Release,2012,157 (2):272-278.
[29] SASAKI Y,AKIYOSHI K. Nanogel engineering for new nanobiomaterials: From chaperoning engineering to biomedical applications [J]. Chem Rec,2010,10 (6):366-376.
[30] MORIMOTO N,HIRANO S,TAKAHASHI H,et al. Self-assembled pH-sensitive cholesteryl pullulan nanogel as a protein delivery vehicle [J]. Biomacromolecules,2013,14 (1):56-63.
[31] ZAN M,LI J,LUO S,et al. Dual pH-triggered multistage drug delivery systems based on host-guest interaction-associated polymeric nanogels [J]. Chem Commun (Camb),2014,50 (58):7824-7827.
[32] LU S,NEOH K G,KANG E T,et al. Mucoadhesive polyacrylamide nanogel as a potential hydrophobic drug carrier for intravesical bladder cancer therapy [J]. Eur J Pharm Sci,2015,72(7):57-68.
[33] WANG H,KE F,MARARENKO A,et al. Responsive polymer-fluorescent carbon nanoparticle hybrid nanogels for optical temperature sensing,near-infrared light-responsive drug release,and tumor cell imaging [J]. Nanoscale,2014,6 (13):7443-7452.
[34] JU C,MO R,XUE J,et al. Sequential intra-intercellular nanoparticle delivery system for deep tumor penetration [J]. Angew Chem Int Ed Engl,2014,53 (24):6253-6258.
[35] WEI X,SENANAYAKE T H,BOHLING A,et al. Targeted nanogel conjugate for improved stability and cellular permeability of curcumin: Synthesis,pharmacokinetics,and tumor growth inhibition [J]. Mol Pharm,2014,11 (9):3112-3122.
[36] WATER J J,KIM Y,MALTESEN M J,et al. Hyaluronic acid-based nanogels produced by microfluidics-facilitated self-assembly improves the safety profile of the cationic host defense peptide novicidin[J]. Pharm Res,2015,32 (8):2727-2735.
[37] KITANO S,KAGEYAMA S,NAGATA Y,et al. HER2-specificT-cell immune responses in patients vaccinated with truncated HER2 protein complexed with nanogels of cholesteryl pullulan [J]. Clin Cancer Res,2006,12 (24):7397-7405.
[38] KAGEYAMA S,KITANO S,HIRAYAMA M,et al. Humoral immune responses in patients vaccinated with 1-146 HER2 protein complexed with cholesteryl pullulan nanogel [J]. Cancer Sci,2008,99 (3):601-607.
[39] YANG H N,PARK J S,JEON S Y,et al. Carboxymethylcellulose (CMC) formed nanogels with branched poly(ethyleneimine) (bPEI) for inhibition of cytotoxicity in human MSCs as a gene delivery vehicles [J]. Carbohydr Polym,2015,122(8):265-275.
[40] NUHN L,GIETZEN S,MOHR K,et al. Aggregation behavior of cationic nanohydrogel particles in human blood serum [J]. Biomacromolecules,2014,15 (4):1526-1533.

基金

国家自然科学基金资助项目(81573368)
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