Scientific Reports of the National University of Life and Environmental Sciences of Ukraine

Vermiculture cultivation on a substrate containing composted wheat straw using an accelerated method

Larysa Mitioglo, Serhii Merzlov, Halyna Merzlova, Pavlo Kovtun, Inna Osipenko
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Abstract

The relevance of the study is conditioned by the need to improve the technology of manufacturing substrates for vermiculture growing, which is important for obtaining high-quality organic fertiliser and improving the efficiency of biotechnological processes for organic waste disposal. The goal was to determine the optimal dose of fermented wheat straw as part of the substrate to increase the growth, development and reproductive capacity of vermiculture. The experiment was conducted in the vivarium of the Bila Tserkva National Agrarian University on seven groups of microbeds formed based on bovine cattle manure with varying contents of composted wheat straw. The Control Group contained cattle manure and only fresh crushed straw, and the substrate from the experimental microbeds included 2.0-6.0% fermented wheat straw. One hundred sexually mature worms were placed in each microbed. For 125 days, the number and weight of sexually mature and non-sexually mature individuals, the number and weight of their cocoons were monitored. The results were processed using variational statistics methods. The best indicators were found with the introduction of 3.0-4.0% of composted straw in the substrate. In these groups, a significant increase in the number and biomass of worms, and an increase in the number of cocoons were recorded. It was recorded that the optimal level of composted straw contributed to improving the adaptation of the population, increasing the number and weight of sexually mature worms in the experimental microbeds. Exceeding the content of composted wheat straw to 5.0-6.0% did not provide an increase in the number of worms in microbeds. This indicates the presence of an upper limit of the population’s tolerance to an increase in the carbon-to-nitrogen ratio in the substrate. It was determined that the optimal dose is 3.0% composted wheat straw, which provides a statistically significant increase in the number and weight of worms compared to the Control. The use of this dose helped to maintain a biologically balanced ratio of nutrients and created conditions for effective reproduction and development of vermiculture. The results obtained can be used to develop effective methods for growing vermiculture based on composted wheat straw, which will help to improve soil fertility and increase the efficiency of organic farming

Keywords

hybrid Red California worms, worm cocoons, microbed, sexually mature individuals, fermentation

