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eISSN
2300-8733
Pierwsze wydanie
25 Nov 2011
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4 razy w roku
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Angielski
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The use of artemia for aquaculture industry: An updated overview

Data publikacji: 15 Jun 2022
Tom & Zeszyt: AHEAD OF PRINT
Zakres stron: -
Otrzymano: 20 Dec 2021
Przyjęty: 11 May 2022
Informacje o czasopiśmie
License
Format
Czasopismo
eISSN
2300-8733
Pierwsze wydanie
25 Nov 2011
Częstotliwość wydawania
4 razy w roku
Języki
Angielski
Abstract

The increasing global population tends many sectors to overcome the food security issue; sustainable aquaculture is one of the systems that reveal the food problem in the world. The aquaculture industry is drastically increasing to offer the growing demand for this food type. The high mortalities threaten this sector during the first larval stages because of the low supplies of suitable feed for the fish larva. Artemia is vital for the aquaculture industry as it is the primary feed source for fish larvae; it is distinguished by its small size, food carrier characteristic, and off-the-shelf food feature. However, the principal source of artemia cysts has been affected by climate change, ultimately affecting artemia cyst production. Consequently, many areas worldwide try to produce artemia locally to satisfy the aquaculture rearing requirements. As a feed transmitter, artemia can be enriched with essential elements to feed the fish larvae; this method increases survivability, growth performance, and other growth indicators for many fish species. This review aimed to update the academia and stakeholders involved in artemia production in relation to the aquaculture industry. An updated overview of artemia production is also presented in the current review.

Keywords

Akbary P., Hosseini S.A., Imanpoor M.R. (2011). Enrichment of Artemia nauplii with essential fatty acids and vitamin C: effect on rainbow trout (Oncorhynchus mykiss) larvae performance. Iran J. Fish. Sci., 10: 557–569. Search in Google Scholar

Al Dhaheri S., Saji A. (2013). Water quality and brine shrimp (Artemia sp.) population in Al Wathba Lake, Al Wathba wetland reserve, Abu Dhabi emirate, UAE. Int. J. Biodivers. Conserv., 5: 281–288. Search in Google Scholar

Anderson G.J., McLaren G.D. (2012). Iron physiology and pathophysiology in humans. Springer. Search in Google Scholar

Ayón P., Criales-Hernandez M.I., Schwamborn R., Hirche H.-J. (2008). Zooplankton research off Peru: A review. Prog. Oceanogr., 79: 238–255. Search in Google Scholar

Belmonte G., Moscatello S., Batogova E., Pavlovskaya T., Shadrin N., Litvinchuk L. (2012). Fauna of hypersaline lakes of the Crimea (Ukraine). Thalassia Sal., 34: 11–24. Search in Google Scholar

Bengtson D.A., Léger P., Sorgeloos P. (2018). Use of Artemia as a food source for aquaculture, Artemia biology. CRC Press, pp. 255–286. Search in Google Scholar

Boglino A., Darias M.J., Ortiz-Delgado J.B., Özcan F., Estévez A., Andree K.B., Hontoria F., Sarasquete C., Gisbert E. (2012). Commercial products for Artemia enrichment affect growth performance, digestive system maturation, ossification and incidence of skeletal deformities in Senegalese sole (Solea senegalensis) larvae. Aquaculture, 324: 290–302. Search in Google Scholar

Camara M.R. (2020). After the gold rush: A review of Artemia cyst production in northeastern Brazil. Aquac. Rep., 17: 100359–100359. Search in Google Scholar

Cavrois-Rogacki T., Rolland A., Migaud H., Davie A., Monroig O. (2020). Enriching Artemia nauplii with selenium from different sources and interactions with essential fatty acid incorporation. Aquaculture, 520: 734677–734677. Search in Google Scholar

Chaoruangrit L., Plodsomboon S., Rogers D.C., Sanoamuang L.-O. (2017). Morphology of mandibles and food size in two fairy shrimps (Branchiopoda: Anostraca) from Thailand. J. Crust. Biol., 37: 579–587. Search in Google Scholar

Choi D.H., Youn B.I., Kim M.J., Lee S.H., Lee S.J. (2021). Maturation and spawning of the Pacific cod Gadus macrocephalus in the West Coast of Yellow Sea of Korea. Korean J. Fish Aquat. Sci., 54: 46–52. Search in Google Scholar

Dawood M.A.O. (2021). Nutritional immunity of fish intestines: important insights for sustainable aquaculture. Rev. Aquac., 13: 642–663. Search in Google Scholar

FAO (2020). National Aquaculture Sector Overview. Egypt. National Aquaculture Sector Overview Fact Sheets. Text by Salem A.M., Saleh M.A. In: FAO Fisheries and Aquaculture Department [online]. Rome. Updated 16 November 2010. [Cited 11 May 2020]. Retrieved from http://www.fao.org/fishery/countrysector/naso_egypt/en. Search in Google Scholar

