Treatment of Starch Wastewater by α‐Amylase Immobilized on Silica Infused Magnetite Nanoparticles for Maltose Syrup Preparation

Harsh Patel, Rucha P. Desai, Darshan Patel, Bhavtosh A. Kikani
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Abstract

Abstract Casein decorated silicainfused magnetite (Fe 3 O 4 ‐SiO 2 ) nanoparticles are employed to immobilize commercial α‐amylase, where glutaraldehyde serves as a cross linker. The optimal concentration of variables, such as casein (1.4%w/v), Fe 3 O 4 ‐SiO 2 (106 µl), glutaraldehyde (55µl) and amylase (1 mg/ml) are defined by a Box Behnken design. The binding of casein, glutaraldehyde and enzyme over the nanoparticles are further confirmed structurally by fourier transform infrared spectroscopy (FTIR) and thermal gravimetric analysis (TGA). The loading capacity is 37 µg amylase over 1 µg of silica infused magnetite nanoparticles. The optimum pH for the catalysis of soluble and immobilized amylases is the same, i.e. pH 7. However, the pH range for catalysis is improved upon immobilization. The temperature optimum of soluble and immobilized amylases are 40 and 70 °C, respectively. The amylase stability is improved upon immobilization, as shown by enhanced half‐life and reduced deactivation rate constant. The immobilized amylase is used for 17 consecutive cycles with retention of 52% of the residual activity. The immobilized amylase produces high maltose syrup using the industrial wastewater containing corn starch. The ISO 5377 protocol determines dextrose equivalence values to be 36% and 24% during cycle 1 and cycle 2, respectively. The findings point out its possible commercial use.

Abstract Image

二氧化硅注入磁性纳米颗粒固定化α‐淀粉酶处理淀粉废水制备麦芽糖糖浆
摘要采用酪蛋白修饰的硅铁磁铁矿(fe3o4‐sio2)纳米颗粒固定化商用α‐淀粉酶,其中戊二醛作为交联剂。通过Box Behnken设计确定了酪蛋白(1.4%w/v)、fe3o4‐sio2(106µl)、戊二醛(55µl)和淀粉酶(1 mg/ml)等变量的最佳浓度。通过傅里叶变换红外光谱(FTIR)和热重分析(TGA)进一步证实了酪蛋白、戊二醛和酶在纳米颗粒上的结合。负载容量为37µg淀粉酶/ 1µg二氧化硅注入的磁铁矿纳米颗粒。催化可溶性淀粉酶和固定化淀粉酶的最佳pH值相同,即pH为7。然而,固定化后催化的pH范围得到改善。可溶性淀粉酶和固定化淀粉酶的最适温度分别为40℃和70℃。固定化后,淀粉酶的稳定性得到了提高,表现为半衰期的延长和失活速率常数的降低。固定化淀粉酶连续使用17个周期,剩余活性的保留率为52%。固定化淀粉酶利用含玉米淀粉的工业废水生产高麦芽糖糖浆。ISO 5377协议确定葡萄糖等效值在循环1和循环2期间分别为36%和24%。研究结果指出了它可能的商业用途。
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