HIGHLIGHTS TECHNOLOGICAL ASPECTS OF RECIRCULATORY AQUACULTURE MODULAR SYSTEM (RAS) AND PHYSIOLOGICAL PARAMETERS OF HYDROBIONTS ORGANISM

FAO (2023). FAO publications catalogue 2023. Rome. https://doi.org/10.4060/cc7285en

Béné C., Arthur R., Norbury H., Allison E. H., Beveridge M., Bush S., Campling L., Leschen W., Little D., Squires D., Thilsted S. H., Troell M., & Williams M. (2016). Contribution of fisheries and aquaculture to food security and poverty reduction: Assessing the current evidence. World Development, issue 79, рр.177–196

Subasinghe R., Soto D., & Jia J. (2009). Global aquaculture and its role in sustainable development. Reviews in Aquaculture, issue 1, vol.1, pp. 2–9.

Timmons M.B. (2002). Recirculating aquaculture system. Ithca Publishing Cooperation.

Turcios A. E., & Papenbrock J. (2014). Sustainable treatment of aquaculture effluents-What can we learn from the past for the future? Sustainability, issue 6, vol. 2, pp. 836–856.

Grynevych O.A., & Grynevych N.Ye. (2023). Retsyrkuliatsiini systemy v akvakulturi – ratsionalne vodovykorystannia ta bezpechnist produktsii. [Recirculation systems in aquaculture - rational water use and product safety]. Materials of the ukrainian scientific and practical conference of higher education graduates "Youth  agricultural science and production. Greening of production and nature protection as the basis of balanced development", Bila Tserkva, April 14, pp. 9–10

Grynevych N.Ye. (2018). Obgruntuvannia systemy sanitarno-hihiienichnykh zakhodiv za zamknutoho vodopostachannia v industrialnykh rybnytskykh hospodarstvakh [Justification of the system of sanitary and hygienic measures for closed water supply in industrial fish farms]: autoref. dissertations to be obtained. scientist degree of Doctor of Vet. of science [special] 16.00.06 - animal hygiene and veterinary sanitation.

Li H., Cui Z., Cui H., Bai Y., Yin Z., & Qu K. (2023). A review of influencing factors on a recirculating aquaculture system: Environmental conditions, feeding strategies, and disinfection methods. Journal of the World Aquaculture Society, issue 54, vol.3, рр. 566–602. https://doi.org/10.1111/jwas.12976

Johnston, I. A., & Bennett, A. F. (2008). Animals and temperature: Phenotypic and evolutionary adaptation, Cambridge University Press, Vol. 59.

Volkoff, H., & Rønnestad, I. (2020). Effects of temperature on feeding and digestive processes in fish. Temperature, issue 7, vol. 4, pp. 307–320.

Honcharova O. V., Sekiou O., & Kutishchev P. S. (2021). Fizioloho-biokhimichni aspekty adaptatsiino-kompensatornykh protsesiv hidrobiontiv za dii tekhnolohichnykh faktoriv. [Physiological and biochemical aspects of adaptation and compensatory processes of the organism of hydrobionts under the influence of technological factors]. Fisheries science of Ukraine. issue 4, vol. 58, pp.101–114. https://doi.org/10.15407/fsu2021.04.101

Dehtiarov P. A., Yevtushenko M. Yu., & Sherman I. M. (2008). Fiziolohiia ryb. Ahrarna osvita. Kyiv. [Physiology of fish]. Agricultural education, Kyiv, 341

Storey K. B. (1996). Oxidative stress: animal adaptations in nature. Brazilian Journal of Medical and Biological Research, issue 29, pp. 1715–1733

Гончарова О.В. (2023). Aspekty neirohumoralnoi rehuliatsii funktsionalnoi aktyvnosti orhanizmu ryb za umov vplyvu abiotychnykh ta biotychnykh chynnykiv (ohliad). [Aspects of neurohumoral regulation of the functional activity of the fish organism under the influence of abiotic and biotic factors (review)]. Fisheries science of Ukraine. issue 2, vol. 64, pp. 83108

Wei, Y., Jiao, Y., An, D., Li, D., Li, W., & Wei, Q. (2019). Review of dissolved oxygen detection technology: From laboratory analysis to online intelligent detection. Sensors, issue 19, vol. 18, pp. 3995

Ebeling, J. M., & Timmons, M. B. (2012). Recirculating aquaculture systems. Aquaculture Production Systems, Oxford, UK: Wiley-Blackwell, pp. 245–277

Jones S. W., Karpol A., Friedman S., Maru B. T., & Tracy B. P. (2020). Recent advances in single cell protein use as a feed ingredient in aquaculture. Current Opinion in Biotechnology, issue 61, рр. 189–197.

