Growing of replacement broodstock for australian red-claw crayfish(Cherax quadricarinatus) in industrial aquaculture

Australian red-claw crayfish Cherax quadricarinatus is a prospective species for aquaculture distinguished by high growth rate and good survival, in comparison with other cultivated crustaceans (shrimps, crabs). Results of experimental cultivation of this species under closed water supply with formation of the replacement broodstock are presented. The main stages of biotechnology are described. Size and weight properties of cultivated juveniles and indices of environmental quality are registered.

1. Arystangalieva, V.A., Development of technology for growing planting material of the Australian red-clawed crayfish (Сherax quadricarinatus) in an installation with closed water use, Cand. Sci. (Agricultural.) Dissertation, Moscow, 2017.

2. Borisov, R.R., Kovacheva, N.P., Akimova, M.Yu., and Parshin-Chudin, A.V., Biologiya i kul’tivirovaniye avstraliyskogo krasnokleshnevogo raka Cherax quadricarinatus (von Martens, 1868) (Biology and cultivation of the Australian red-lobed cancer Cherax quadricarinatus (von Martens, 1868)), Moscow: VNIRO, 2013.

3. Brynballe, Ya., Rukovodstvo po akvakul’ture v ustanovkakh zamknutogo vodosnabzheniya. Vvedeniye v novyye ekologicheskiye i vysokoproduktivnyye zamknutyye rybovodnyye sistemy (Guide to aquaculture in closed water supply installations. Introduction to new ecological and highly productive closed fish farming systems), Copenhagen: FAO, 2010.

4. Zhigin, A.V., Zamknutyye sistemy v akvakul’ture (Closed systems in aquaculture), Moscow: Publishing house of the Russian State Agricultural Academy named after K. A. Timiryazev, 2011.

5. Zhigin A.V., Arystangalieva V.A., and Kovacheva N.P., Influence of water temperature on growth and survival of australian red claw crayfish, in Prirodnyye resursy, ikh sovremennoye sostoyaniye, okhrana, promyslovoye i tekhnicheskoye ispol’zovaniye, 8-y Vseros. nauchn.-prakt. konf., posvyashchennaya 75-letiyu rybokhozyaystvennogo obrazovaniya na Kamchatke, Tezisy dokladov (Natural resources, their current status, protection, commercial and technical use, Proc. 8th All-Russ. Sci.-Pract. Conf., Commem. 75th Anniversary of Fisheries Education in Kamchatka), PetropavlovskKamchatsky: Kamchatka State Technical University, 2017, part 1, pp. 86–89.

6. Kolmykov, E.V., Instruktsiya po razvedeniyu rechnykh rakov (Instructions for breeding river crayfish), Astrakhan: Kasp. Nauchno-Issled. Inst. Rybn. Khoz., 2004.

7. Kupinsky, S.B., Produktsionnyye vozmozhnosti rybokhozyaystvennykh vodoyemov i ob”yektov rybovodstva (Production capabilities of fisheries reservoirs and fish farming facilities), St. Petersburg: Lan, 2019.

8. Kupinsky, S.B., Rainbow trout — preliminary parameters of the standard model of mass accumulation, in Sb. nauchn. tr. VNIIPRKH “Industrial’noye rybovodstvo v zamknutykh sistemakh”, 1986, no. 46, pp. 109–115.

9. Lagutkina, L.Y., Mart’yanov, A.S., Stepanov, R.V., and Shahveranov, K.G., Optimization of the technology of feeding Australian crayfish through the use of experimental feeds formulas, Vestnik Astrakh. Gos. Tekh. Univ., Ser. Ryb. khoz-vo, 2016, no. 1, pp. 77–86.

10. Khoroshko, A.I. and Kryuchkov, V.N., RF Patent no. 2709973, IPC A01K 61/00 (2006.01), Method rearing of tropical species in pond polyculture, Byul., 2019, no. 36.

11. Shokasheva, D.I., Growth of australian crayfish (Cherax quadricarinatus) juveniles in industrial conditions depending on the environment temperature, Vestnik Astrakh. Gos. Tekh. Univ., Ser. Ryb. khoz-vo, 2018, no. 2, pp. 98–103. doi 10.24143/2073-5529-2018-2-98-103

12. De Bock, M.S. and López Greco, L.S., Sex reversal and growth performance in juvenile females of the freshwater crayfish Cherax quadricarinatus (Parastacidae): effect of increasing temperature and androgenic gland extract in the diet, Aquacult. Int., 2010, no. 18, pp. 231–243. doi 10.1007/s10499-008-9239-x

13. Lawrence, C. and Jones, C., Chapter Chera, Biology of Freshwater Crayfish, Oxford: Blackwell Science, 2002, pp. 635–670.

