Fumaric acid production from fermented oil palm empty fruit bunches using fungal isolate K20: a comparison between free and immobilized cells.

This study investigated the potential of using steam-exploded oil palm empty fruit bunches (EFB) as a renewable feedstock for producing fumaric acid (FA), a food additive widely used for flavor and preservation, through a separate hydrolysis and fermentation process using the fungal isolate K20. The efficiency of FA production by free and immobilized cells was compared. The maximum FA concentration (3.25 g/L), with 0.034 g/L/h productivity, was observed after incubation with the free cells for 96 h. Furthermore, the production was scaled up in a 3-L air-lift fermenter using oil palm EFB-derived glucose as the substrate. The FA concentration, yield, and productivity from 100 g/L initial oil palm EFB-derived glucose were 44 g/L, 0.39 g/g, and 0.41 g/L/h, respectively. The potential for scaling up the fermentation process indicates favorable results, which could have significant implications for industrial applications.

Cellulase production under solid-state fermentation by Aspergillus sp. IN5: Parameter optimization and application.

Microbial cellulases are highly versatile catalysts with significant potential in various industries, including pulp and paper, textile manufacturing, laundry, biofuel production, food and animal feed, brewing, and agriculture. Cellulases have attracted considerable attention from the scientific community owing to their broad industrial applications and the complex nature of enzymatic systems. In the present study, a novel fungal isolate of Aspergillus sp. IN5 was used to produce cellulases. We optimized each parameter, including carbon source, incubation temperature, pH, and incubation time, for maximum cellulase production using isolate IN5 under solid-state fermentation conditions. The optimized parameters for cellulase production by isolate IN5 under solid-state fermentation were as follows: substrate, soybean residue; incubation temperature, 35 °C; pH, 7.0; and incubation duration, 5 days. These conditions resulted in the highest total cellulase activity (0.26 U/g substrate), and carboxymethyl cellulase and ß-glucosidase activities of 3.32 and 196.09 U/g substrate, respectively. The obtained fungal cellulase was used for the enzymatic hydrolysis of acid- or alkali-pretreated rice straw, which served as a model substrate. Notably, compared with acid pretreatment, the pretreatment of rice straw with diluted alkali led to higher yields of reducing sugars. Maximum reducing sugar yield (286.06 ± 2.77 mg/g substrate) was obtained after 24-h incubation of diluted alkali-pretreated rice straw mixed with an enzyme loading of 15 U/g substrate. The findings of this study provide an alternative strategy for utilizing agricultural waste and an approach to efficiently produce cellulase for the degradation of lignocellulosic materials, with promising benefits for sustainable waste management.

Optimization of Textile Waste Blends of Cotton and PET by Enzymatic Hydrolysis with Reusable Chemical Pretreatment.

Textile waste usually ends up in landfills and causes environmental pollution. In this study, pretreatment methods for textile recycling, including autoclaving, freezing alkali/urea soaking, and alkaline pretreatment, were applied to textile waste with various cotton/polyester blending ratios. The best condition for enzymatic hydrolysis was a 60/40 textile waste blend of cotton/polyethylene terephthalate (PET) with a reusable chemical pretreatment (15% NaOH) at 121 °C for 15 min. The hydrolysis of pretreated textile waste by cellulase was optimized using response surface methodology (RSM) based on central composite design (CCD). The optimized conditions were 30 FPU/g of enzyme loading and 7% of substrate loading, which resulted in a maximum observed value of hydrolysis yield at 89.7%, corresponding to the predicted value of 87.8% after 96 h of incubation. The findings of this study suggest an optimistic solution for textile waste recycling.