Adding Fruit Fermentation Liquid Improves the Efficiency of the Black Soldier Fly in Converting Chicken Manure and Reshapes the Structure of Its Intestinal Microbial Community

Adding Fruit Fermentation Liquid Improves the Efficiency of the Black Soldier Fly in Converting Chicken Manure and Reshapes the Structure of Its Intestinal Microbial Community

This study evaluated how fruit fermentation liquid (FFL) enhances the conversion of chicken manure by black soldier fly larvae (BSFL) and modulates their gut microbiota. Three groups were tested: control (A: 300 g manure + 50 g water), low-dose FFL (B: 300 g manure + 25 g FFL + 25 g water), and high...

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Main Authors: Lifei Chen, Guiying Wang, Hanhan Song, Qi Yang, Jiani Fu, Jiale Liu, Haoyang Sun, Yuxi Wang, Qile Tian, Yuting Sun, Lei Sun, Hao Xin, Zuyin Xiao, Guoliang Wang, Zixuan Zhang, Yinling Zhao, Hongyan Yang, Lusheng Li
Format: Article
Language:English
Published: MDPI AG 2025-04-01
Series:Insects
Subjects:
black soldier fly larvae
fruit fermentation liquid
chicken manure conversion
intestinal microbial community
ammonia emissions
Online Access:https://www.mdpi.com/2075-4450/16/5/472
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Summary:This study evaluated how fruit fermentation liquid (FFL) enhances the conversion of chicken manure by black soldier fly larvae (BSFL) and modulates their gut microbiota. Three groups were tested: control (A: 300 g manure + 50 g water), low-dose FFL (B: 300 g manure + 25 g FFL + 25 g water), and high-dose FFL (C: 300 g manure + 50 g FFL). The results show that the dry matter conversion rate significantly increased by 9.5% (<i>p</i> < 0.05), while the feed-to-larvae ratio was reduced by 1.02 (<i>p</i> < 0.01) in group C. NH<sub>3</sub> emissions in group C decreased by 24.48 mg·kg<sup>−1</sup>·DM (dry matter substrate) day<sup>−1</sup> (24.48 mg per kilogram of dry matter substrate per day) (<i>p</i> < 0.01), with suppressed H<sub>2</sub>S release. Gut microbiota analysis revealed that FFL reduced the abundance of Proteobacteria (6.07% decrease in group C) while enriching Actinobacteriota (4.68% increase) and beneficial genera (<i>Corynebacterium</i>, <i>Gallicola</i>). Substrate microbial diversity in group C improved, with Proteobacteria and Firmicutes increasing by 11.07% and 4.83%, respectively, and pathogenic <i>Sphingobacteriaceae</i> declining by 21.16% by day 7. FFL likely introduced organic acids and nutrients, enhancing larval digestion and nutrient absorption while inhibiting the production of harmful gases. These findings demonstrate that FFL optimizes BSFL-driven waste conversion efficiency through modulation of the microbiota, offering a sustainable strategy for organic waste management and contributing to circular agricultural systems.
ISSN:2075-4450

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