Morphology of the (Alburnus chalcoides) during growth

Document Type : Morphology

Authors

1 Department of Marine Biology, Faculty of Marine Science and Technology, Islamic Azad University, Tehran, Iran

2 Iran Fisheries Science Research Institute, Agricultural Research and Training Organization, Tehran, Iran

3 Inland Water Aquaculture Research Institute, National Fisheries Sciences Research Institute, Agricultural Research and Training Organization, Bandar Anzali, Iran

Abstract

The Alburus chalcoides (Guendenstaedt, 1772), of Cyprinidae family, is a valuable bony fish of the Caspian Sea. Checking the start of a feedind is one of the most significant cases of larval growth. Actually, Specifying the day of opening the mouth of the fish and the day the active nutrition and pelleting is started will also affect the growth of the fish, especially as the guinea pig fish feed more on protein sources and this will speed up the digestion and absorption of food. The King of Gypsy was opened from the fifth day after hatching his mouth and was seen as a gutter. To evaluate morphological characteristics of larvae and infants, 10 samples were considered.The length of larvae on this day is 4.6 ± 2.2 mm and weighs 0.010 g. On this day, larvae can use environmental food in the water, but given the size of the mouth of this fish on the eighth day to the size The size is 84 micrometers (5.5 ± 4.4 mm in length and 0.013 grams in weight). This day was calculated as a starting point for feeding pellets, which could be used for larvae in addition to perennial food from pellet. The purpose of this research is to determine the appropriate feeding time for fish.

Keywords

References

  1. Chakrabarti, R.; Rathore, R.M.; Mittal, P. and Kumar, S., 2006. Functional changes in digestive enzymes and characterization of proteases of silver carp and bighead carp hybrid, during early ontogeny. Aquaculture. Vol. 253, pp: 694-702.
  2. Chapman, D.C. and George, A., 2011. Developmental rate and behavior of early life stages of Bighead Carp and Silver Carp. 62 p.
  3. Dabrowski, K. and Bardega, R., 1984. Mouth size and predicted food size preferences of larvae of three cyprinid fish species. Aquaculture. Vol. 40, pp: 41-46.
  4. Dos-Santos, M.; Arantes, F.; Santiago, K. and Dos-santos, E.J., 2015. Morphological characteristics of the digestive tract of Schizodon knerii (Steindachner, 1875), (Characiformes: Anostomidae): An anatomical, histological and histochemical study. Vol. 87, No. 2, pp: 867-878.
  5. Gawlicka, A.; Parent, B.; Horn, M.H.; Ross, N.; Opstad, I. and Torrissen, O.J., 2000. Activity of digestive enzymes in yolk-sac larvae of Atlantic halibut (Hippoglossus hippoglossus): indication of readiness for first feeding. Aquaculture.Vol. 184, pp: 303-314.
  6. Gozlan, E.R.; Gordon, H. and Noel, T., 1999. Early development of the sofie, Chondrostoma toxostoma. Environmental biology of fishes. Vol. 56, pp: 67-77.
  7. Hazzaa, R. and Hussein, A., 2007. Larval Development of Himri, Barbus luteus (Cyprinidae: Cypriniformes) Reared in the Laboratory. Turkish Journal of Zoology. Vol. 31, pp: 27-33.
  8. He, T.; Xiao, Zh.; Liu, Q.; Ma, D.; Xu, Sh.; Xiao, Y. and Li, J., 2012. Ontogeny of the digestive tract and enzymes in rock bream Oplegnathus fasciatus larvae. J. Fish Physiol Biochem. Vol. 38, pp: 297-308.
  9. Jafari, M.; Kamarudin, M.S.; Saad, C.R.; Arshad, A.; Oryan, S. and Bahmani, M., 2009. Development of Morphology in Hatchery-Reared Rutilus frisii kutum Larvae. European Journal of Scientific Research. Vol. 38, No. 2, pp: 296-305.
  10. Kim, B.G.; Divakaran, S.; Brown, C.L. and Ostrowski, A., 2001. Comparative digestive enzyme ontogeny in two marine larval fishes: Pacific threadfin (Polydactylus sexfilis) and bluefin trevally (Caranx melampygus). Journal of Fish Physiology and Biochemistry. Vol. 24, pp: 225-241.
  11. Khoshnood, Z.; Jamili, SH.; Khodabandeh, S.; Mashinchian moradi, A. and Motalebi, A., 2014. Studying the Structure and Ultrastructure and Immunolocalization of the Gill Chloride cells in Caspian Kutum, Rutilus frisii kutum Fry. Journal of Animal Researches, Vol. 27, No. 4, 
    pp: 498- 508.
  12. Rajabi Nezhad, R. and Azari Takami, G., 2009. A study of feeding habits of Caspian Shemaya (Shah-Koolee) Chalcalburnus chalcoides (Guldenstadt, 1772) in the Sefidrood river. Journal of marine biology. Vol. 1, No. 3, pp: 45-63.
  13. Ramezani-Fard, E.; Kamarudin, M.S.; Harmin, S.A.; Saad, C.R.; Abd Satar, M.K. and Daud, S.K., 2011. Ontogenic development of the mouth and digestive tract in larval Malaysian mahseer, Tor tambroides Bleeker,1854. Applied Ichthyology. Vol. 27, pp: 920-927.
  14. Ronnestad, R.; Dominguez, R.P. and Tanaka, M., 2000. Ontogeny of digestive tract functionality in Japanese flounder, Paralichthys olivaceus studied by in vivo microinjection: pH and assimilation of free amino acids. Fish physiology and biochemistry. Vol. 22, pp: 225-235.
  15. Ronnestad, I.; Koven, W.M.; Tandler, A.; Harel, M. and Fyhn, H.J, 1998. Utilisation of yolk fuels in developing eggs and larvae of European sea bass (Dicentrarchus labrax). Aquaculture. Vol. 162, pp: 157-170.
  16. Theilacker, A., 1978. Effect of star vatton on the histological and morphological characteristics of jack mackerel, Trachurus symmetricus larvae. Fishery bulletin. Vol. 76, No. 2, pp: 403-414.
  17. Okan Kamaci, H.; Suzer, C.; Coban, D.; Saka, S. and Firat, K., 2010. Organogenesis of exocrine pancreas in sharpsnout sea bream (Diplodus puntazzo) larvae: characterization of trypsin expression. J. Fish Physiol Biochem. Vol. 36, pp: 993-1000.
  18. Winkler, H. and Orellana, C.P., 1992. The costs of mixed prey for a planktivorous cyprinid, Chalcalburnus chalcoides mento. Journal of biology Environmental Fish. Vol. 35, No. 1, pp: 85-93.
  19. Yaghoubi, M.; Amiri, B.; Nematollahi, M.A. and Yelghi, S., 2014. Histological development of the alimentary channel of Caspian Roach (Rutilus rutilus caspicus). Journal of Fisheries. Vol. 67, No. 4, pp: 625- 639.
Journal of Animal Environment
Volume 11, Issue 3
October 2019
Pages 163-172

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