Francis D.S., Cleveland B.J., Jones P.L., Turchini G.M., Conlan J.A. (2019). Effects of PUFA-enriched Artemia on the early growth and fatty acid composition of Murray cod larvae. Aquaculture, 513: 734362. Search in Google Scholar

Hasan M.R. (2016). FAO Expert workshop on sustainable use and management of Artemia resources in Asia. Retrieved from https://www.fao.org/fileadmin/user_upload/affris/docs/PowerPoint_Presentations.pdf. Search in Google Scholar

Hefnawy A.E.G., Tórtora-Pérez J.L. (2010). The importance of selenium and the effects of its deficiency in animal health. Small Rumin. Res., 89: 185–192. Search in Google Scholar

Islam S.U., Ahmed M.B., Shehzad A., Lee Y.S. (2019). Methanolic extract of Artemia salina eggs and various fractions in different solvents contain potent compounds that decrease cell viability of colon and skin cancer cell lines and show antibacterial activity against Pseudomonas aeruginosa. Evid. Based Complement. Alternat. Med., 2019: 9528256. Search in Google Scholar

Jamali H., Ahmadifard N., Noori F., Agh N., Gisbert E. (2018). Improving co-feeding strategies for Neotropical green terror cichlid (Aequidens rivulatus) larvae with lecithin-enriched Artemia franciscana nauplii: Effects on survival, growth performance and body composition. Aquac. Res., 49: 3909–3918. Search in Google Scholar

Juhász P., Lengyel S., Udvari Z., Sándor A.N., Stündl L. (2017). Optimised selenium enrichment of Artemia sp. feed to improve Red Drum (Sciaenops ocellatus) larvae rearing. Acta Biol. Hung., 68: 255–266. Search in Google Scholar

Kamaszewski M., Wójcik M., Ostaszewska T., Kasprzak R., Kolman R., Prusińska M. (2014). The effect of essential fatty acid (EFA) enrichment of Artemia sp. nauplii on the enzymatic activity of Atlantic sturgeon (Acipenser oxyrinchus Mitchill, 1815) larvae – preliminary study. J. Appl. Ichthyol., 30: 1256–1258. Search in Google Scholar

Kandathil Radhakrishnan D., AkbarAli I., Schmidt B.V., John E.M., Sivanpillai S., Thazhakot V.S. (2020). Improvement of nutritional quality of live feed for aquaculture: An overview. Aquac. Res., 51: 1–17. Search in Google Scholar

Kideys A.E., Kovalev A.V., Shulman G., Gordina A., Bingel F. (2000). A review of zooplankton investigations of the Black Sea over the last decade. J. Mar. Syst., 24: 355–371. Search in Google Scholar

Łączyńska B., Palińska-Żarska K., Nowosad J., Biłas M., Krejszeff S., Müller T., Kucharczyk D., Żarski D. (2016). Effect of age, size and digestive tract development on weaning effectiveness in crucian carp, Carassius carassius (Linnaeus, 1758). J. Appl. Ichthyol., 32: 866–872. Search in Google Scholar

Lavens P., Sorgeloos P. (2000). The history, present status and prospects of the availability of Artemia cysts for aquaculture. Aquaculture, 181: 397–403. Search in Google Scholar

Lim C., Klesius P.H., Li M.H., Robinson E.H. (2000). Interaction between dietary levels of iron and vitamin C on growth, hematology, immune response and resistance of channel catfish (Ictalurus punctatus) to Edwardsiella ictaluri challenge. Aquaculture, 185: 313–327. Search in Google Scholar

Litvinenko L.I., Litvinenko A.I., Boiko E.G., Kutsanov K. (2015). Artemia cyst production in Russia. Chin. J. Oceanol. Limnol., 33: 1436–1450. Search in Google Scholar

Morais S., Conceição L.E.C., Rønnestad I., Koven W., Cahu C., Infante J.L.Z., Dinis M.T. (2007). Dietary neutral lipid level and source in marine fish larvae: effects on digestive physiology and food intake. Aquaculture, 268: 106–122. Search in Google Scholar

Mugwanya M., Dawood M.A., Kimera F., Sewilam H. (2021). Biofloc systems for sustainable production of economically important aquatic species: A review. Sustainability, 13: 7255. Search in Google Scholar

Naganawa H., Mura G. (2017). Two new cryptic species of Artemia (Branchiopoda, Anostraca) from Mongolia and the possibility of invasion and disturbance by the aquaculture industry in East Asia. Crustaceana, 90: 1679–1698. Search in Google Scholar

Nevejan N., De Schryver P., Wille M., Dierckens K., Baruah K., Van Stappen G. (2018). Bacteria as food in aquaculture: do they make a difference? Rev. Aquac., 10: 180–212. Search in Google Scholar

Nielsen R., Nielsen M., Abate T.G., Hansen B.W., Jepsen P.M., Nielsen S.L., Støttrup J.G., Buchmann K. (2017). The importance of live-feed traps – farming marine fish species. Aquac. Res., 48: 2623–2641. Search in Google Scholar

