POLYANILINE STABILIZATION OF MAGNETIC PARTICLES AND IMMOBILIZATION OF α-AMYLASE

被引:0
作者
Radovanovic, Mirjana N. [1 ]
Nikolic, Milan P. [1 ]
Durovic, Vesna M. [1 ]
Jugovic, Branimir Z. [2 ]
Gvozdenovic, Milica M. [3 ]
Grgur, Branimir N. [3 ]
Knezevic-Jugovic, Zorica D. [3 ]
机构
[1] Univ Kragujevcu, Agron Fak Cacku, Cara Dusana 34, Cacak 32000, Serbia
[2] Srpske Akad Nauka & Umetnosti, Inst Tehnickih Nauka, Belgrade, Serbia
[3] Univ Beogradu, Tehnol Met Fak, Beograd, Serbia
关键词
Adsorption; alpha-Amylase; Magnetic particles; Polyaniline; Zeta potential; FTIR; MODIFIED FE3O4 NANOPARTICLES; COVALENT IMMOBILIZATION; ENHANCED STABILITY; CATALYTIC-ACTIVITY; ACID) HYDROGELS; ADSORPTION; HYDROLYSIS; MEMBRANE; SURFACE; STARCH;
D O I
10.2298/HEMIND161213016R
中图分类号
TQ [化学工业];
学科分类号
0817 ;
摘要
Magnetic particles (MAG), obtained by standard procedure of coprecipitation of Fe2+ and Fe3+ in an excess of ammonia, and polyaniline modified magnetic particles MAG-PANI were used as carriers for immobilization of a-amylase from Bacillus licheniformis. The formation of a polyaniline layer (PANI) on MAG particles was achieved by chemical polymerization of aniline. Immobilization was carried out by adsorption, as a simple, inexpensive and fast method that allows retention of a large portion of the initial activity of the immobilized enzyme. FTIR spectroscopy was used to characterize the obtained particles and to confirm changes dueto formation of a PANI layer and conjugation of a-amylase on the particle surfaces. Particle size distribution was bimodal and three-modal for MAG and MAG-PANI, respectively. Appearance of a fraction of smaller MAG-PANI particles than MAG particles could be attributed to the formation of PANI particles without the MAG core. Measured values of Zeta potential for MAG-PANI were higher as compared to MAG indicating stabilization of particles in the presence of PANI. Relevant kinetic parameters for immobilized enzyme were determined from the Hanes plot. The apparent K-m constant was 1.91 and 1.48 g L-1 for MAG-A and MAG-PANI-A, respectively, while V-m was 0.19 g L-1 min(-1) for MAG and 0.32 g L-1 min(-1) for MAG-PANI. The obtained values of K-m indicated that modification of MAG by PANI enhanced kinetic properties of the immobilized enzyme. Moreover, the modification of MAG by PANI showed the increase in both pH and thermal stabilities of the immobilized enzyme. Studies of the operational activity of the immobilized enzyme on MAG-PANI have shown that 98.8% of starch was hydrolyzed over 20.0 min. In the first cycle in the packed bed reactor operated in a recycling mode, but approximately five times longer period was required to hydrolyze 93.5 of starch in the fifth cycle. In the continuous packed bed reactor without recycling, the degree of starch hydrolysis was not changed significantly during 4 h and was 88.8 +/- 1.6%, whereas the half-life of the biocatalyst was 6.2 h. Although coating MAG particles with a polyaniline offers many advantages, the main disadvantage is possible appearance of residues of aniline monomers and dimmers. The potential toxicity of these residues requires precise composition analysis of the product of starch hydrolysis catalyzed by a-amylase adsorbed onto MAG-PANI.
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页码:1 / 12
页数:12
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