Un Panorama de los Presupuestos de Nitrógeno para Cultivo de Camarón

Authors

  • Mayra L. González-Félix Universidad de Sonora.
  • Martín Pérez-Velázquez Universidad de Sonora.

Keywords:

shrimp, L. vannamei, nitrogen budget, zero water exchange

Abstract

In recent years, aquaculture research has focused on the minimization of its impact on the environment as effluents
produced by this activity contribute to the eutrophication of the receiving water bodies by the addition of organic
matter and nutrients. Nitrogen is one of these nutrients; it is introduced into culture systems mostly through the
addition of balanced feeds and incorporated into shrimp biomass. However, culture systems may be inefficient in
transforming nitrogen into biomass, its efficiency can be determined through a nitrogen budget. Less efficient
systems may incorporate close to 22% of nitrogen into biomass, while more efficient systems may incorporate up to
46.7%. The remaining nitrogen may be lost as organic nitrogen dissolved in the water and lost through effluents or it
may be trapped in the sediments (14-57%); also it may be lost as inorganic nitrogen in the form of ammonia, nitrite
or nitrate (12-37%). Some nitrogen may be unaccounted for at the end of a cycle (5.2-55%) and it may be lost
through ammonia volatilization, N2 gas removal, etc. Information provided by a nitrogen budget can help us identify
areas or procedures within a shrimp farm that require improvement and allow for a reduction of excess nitrogen that
causes pollution, and at the same time, maximize its retention by shrimp.

Downloads

Download data is not yet available.

References

Briggs, M.R.P., Funge-Smith, S.J. (1994) A nutrient budget of some intensive marine shrimp ponds in Thailand.

Aquaculture and Fisheries Management 25, 789-811.

Browdy, C.L & Bratvold, D. (2001) Effects of sand sediment and vertical surface (AquaMats(TM)) on production,

water quality, and microbial ecology in an intensive Litopenaeus vannamei culture system. Aquaculture

, 81-94.

Burford, M.A., Preston, N.P., Glibert, P.M., Dannison, W.C. (2002) Tracing the fate of 15N-enriched feed in an

intensive shrimp system. Aquaculture 206, 199-216.

Burford, M.A., Thompson, P.J., McIntosh, R.P., Bauman, R.H., Pearson, D.C. (2003) Nutrient and microbial

dynamics in high-intensity, zero exchange shrimp ponds in Belize. Aquaculture 219, 393-411.

Burford, M.A., Williams, K.C. (2001) The fate of nitrogenous waste from shrimp feeding. Aquaculture 198, 79-93.

Daniels, H.V., Boyd, C.E. (1988) Pond bottom degradation. Coastal Aquaculture 5, 2-5.

Daniels, H.V., Boyd, C.E. (1989) Chemical budgets for polyethylene-lined brackishwater ponds. Journal of the

World Aquaculture Society 20, 53- 60.

González-Félix, M.L., Gómez-Jiménez, S., Perez-Velazquez, M., Davis, D.A., Velazco-Rameños, J.G. (2006)

Nitrogen budget for a low salinity zero water exchange culture system: I. Effect of various dietary protein

levels on the biological performance of Litopenaeus vannamei (Boone). Aquaculture Research, submitted.

Islam, M.S., Sarker, M.J., Yamamoto, T., Wahab, M.A., Tanaka, M. (2004) Water and sediment quality, partial mass

budget and effluent N loading in coastal brackishwater shrimp farms in Bangladesh. Marine Pollution

Bulletin 48 (5-6), 471-485.

Jackson, C., Preston, N., Thompson, P.J., Burford, M. (2003) Nitrogen Budget and effluent nitrogen components at

an intensive shrimp farm. Aquaculture 218, 397-411.

Miramontes-Higuera, N. (2004) Alimentación isonitrógena de diferentes niveles de proteína dietética para

Litopenaeus vannamei Boone 1931 (Crustacea: Penaeidae) en sistema de cultivo estático en baja salinidad:

Efecto sobre el presupuesto de nitrógeno y parámetros de producción. Universidad de Sonora,

Departamento de Investigaciones Científicas y Tecnológicas. Hermosillo, Sonora, México. 55p.

Paerl, H.W. & Whitall, D.R. (1999) Anthropogenically-derived atmospheric nitrogen deposition, marine

eutrophication and harmful algal blooms expansion: is there a link? Ambio 28, 307-311.

Páez-Osuna, F. (2001) Camaronicultura y medio ambiente. Instituto de ciencias del Mar y Limnología, Estación

Mazatlán, UNAM, Programa Universitario de Alimentos y El Colegio de Sinaloa. México D.F. 451 p.

Schuur, A.M. (2003) Evaluation of biosecurity applications for intensive shrimp farming. Aquacultural Engineering

, 3-19.

Smith, L.L. & Lawrence, A.L. (1990) Feasibility of penaeid shrimp culture in inland saline groundwater-fed ponds.

The Texas Journal of Science 42, 3-12.

Tacon, A.G.J., Cody, J.J., Conquest, L.D., Divakaran, S., Forster, L.P., Decamp, O.E. (2002) Effect of culture system

on the nutrition and growth performance of Pacific white shrimp Litopenaeus vannamei (Boone) fed

different diets. Aquaculture Nutrition 8, 121-137.

Thakur, D.P. & Lin, C.K. (2003) Water quality and nutrient budget in closed shrimp (Penaeus monodon) culture

systems. Aquacultural Engineering 27, 159-176.

Thoman, E.S., Ingall, E.D., Davis, D.A., Arnold, C.R. (2001) A nitrogen budget for a closed, recirculating

mariculture system. Aquacultural Engeneering 24, 195-211.

Tyrell, T. (1999) The relative influences of nitrogen and phosphorus on oceanic primary production. Nature 400,

-531.

Young, A. (2002) Nitrogen budgets for your dairy. Utah State University Extension. Electronic Publishing

AG/Dairy-02, 1-4.

How to Cite

González-Félix, M. L., & Pérez-Velázquez, M. (2019). Un Panorama de los Presupuestos de Nitrógeno para Cultivo de Camarón. Avances En Nutrición Acuicola. Retrieved from https://nutricionacuicola.uanl.mx/index.php/acu/article/view/167

Most read articles by the same author(s)

Similar Articles

<< < 10 11 12 13 14 15 

You may also start an advanced similarity search for this article.