Pacitti D., Lawan M.M., Sweetman J., Martin S.A.M., Feldmann J., Secombes C.J. (2015). Selenium supplementation in fish: A combined chemical and biomolecular study to understand Sel-Plex assimilation and impact on selenoproteome expression in rainbow trout (Oncorhynchus mykiss). PLoS One, 10: e0127041–e0127041. Search in Google Scholar

Pérez-Rodríguez J.C., Yamasaki-Granados S., García-Guerrero M.U., Martínez-Porchas M., Méndez-Martínez Y., Latournerié-Cervera J.R., Cortés-Jacinto E. (2018). Growth and survival of juvenile cauque river prawn Macrobrachium americanum fed with diets containing different protein levels. Lat. Am. J. Aquat. Res., 46: 534–542. Search in Google Scholar

Prusińska M., Nowosad J., Jarmołowicz S., Mikiewicz M., Duda A., Wiszniewski G., Sikora M., Biegaj M., Samselska A., Arciuch-Rutkowska M., Targońska K., Otrocka-Domagała I., Kucharczyk D. (2020). Effect of feeding barbel larvae (Barbus barbus (L, 1758)) Artemia sp. nauplii enriched with PUFAs on their growth and survival rate, blood composition, alimentary tract histological structure and body chemical composition. Aquac. Rep., 18: 100492. Search in Google Scholar

Putra D., Trisyahdar T., Dewiyanti I., Muhammadar A. (2018). Effect of enhanced Artemia with gamat emulsion on growth performance and survival rate of white shrimp Litopenaeus vannamei larvae, IOP Conference Series: Earth and Environmental Science. IOP Publishing, p. 012005. Search in Google Scholar

Rasdi N.W., Qin J.G. (2016). Improvement of copepod nutritional quality as live food for aquaculture: a review. Aquac. Res., 47: 1–20. Search in Google Scholar

Rezaei Aminlooi V., Ahmadifard N., Tukmechi A., Agh N. (2019). Improvement of reproductive indices, lysozyme activity, and disease resistance in live-bearing ornamental fish, Poecilia latipinna using Artemia supplementation with treated yeast cell, Saccharomyces cerevisiae. Aquac. Res., 50: 72–79. Search in Google Scholar

Roo J., Hernández-Cruz C.M., Mesa-Rodriguez A., Fernández-Palacios H., Izquierdo M.S. (2019). Effect of increasing n-3 HUFA content in enriched Artemia on growth, survival and skeleton anomalies occurrence of greater amberjack Seriola dumerili larvae. Aquaculture, 500: 651–659. Search in Google Scholar

Sorgeloos P. (1980). The use of the brine shrimp Artemia in aquaculture. The brine shrimp Artemia, 3: 25–46. Search in Google Scholar

Sui L., Ren B., Wang S., Gao M., Van Stappen G. (2020). Archaea Haloferax supplementation improves Artemia biomass production in hypersaline conditions. Aquaculture, 528: 735540–735540. Search in Google Scholar

Tacon A.G.J., Cowey C.B. (1985). Protein and amino acid requirements. Springer, 155–183. Search in Google Scholar

Toi H.T., Boeckx P., Sorgeloos P., Bossier P., Van Stappen G. (2013). Bacteria contribute to Artemia nutrition in algae-limited conditions: A laboratory study. Aquaculture, 388–391: 1–7. Search in Google Scholar

Tonheim S.K., Koven W., Rønnestad I. (2000). Enrichment of Artemia with free methionine. Aquaculture, 190: 223–235. Search in Google Scholar

Tórtora-Pérez J.L. (2010). The importance of selenium and the effects of its deficiency in animal health. Small Rumin. Res., 89: 185–192. Search in Google Scholar

Treece G.D. (2000). Artemia production for marine larval fish culture. Southern Regional Aquaculture Center Stoneville, Mississippi. Search in Google Scholar

Vajargah M.F., Hashemi G., Bibak M., Yalsuyi A.M. (2021). The effect of vitamin c-fortified Artemia on growth and survival of Sepia pharaonis larvae. J. Environ. Treat. Tech., 9: 815–818. Search in Google Scholar

Van Stappen G., Sui L., Hoa V.N., Tamtin M., Nyonje B., de Medeiros Rocha R., Sorgeloos P., Gajardo G. (2020). Review on integrated production of the brine shrimp Artemia in solar salt ponds. Rev. Aquac., 12: 1054–1071. Search in Google Scholar

Ζαχίδου Χ.Β. (1995). Εμπλουτισμός με HUFA (Highly Unsaturated Fatty Acids-Πολυακόρεστα λιπαρά οξέα) της αλμυρογαρίδας Artemia salina: επίδραση εμπορικών παρασκευασμάτων στην ανάπτυξή της. Search in Google Scholar

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