Suggested citation
Mitioglo, L., Merzlov, S., Merzlova, Halyna, Kovtun, P., & Osipenko, I. (2026). Vermiculture cultivation on a substrate containing composted wheat straw using an accelerated method. Scientific Reports of the National University of Life and Environmental Sciences of Ukraine, 22(1),22-35. https://doi.org/10.31548/dopovidi/1.2026.22
References
  1. Ahmad, I., Hussain, A., Akhtar, N., & Raza, M.A. (2022). Wheat-straw vermicompost improves drought tolerance in wheat. Frontiers in Environmental Science, 10, article number 894517. doi: 10.3389/fenvs.2022.894517.
  2. Alwaneen, W.S. (2016). Cow manure composting by microbial treatment for using as potting material: An overview. Pakistan Journal of Biological Sciences, 19(1), 1-10. doi: 10.3923/pjbs.2016.1.10.
  3. Brown, K.D. (2019). Earthworm recorder’s handbook. Shrewsbury: Earthworm society of Britain.
  4. Cao, Y., Tian, Y., Wu, Q., Li, J., & Zhu, H. (2021). Vermicomposting of livestock manure as affected by carbon-rich additives (straw, biochar and nanocarbon): A comprehensive evaluation of earthworm performance, microbial activities, metabolic functions and vermicompost quality. Bioresource Technology, 320(Pt B), article number 124404. doi: 10.1016/j.biortech.2020.124404.
  5. Convention on Biological Diversity. (1992, June). Retrieved from https://zakon.rada.gov.ua/laws/show/995_030#Text.
  6. Havekes, C.D., Duffield, T.F., Carpenter, A.J., & DeVries, T.J. (2020a). Effects of wheat straw chop length in high-straw dry cow diets on intake, health, and performance of dairy cows across the transition period. Journal of Dairy Science, 103(1), 254-271. doi: 10.3168/jds.2019-17033.
  7. Havekes, C.D., Duffield, T.F., Carpenter, A.J., & DeVries, T.J. (2020b). Effects of molasses-based liquid feed supplementation to a high-straw dry cow diet on feed intake, health, and performance of dairy cows across the transition period. Journal of Dairy Science, 103(6), 5070-5089. doi: 10.3168/jds.2019-18085.
  8. Herasymenko, V.H. (Ed.). (2006). Biotechnology. Kyiv: “INKOS” Company.
  9. Leet, J.K., & Volz, D.C. (2013). Improving waste management strategies for small livestock farms. Environmental Science & Technology, 47(21), 11940-11941. doi: 10.1021/es404078b.
  10. Mitiohlo, L.V., Merzlov, S.V., & Merzlova, H.V. (2023). Physical and chemical indicators of wheat straw fermented with a biodestructor of domestic production. Scientific Messenger of Lviv National University of Veterinary Medicine and Biotechnologies. Series: Agricultural sciences, 25(99), 114-119. doi: 10.32718/nvlvet-a9919.
  11. Nasiru, A., Ismail, N., & Ibrahim, M.H. (2013). Vermicomposting: Tool for sustainable ruminant manure management. Journal of Waste Management, 2013, article number 732759. doi: 10.1155/2013/732759.
  12. Nigussie, A., Dume, B., Ahmed, M., Mamuye, M., Ambaw, G., Berhiun, G., Biresaw, A., & Aticho, A. (2021). Effect of microbial inoculation on nutrient turnover and lignocellulose degradation during composting: A meta-analysis. Waste Management, 125, 220-234. doi: 10.1016/j.wasman.2021.02.043.
  13. Osipenko, I.S., & Merzlov, S.V. (2023). Biochemical and chemical composition of vermiculture biomass Grown on poultry litter fermented by the accelerated method. Scientific and Technical Bulletin of the State Scientific Research Control Institute of Veterinary Medical Products And Fodder Additives and Institute of Animal Biology, 24(1), 105-113. doi: 10.36359/scivp.2023-24-1.15.
  14. Sahu, A., Sankla, S., Bhattacharjya, S., Sahu, N., Bharati, K., & Devi, M.H. (2025). Enhancing composting efficiency: Thermophilic lignocellulolytic microbes for bioconversion of rice and wheat straw. Journal of Advances in Biology & Biotechnology, 28(2), 786-799. doi: 10.9734/jabb/2025/v28i22039.
  15. Shen, X., Huang, G., Yang, Z., & Han, L. (2015). Compositional characteristics and energy potential of Chinese animal manure by type and as a wholeApplied Energy160, 108-119. doi: 10.1016/j.apenergy.2015.09.034.
  16. Sun, Q., Gu, X.J., Wang, Y.F., Gao, H.S., Wang, X.J., Chen, X.L., & Sun, S.M. (2025). Impact of straw return on greenhouse gas emissions from maize fields in China: Meta-analysis. Frontiers in Plant Science, 16, article number 1493357. doi: 10.3389/fpls.2025.1493357.
  17. Tuyttens, F.A.M. (2005). The importance of straw for pig and cattle welfare: A review. Applied Animal Behaviour Science, 92(3), 261-282. doi: 10.1016/j.applanim.2005.05.007.
  18. Vyas, P., Sharma, S., & Gupta, J. (2022). Vermicomposting with microbial amendment: Implications for bioremediation of industrial and agricultural waste. Biotechnologia, 103(2), 203-215. doi: 10.5114/bta.2022.116213.
  19. Wang, Y., Yu, Q., Zheng, C., Wang, Y., Chen, H., Dong, S., & Hu, X. (2024). The impact of microbial inoculants on large-scale composting of straw and manure under natural low-temperature conditions. Bioresource Technology, 400, article number 130696. doi: 10.1016/j.biortech.2024.130696.
  20. Zekker, I., Kivirüüt, A., Rikmann, E., Mandel, A., Jaagura, M., Tenno, T., Artemchuk, O., Rubin, S.D., & Tenno, T. (2019). Enhanced efficiency of nitritating-anammox sequencing batch reactor achieved at low decrease rates of oxidation-reduction potential. Environmental Engineering Science, 36(3), 350-360. doi: 10.1089/ees.2018.0225.
  21. Zekker, I., Raudkivi, M., Artemchuk, O., Rikmann, E., Priks, H., Jaagura, M., & Tenno, T. (2021). Mainstream-sidestream wastewater switching promotes anammox nitrogen removal rate in organic-rich, low-temperature streams. Environmental Technology, 42(19), 3073-3082. doi: 10.1080/09593330.2020.1721566.
  22. Zhang, H., Li, G., Gu, J., Wang, G., Li, Y., & Zhang, D. (2016). Influence of aeration on volatile sulfur compounds (VSCs) and NH3 emissions during aerobic composting of kitchen waste. Waste Management, 58, 369-375. doi: 10.1016/j.wasman.2016.08.022.