Abstract
Ginkgo biloba leaves are well known for their high content of nutrients and bioactive substances. However, unpleasant smell and a small number of ginkgolic acids greatly reduce the utilization of the leaves. In this work, solid-state fermentation of G. biloba leaves using Eurotium cristatum was studied by investigation of the nutrient changes and its feasibility as a functional feed. E. cristatum could grow on pure G. biloba leaves and the addition of excipients could significantly improve the growth of E. cristatum. The optimal medium was with 10% (w/w) of whole G. biloba seeds and the optimized water content, pH, inoculum size and fermentation time were 45% (w/w), 4.5, 4.76 × 107 CFU/100 g wet medium, and eight days, respectively. Under the optimal conditions, the spore number increased by about 40 times. The content of flavonoids was greatly increased by 118.6%, and the protein and polyprenyl acetates (PPAs) were increased by 64.9% and 10.6%, respectively. The ginkgolic acids, lignin, and cellulose were decreased by 52.4%, 38.5%, and 20.1% than before, respectively. Furthermore, the fermented G. biloba leaves showed higher antioxidant activity and held more aroma substances. Thus, G. biloba leaves fermented by E. cristatum have potential as s high value-added feed. This is the first investigation of E. cristatum fermentation on ginkgo leaves, which will facilitate the use of ginkgo leaves in the feed industry.
Highlights
The use of antibiotics in the feed industry once had positive effects on prevention of animal diseases and improvement of feed reward
The results demonstrated that E. cristatum could grow on pure G. biloba leaves and the addition of excipients could significantly improve the growth of Eurotium cristatum
The results showed that G. biloba leaves fermented by E. cristatum were promising as a fermented feed
Summary
The use of antibiotics in the feed industry once had positive effects on prevention of animal diseases and improvement of feed reward. Fermented feed has attracted wide attention because of its low-cost, high nutritional value, and multifunctionality. Antinutrient factors, and macromolecular substances, raw materials can be decomposed or transformed into bioactive components such as organic acids, active small peptides, and growth factors [4]. The strains permitted for use in fermented feed include Bacillus subtilis, Saccharomyces, and Aspergillus, among others [3,5]. Bacillus subtilis can improve the growth performance of animals by secreting amylase, protease, and lipase [6]. Saccharomyces has the prominent ability of protein digestion and acid production to prevent antimicrobial-associated diarrhea [7,8].
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