Studying the solid-liquid extraction of enzyme amylase: influence of type of solvent, temperature, contact time and their interrelationship
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Date
2025-07-15
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Publisher
Plovdiv University Press “Paisii Hilendarski”
Abstract
Amylases are one of the most essential and widely used enzymes in a number of industries, including food, fermentation, paper, textile and pharmaceutical. The industrial production of enzyme amylase is carried out using two methods which are submerged fermentation and solid-state fermentation. The important factors that affect the fermentation process are pH, temperature, carbon and nitrogen sources, and metal ions. This study aims at investigating the solid-liquid extraction of amylase from Aspergillus niger, focusing on the influence of solvent type, temperature, contact time, and their interrelationship. The effects of different solvents, temperatures, and contact times on the extraction efficiency and activity of amylase were examined using solvents of different polarity (water, methanol, ethanol, glycerol and acetone), varying temperatures (15 °C, 30 °C and 45 °C) and varying contact times (15, 30 and 90 minutes). The results provided insights into optimizing the extraction process parameters for enhanced amylase yield and activity. Polar solvents like glycerol extracted amylase with the highest enzyme activity levels compared to less polar solvents. A temperature of 30 °C was identified as the optimum for amylase extraction. The results showed that the majority of the amylase was recovered within the first 90 minutes of the process, with diminishing returns for longer contact times. Thus, this research concluded that the interplay between solvent type, temperature, and extraction time is complex, and further optimization through a systematic experimental design would be necessary to identify the ideal combination of these factors for maximizing amylase extraction efficiency and yield.
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Keywords
amylase, Aspergillus niger, solid state fermentation, extraction efficiency