Beeswax waste improves the mycelial growth, fruiting body yield, and quality of oyster mushrooms ( Pleurotus ostreatus )

Heilongjiang Province has the third largest bee population in China, producing over 2,000 tons of beeswax waste (BW) each year. Most of this BW is discarded or burned. Therefore, we urgently need to find sustainable applications of BW. mushrooms, commonly referred to as oyster mushrooms, are cultiva...

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Bibliographic Details
Published in:PeerJ (San Francisco, CA) CA), 2024-12, Vol.12, p.e18726, Article e18726
Main Authors: Pan, Chunlei, Sheng, Chunge, Wang, Kang, Zhang, Yi, Liu, Chunguang, Zhang, Zhihao, Tao, Liang, Lv, Yang, Gao, Fuchao
Format: Article
Language:English
Subjects:
Agricultural Science
Animals
Bees - growth & development
Beeswax
Beeswax waste (BW)
Biotechnology
China
Crop yields
Fruiting Bodies, Fungal - chemistry
Fruiting Bodies, Fungal - growth & development
Fruiting Bodies, Fungal - metabolism
Growth
Mushrooms
Mycelium - growth & development
Mycology
Nutritional quality
Pleurotus - growth & development
Pleurotus - metabolism
Pleurotus ostreatus
Polysaccharides
Refuse and refuse disposal
Waxes - chemistry
Wheat
Yield
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Summary:Heilongjiang Province has the third largest bee population in China, producing over 2,000 tons of beeswax waste (BW) each year. Most of this BW is discarded or burned. Therefore, we urgently need to find sustainable applications of BW. mushrooms, commonly referred to as oyster mushrooms, are cultivated for both food and medicine. The substrate used to grow mushrooms often contains wheat bran as a nitrogen source. The goal of this study was to explore the feasibility of substituting this wheat bran with BW to cultivate mushrooms. Five treatments were established, with BW making up 0%, 3%, 5%, 7%, and 9% of the total substrate, and the effects on the mycelial growth and development, biological efficiency (BE), and yield were evaluated along with changes in the chemical biomass composition of the fruiting bodies. Adding BW increased the number of days needed for primordia initiation and the number of days between flushes of mushrooms. With increasing BW, the total fresh weight of mushrooms first increased and then decreased. The 5% BW treatment resulted in the highest yield and biological efficiency (BE) of 1,478.96 ± 9.61 g bag and 92.43 ± 0.60%, respectively, which exceeded the values of the control by 4.14% (control: 1,420.15 ± 9.53 g bag and 88.76 ± 0.60%, respectively). The 5% BW treatment also resulted in the highest mushroom crude protein content (23.47 ± 0.18 g 100 g ), which was 28.18% higher compared with the control (18.31 ± 0.05 g 100 g ). The 9% BW treatment resulted in the highest crude polysaccharide content (10.33 ± 0.76 g 100 g ), which was 2.42-fold that of the control (4.26 ± 0.30 g 100 g ). This study suggests that BW could serve as an effective source of nitrogen to cultivate . BW is a promising, cost-effective, and efficient additive to mushroom substrate, improving the yield and quality of mushrooms while providing a sustainable use for an otherwise difficult to dispose of waste product.
ISSN:2167-8359
2167-8359
DOI:10.7717/peerj.18726