Paper Titles

Thermodynamic Properties of Nb₄AlC₃
p.442

The Reach on the Salt Spray Corrosion of 6000 Series Aluminum Alloys for the High-Speed Trains
p.447

Influence of Stress Concentration on Fatigue Property of Welded Joints of 5083 Aluminum Alloy
p.451

Research Progress of Phase Change Materials on Heat Transfer
p.456

The Advances in Research of Complexes of Chitosan and its Derivatives
p.461

The Study on the Basic Theory of Gold Seamless Pipe Welding Numerical Simulation
p.467

Synthesis, Morphology and Hydrophobicity of Core-Shell Fluoinated Copolymer Latexes
p.471

Surface Hardening of a Vermicular Cast Iron Used for Integral Molding Valve Seat by High Power Laser
p.474

Numerical Simulation of Aluminum Alloy Welding for Butt-Joint of AA2024 Considering Surface Effect Element
p.478

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 456The Advances in Research of Complexes of Chitosan...

The Advances in Research of Complexes of Chitosan and its Derivatives

Article Preview

Abstract:

Chitosan is a partially deacetylated polymer of acetyl glucosamine obtained byalkaline deacetylation of chitin. It displays interesting properties such as biocompatibility, biodegradability as its degradation products are non-toxic, non-immunogenic, and non-carcinogenic. It can be modified chemically for the presence of amino and hydroxyl groups to prepare functional derivatives of chitosan. Chitosan and its derivatives have good adsorption ability for metal ions due to theirs high percentage of nitrogen, amino and hydroxyl groups on their chemical structure act as chelation sites for metal ions. This article reviews the developments of the studies on coordination between chitosan, derivatives and metal ions, as well as the applications of chitosan-based complexes in many fields such as antibacterial effect, the catalysts, metal recovery and detection, and agriculture.

You might also be interested in these eBooks

Research in Mechanical Engineering and Material Science

Info:

Periodical:

Applied Mechanics and Materials (Volume 456)

Pages:

461-466

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.456.461

Citation:

Cite this paper

Online since:

October 2013

Authors:

Feng Ma*, Feng Yan Lu

Keywords:

Application, Chitosan, Complexes, Coordination, Derivatives, Metal Ions

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

© 2014 Trans Tech Publications Ltd. All Rights Reserved

Share:

Citation:

* - Corresponding Author

[1] J. Miao, G. H. Chen, C. J. Gao, S. X. Dong, Desalination. 233(2008), p.147.

[2] A. J. Varma, J. F. Kennedy, Carbohydrate Polymers. 55(2004), p.77.

[3] H. He, Z. C. Yu, Hebei textile. 4(2008), p.14.

[4] E. I. Rabea, M. E. T. Badawy, C. V. Stevens, G. Smagghe, W. Steurbaut, American Chemical Society. 4(2003), p.1457.

[5] X. H Tang, A. L Zhou, Jiangxi chemical industry. 1(2007), p.1.

[6] N. Yang, X. M. Zhang, L. Y. Tian, B. H. Zhao, Applied chemical industry. 37(2008), p.1362.

[7] X. Q. Feng, X. F. Xi, S. Yang, G. Q Fu, T. P. Wang, Z. X Sun, Science and Technology of Food Industry. 31(2010), p.304.

[8] X. H. Cai, W. Zhang, X. Wu, Pesticides. 51(2012), p.179.

[9] Z. G. Ma,Y. M. Zou, A. P Zhang, Journal of Hebei University. 28(2008), p.494.

[10] M. Adlim, M. A. Bakar, K.Y. Liew, J. I Smail, Journal of Molecular Catalysis A: Chemical. 212 (2004) , p.141.

[11] M. Rhazi, J. Desbrieres, A. Tolaimate, M. Rinaudo, P. Vottero, A. Alagui, Polymer. 43(2002), p.1267.

DOI: 10.1016/s0032-3861(01)00685-1

[12] H. R Zhang, S.Y. Guo, L. Li, J. N. Chen, Chinese Journal of Spectroscopy Laboratory. 23(2006), p.1035.

[13] X. N. Zhang, J. S. Sun, S. H. Wang, J. S. Zhang, C. L. Miao, Journal of Chemical Engineering of Chinese Universities. 25(2011), p.91.

[14] S. L. Sun, A. Q. Wang, Journal of hazardous materials. 131(2006), p.103.

[15] D. H. Liu, S. Q. Cao, F. Wang, Journal of Xinyang Normal University (Natural Science Edition). 18(2005), p.454.

[16] Y. Lin, C. C. Zhou, Food Research International. 37(2004), p.883.

[17] Y. G Peng, Q. Zhang, Y. Xiang, Chemical Journal of Chinese Universities. 32(2011), p.2828.

[18] J. J. Dong, S. D. Li, W. Y. Quan, X. D. She, Y. L. Zheng, Guangzhou Chemical Industry. 38(2010), p.73.

[19] R. J Qu, C. M. Sun, C. N. Ji, C. H. Wang, H. Chen, Y. Z Niu, C. J. Liang, Q. Y. Song, Carbohydrate Research. 343(2008), p.267.

[20] V. Singh, A. Tiwari, D. N. Tripathi, R. Sanghi, Journal of hazardous materials. 47(2006), p.254.

[21] S. L Sun, A. Q. Wang, Reactive&Functional Polymers. 66(2006), p.819.

[22] M. Ruiz, A. M. Sastre, E. Guibal, Reactive & Functional Polymers. 45(2000), p.155.

[23] X. Q. Feng, X. F. Li, S. Yang, G. Q. Fu, T. P. Wang, Food Science. 32(2011), p.152.

[24] J. L. Xia, T. E. Song, Z. Y. Nie, E. P. Li, Acta Scientiarum Naturalium Universitatis Sunyatseni. 46 (2007), p.21.

[25] P. Liu, P. Zhang, X. Y. Wang, Journal of Molecular Catalysis. 20(2006), p.339.

[26] L. Zhang, X. W. Zhao, X. M. Liu, Y. Li, Y. C. Cui, Acta Polymerica Sinica. 9 (2006), p.1033.

[27] C. Demetgül, Carbohydrate Polymers. 89(2012), p.354.

[28] L. M. Zhou,Y. P. Wang, Q. W. Huang, Z. R. Liu, Acta Physico-Chimica Sinica. 23(2007), p. (1979).

[29] X. P. Jiang, K. Cheng, S. Wang, X. M. Liu, L. Yu, L. Shi, Chinese Journal of Applied Chemistry. 27(2010), p.462.

[30] H. Wu, D. F. Wang, L. N. Yu, H. Y. Li, Y. L. Shi, Journal of Rare Earths. 24 (2006), p.176.

[31] Y. F. Li, D. M. Huang, Y. An, Journal of Anhui Agricultural Sciences. 40(2012), p.8240.