Deng, Y. L., Ruan, Y. J., Zhu, S. M., Guo, X. S., Han, Z. Y., Ye, Z. Y., Liu, G., & Shi, M. M. (2017). The impact of DO and salinity on microbial community in poly (butylene succinate) denitrification reactors for recirculating aquaculture system waste-water treatment. AMB Express, issue 7, vol. 1, pp. 1–11.

Кононенко Р.В. (2013) Vykorystannia ustanovky zamknutoho vodopostachannia pry intensyfikatsii vyrobnytstva ryboproduktsii. [The use of a closed water supply installation during the intensification of fish production. Fisheries science of Ukraine]. Fisheries science of Ukraine. issue 2, pp. 56–65.

Honcharova O., Bekh V. & Glamuzina B. (2023). Physiological and biochemical aspects of the carp organism in conditions of increasing their viability when stocking water bodies. Animal Science and Food Technology, issue 14, vol. 2. рр. 2843.

Honcharova O., Kutishchev P., & Korzhov Y. (2021). A Method to Increase the Viability of Cyprinus Carpio (Linnaeus, 1758). Stocking of the Aquatories Under the Influence Advanced Biotechnologies. Aquaculture Studies, issue 21, vol.4, pp.139148.

Koryliak M., Bernakevych O., Dobrianska O., & Bobeliak L. (2023). Diialnist systemy antyoksydantnoho zakhystu v orhanizmi molodi koropa pislia hoduvannia oliieiu roztoropshi pliamystoi. [Activity of the antioxidant protection system in the body of juvenile carp after feeding them with spotted thistle oil]. Fisheries science of Ukraine, issue 4, vol. 66, pp. 100–113.

Pivovarov O., Mykolenko S., & Honcharova O. (2018). Comprehensive food safety and quality assessment of plasma-chemically activated water usage Development of natural sciences in countries of the European Union taking into account the challenges of XXI. Izdevnieciba «Baltija Publishing» [Collective monograph]. The book is compiled by W.Klaczewski-Lublin, Poland. 480.

Bekh V., Martseniuk V., & Tushnytska N. (2000). Perspektyvy vykorystannia bilkovykh komponentiv netradytsiinoho pokhodzhennia v kombikormakh dlia akvakultury (Ohliad). [Outlook of using protein components of non‐traditional origin in aquaculture feeds (Review)]. Fisheries science of Ukraine. issue 2, vol. 52, pp. 53–64. https://doi.org/10.15407/fsu2020.02.053

Yevtushenko M. Yu., & Khyzhniak M. I. (2019). Metodolohiia naukovykh doslidzhen u rybnytstvi. [Methodology of scientific research in fish farming], Kyyiv, 296.

Zheltov Yu. Yu, Oleksiyenko O. O., & Grex V. I. (2016). Vy`kory`stannya deyaky`x netrady`cijny`x kormiv v godivli riznovikovy`x grup koropa. [The use of some non-traditional feeds when feeding groups of different ages]. Fisheries science of Ukraine. issue 1, pp. 102–105. https://fsu.ua/images/jurnal/2016-01v35/2016-01_102-105_Alekseenko.pdf

Xiumei Z., & Wenhua L. (2023). Physical enrichment for improving welfare in fish aquaculture and fitness of stocking fish: A review of fundamentals, mechanisms and applications. Aquaculture, issue 574, vol. 1, pp. 739651.

Honcharova O., Kutishchev P., & Korzhov Y. (2021). A Method to Increase the Viability of Cyprinus Carpio (Linnaeus, 1758). Stocking of the Aquatories Under the Influence Advanced Biotechnologies. Aquaculture Studies, issue 21, vol. (4), pp.139148.

Гончарова О.В. (2020). Funktsionalnyi status orhanizmu tyliapii v polikulturi Oreochromis mossambicus ta Florida red. [Functional status of the body of tilapia in the polyculture of Oreochromis mossambicus and Florida red]. Tavriysky Vestnik. issue. 111. Kherson, pp. 251257