14. Meade, M.E., Doeller, J.E., Kraus, D.W., and Walls, S.A., Effects of temperature and salinity on weight gain, oxygen consumption rate, and growth efficiency in juvenile red-claw crayfish Cherax quadricarinatus, Journal of the World Aquaculture Society, 2002, vol. 33, no. 2, pp. 188–198.

15. Sagi, A., Milstein, A., Eran, Y., Joseph, D., Khalaila, I., Abdu, U., Harpaz, S., and Karplus, I., Culture of the Australian red-claw crayfish (Cherax quadricarinatus) in Israel. II. Second growout season of overwintered populations, Israeli J. Aquacult. — Bamidgeh, 1997, vol. 49, P. 222–229.

16. Saoud, I.P., Ghanawi, J., Thompson, K.R., and Webster, C.D., A review of the culture and diseases of redclaw crayfish Cherax quadricarinatus (Von Martens 1868, Journal of the World Aquaculture Society, 2013, vol. 44, no. 1, pp. 1–29. doi 10.1111/jwas.12011

17. Souty-Grosset, C., Holdich, D.M., Noel, P.Y., and Reynolds, J.D., Atlas of Crayfish Europe, Paris: Museum national d’Histoire naturelle, 2006.

18. Xiaoxuan, C., Zhixin, W., and Licai, H., Effects of water temperature on ingestion and growth of Cherax quadricarinatus, J. Huazhong (Central China) Agricultural University, 1995, vol. 14(5), pp. 477–480.

19. Food systems for better nutrition: The state of food and agriculture. Rome: FAO Fisheries and Aquaculture Department, 2013. http://www.fao.org/publications/sofa/2013/en. Cited August 27, 2021.

20. RD 52.24.496-2018. Metodika izmereniy temperatury, prozrachnosti i opredeleniya zapakha vody (RD 52.24.496-2018. Method of measuring temperature, transparency and determination of the smell of water), Rostov-na Donu: Gidrokhimicheskiy institut, 2018.

21. RD 52.24.419-2005. Massovaya kontsentratsiya rastvorennogo kisloroda v vodakh. Metodika vypolneniya izmereniy yodometricheskim metodom (RD 52.24.419-2005. Mass concentration of dissolved oxygen in water. The method of performing measurements by the iodometric method), Rostov-na-Donu: Federal’naya sluzhba Rossii po gidrometeorologii i monitoringu okruzhayushchey sredy, 2004.

22. PND F 14.1:2:3:4.121-97. Kolichestvennyy khimicheskiy analiz vod. Metodika vypolneniya izmereniy pH v vodakh potentsiometricheskim metodom (PND F 14.1:2:3:4.121-97. Quantitative chemical analysis of waters. Measurement procedure pH in waters by the potentiometric method), Moscow: Federal’nyy tsentr analiza i otsenki tekhnogennogo vozdeystviya, 2016.

23. PND F 14.1:2:3.1-95. Kolichestvennyy khimicheskiy analiz vod. Metodika izmereniy massovoy kontsentratsii ionov ammoniya v prirodnykh i stochnykh vodakh fotometricheskim metodom s reaktivom Nesslera (PND F 14.1:2:3.1-95. Quantitative chemical analysis of waters. Method of measuring the mass concentration of ammonium ions in natural and wastewater by photometric method with Nessler reagent), Moscow: Federal’nyy tsentr analiza i otsenki tekhnogennogo vozdeystviya, 2017.

24. RD 52.24.381-2017. Massovaya kontsentratsiya nitritnogo azota v vodakh. Metodika izmereniy fotometricheskim metodom s reaktivom Grissa (RD 52.24.381-2017. Mass concentration of nitrites in waters. The method of performing measurements by the photometric method with the Griss reagent), Rostov-na-Donu: Gidrokhimicheskiy institut, 2017.

25. RD 52.24.380-2017. Massovaya kontsentratsiya nitratnogo azota v vodakh. Metodika izmereniy fotometricheskim metodom s reaktivom Grissa posle vosstanovleniya v kadmiyevom reduktore (RD 52.24.380-2017. Mass concentration of nitrate nitrogen in waters. Measurement technique by photometric method with Griss reagent after reduction in a cadmium reducer), Rostov-na-Donu: Gidrokhimicheskiy institut, 2017.