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  • Mathematic modeling for optimum conditions on aflatoxin B₁degradation by the aerobic bacterium Rhodococcus erythropolis.

Mathematic modeling for optimum conditions on aflatoxin B₁degradation by the aerobic bacterium Rhodococcus erythropolis.

Toxins (2012-12-04)
Qing Kong, Cuiping Zhai, Bin Guan, Chunjuan Li, Shihua Shan, Jiujiang Yu
ABSTRACT

Response surface methodology was employed to optimize the degradation conditions of AFB₁ by Rhodococcus erythropolis in liquid culture. The most important factors that influence the degradation, as identified by a two-level Plackett-Burman design with six variables, were temperature, pH, liquid volume, inoculum size, agitation speed and incubation time. Central composite design (CCD) and response surface analysis were used to further investigate the interactions between these variables and to optimize the degradation efficiency of R. erythropolis based on a second-order model. The results demonstrated that the optimal parameters were: temperature, 23.2 °C; pH, 7.17; liquid volume, 24.6 mL in 100-mL flask; inoculum size, 10%; agitation speed, 180 rpm; and incubation time, 81.9 h. Under these conditions, the degradation efficiency of R. erythropolis could reach 95.8% in liquid culture, which was increased by about three times as compared to non-optimized conditions. The result by mathematic modeling has great potential for aflatoxin removal in industrial fermentation such as in food processing and ethanol production.

MATERIALS
Product Number
Brand
Product Description

Sigma-Aldrich
Aflatoxin B1 from Aspergillus flavus, from Aspergillus flavus
Supelco
Aflatoxin B1 solution, 3 μg/mL in benzene:acetonitrile (98:2), analytical standard
Aflatoxin B1 solution, 3.79 μg/g in acetonitrile, ERM®, certified reference material
Supelco
Aflatoxin B1 solution, 2 μg/mL in acetonitrile, analytical standard