Download Preparation of Chitosan-Coated Magnetite Nanoparticles and

Journal of Applied Polymer Science
123:707-716 (2012)
Preparation of Chitosan-Coated Magnetite Nanoparticles
and Application for Immobilization of Laccase
Nuzhet Ayca Kalkan, Serpil Aksoy, Eda Ayse Aksoy, Nesrin Hasirci
Department of Chemistry, Faculty of Arts and Sciences, Gazi University, Teknikokullar, 06500 Ankara, Turkey
2011. 11. 10
Sang-Hoon Lee
Gwi-Yeong Jang
Introduction

The objectives of the study are, to functionalize Fe3O4 nanoparticles by coating
with a functional polymer; to immobilize laccase on these magnetic nanosystems;
to measure and compare the activity and reusability of the enzyme containing
systems at different conditions.

Applications of nanosized magnetic particles (maghemite, c-Fe3O4 or magnetite,
Fe3O4) in biology and medicine.
 Magnetic resonance imaging
 hyperthermia generation
 Magnetically controlled transport of anticancer drugs
 RNA and DNA purification
 magnetic cell separation and purification
 enzyme and protein immobilization

Using magnetic nanoparticles as the support of immobilized enzymes also has
the following advantages
 higher specific surface area for the binding of higher amounts of enzymes
 lower mass transfer resistance
 less fouling
 less diffusion problem
 lower operational cost
Introduction

Chitosan
 Chitosan based materials are used as supports, in various forms such as powder, flake, and
gel, and of different geometrical configurations, for immobilization of several enzymes.
 Chitosan is produced commercially by deacetylation of chitin, which is the structural element
in the exoskeleton of crustaceans and cell walls of fungi.
 A common method for the synthesis of chitosan is the deacetylation of chitin using sodium hy
droxide in excess as a reagent and water as a solvent. This reaction pathway, when allowed
to go to completion yields up to 98% product.

Laccase
 Laccases are extracellular, multi-copper enzymes and are found in plants, insects, bacteria,
and more redominantly in fungi.
 Laccases act on phenols and similar molecules, performing a one-electron oxidations, which
remain poorly defined.
 Application areas : Textile dye bleaching, pulp bleaching, food improvement, bioremediation
of soils and water, polymer synthesis, development of biosensors, or biofuel cells

The hypothesis of this study
 laccase enzyme which is a commercialized industrial catalysts used in bioremediation, would
have high catalytic activity and efficient reuse capacity upon immobilization on functionalized
magnetic nanoparticles.
Materials and methods


Materials
 Fe3O4 nanoparticles (<50 nm), Chitosan, acetic acid, mineral Oil, ABTS, Ethanol, Tween 80,
Glutaraldehyde, Laccase, Bovine serum albumin, Carbodiimide, EDAC, Cyanuric chloride.
Methods
 Preparation of chitosan-coated magnetite nanoparticles
 Characterization of chitosan-coated magnetite nanoparticles
 Enzyme immobilization studies
 Immobilization of laccase
 Immobilization efficiency
 Assay of laccase activity
 Effect of pH
 Effect of temperature
 Kinetic studies
 Reusability of immobilized laccases
Materials and methods

Preparation of chitosan-coated magnetite nanoparticles
 Reversed phase suspension method
1.
200 mg Fe3O4 NPs + ethanol  washing X 3
2.
Add : 50.0 mL mineral oil containing 0.5 mL Tween 80
3.
The mixture was sonicated
4.
Add : chitosan solution (1% w/v, 15.0 mL in 5.0% v/v acetic acid)
5.
The Fe3O4-chitosan dispersion was sonicated for 30 min
6.
stirred at1500 rpm with a mechanical stirrer.
7.
Add : Glutaraldehyde solution (3.0 mL, 25% w/v in water) was added to the medium
8.
stirred for 4 h at room temperature.
9.
The resultant chitosan-coated magnetite nanoparticles (Fe3O4-CS) were separated
from the reaction mixture by a permanent magnet, washed several times with acetone,
and dried in vacuum oven at 40C.
Results
1. Characterization of Fe3O4-CS nanoparticles – TEM image
Fe3O4
(approx. 50 nm)
CS on Fe3O4
nanoparticle
(1.0-4.8 nm)
Results
1. Characterization of Fe3O4-CS nanoparticles
3650
O-H
2870
-C-H
1659
C=O
1074
C-O-C
6.86
7.91
74.1
25.2
Results
2. Immobilization of laccase – Covalent binding method
Results
2. Immobilization of laccase – Covalent immobilization
Immobilization efficiency : 93.76%
Immobilization efficiency : 94.%
Immobilization efficiency : 94.36%
Results
2. Immobilization of laccase – Effect of pH and temperature
The optimum pH for free or immobilized Laccase
- Free laccase : pH 3.0
- Fe3O4-CS-L : pH 3.0
- Fe3O4-CS-EDAC-L : pH 4.5
- Fe3O4-CS-CC-L : pH 3.5
The optimum temperature for free or immobilized Laccase
- Free laccase : 40℃
- Fe3O4-CS-L : 40℃
- Fe3O4-CS-EDAC-L : 30℃
- Fe3O4-CS-CC-L : 40℃
Results
3. Kinetic study
Results
4. Reusability of immobilized laccase
More than 85%
71%
74%
81%
Conclucsions

Chitosan-coated magnetite(Fe3O4-CS) nanoparticles
 Prepared by reversed phase suspension technique
 There Structural and magnetic properties were characterized.
 TEM analysis : thickness of CS layer covered the surface of magnetite nanoparticles were
less than 5 nm
 Isoelectric point(pI) : 6.86 by zeta-potential measurement

Immobilized laccase(Fe3O4-CS + laccase)
 By adsorption and covalent binding methods
 The dependence of immobilized laccase activities against pH and temperature demonstrated
that enzyme became more stable upon immobilization compared with the free form
 Catalytic efficiencies of the immobilized enzymes were also quite close to the free enzyme.
 All the immobilized systems prepared either by adsorption or covalent binding exhibited more
than 71% activity at the end of 30th repeated use.
Therefore, it can be concluded that all laccase immobilized magnetic nanosystems prepared in
this study can be good candidates to be used in industrial applications in terms of catalytic
activity and reuse capacity.