15 resultados para marine fish
em Acceda, el repositorio institucional de la Universidad de Las Palmas de Gran Canaria. España
Resumo:
La acuicultura es uno de los sectores con mayor crecimiento en la producción animal mundial, con una tasa superior al 5% anual en la última década (Izquierdo et al., 2008). En la acuicultura, el éxito del cultivo de cualquier especie de peces marinos está limitado por la cantidad y la calidad de la producción en masa de sus alevines (Izquierdo y Fernández - Palacios, 1997). Por lo tanto, para cubrir las crecientes demandas de la producción de semillas, es necesario mejorar la calidad nutritiva de sus larvas, lo cual todavía constituye una de las principales limitaciones para el desarrollo del cultivo de especies de peces marinos (Watanabe et al., 1983; Yúfera y Pascual, 1984; Sargent et al. 1997; Izquierdo et al., 2000). Aunque la producción Mediterránea del cultivo de peces marinos se ha incrementado en varias especies, la dorada Sparus aurata continúa siendo la especie mas cultivada (Izquierdo, 2005), con una producción anual de alevines que supera los 120 millones/ año. La demanda de alevines de buena calidad está aumentando a un ritmo del 10% anual, pero el éxito de la producción de los juveniles se ve muy afectado por la eficacia de la primera alimentación y la calidad nutricional de la dieta de arranque (Kolkovski et al., 1993; Sargent et al., 1997; Izquierdo et al., 2000). En general, la dorada y la lubina europea (Dicentrarchus labrax) son las especies más importantes de peces marinos criados en la región mediterránea y han caracterizado el desarrollo de la acuicultura marina en esta región en las últimas tres décadas (FAO, 1999). Además, en la producción, de ambas especies, se prevee una mayor expansión (Basurco y Abellán, 1999). Sin embargo, a pesar de que el engorde de estas especies está bien controlado, el conocimiento de sus necesidades nutricionales, en comparación con otras especies como salmónidos y carpas, sigue siendo incompleto (NRC, 1993). Por lo tanto, para obtener un mejor crecimiento y una mayor tasa de supervivencia, es esencial una dieta que responda a las necesidades nutricionales de las larvas, tanto cualitativas como cuantitativas (Kolkovski et al., 1993; Sargent et al., 1997). Además, incluso antes de que comience el desarrollo larvario, los huevos de los peces deben contener todos los nutrientes que cubran los requerimientos adecuados para el desarrollo del embrión (Izquierdo y Fernández - Palacios, 1997). En los últimos años, las investigaciones han prestado gran atención a la importancia de los lípidos dietéticos para larvas de peces marinos (Izquierdo et al., 2003), puesto que son esenciales para el crecimiento y el desarrollo de los mismos (Watanabe, 1982; Sargent et al., 1999a). Como reflejo de esta importancia, la dieta para dorada y lubina se ha convertido en una dieta altamente energética (25% de lípidos) en comparación con la década anterior (12% de lípidos) (Izquierdo et al., 2003). Los lípidos dietéticos proporcionan una fuente rica de energía y fosfolípidos y son fundamentales para la estructura de las biomembranas. Los lípidos dietéticos también sirven como vehículos para la absorción de otros nutrientes, como las vitaminas liposolubles A, D, E, y K, y pigmentos naturales o sintéticos. Los lípidos son componentes de las hormonas y precursores para la síntesis de diversos metabolitos funcionales, como las prostaglandinas y otros eicosonoides. Además, los lípidos dietéticos son reconocidos como uno de los factores nutricionales más importantes que afectan el crecimiento y la supervivencia de las larvas (Watanabe et al., 1983), porque constituyen materiales esenciales para la formación normal de célula, las membranas de los tejidos y el desarrollo de órganos (Izquierdo et al., 1998, 2003; Pousaò et al., 2003). Sin embargo, la utilización de los lípidos dietéticos por las larvas puede verse afectada directa o indirectamente por varios cambios morfológicos y fisiológicos que ocurren durante el desarrollo larvario. En los últimos años ha habido más interés en todos estos aspectos nutricionales de los lípidos en las larvas de peces, debido a la importancia de utilización de los lípidos dieteticos para el óptimo crecimiento y supervivencia larvaria (Izquierdo et al., 2000).
Resumo:
Máster Oficial en Cultivos Marinos. VI Máster Internacional en Acuicultura. Trabajo presentado como requisito parcial para la obtención del Título de Máster Oficial en Cultivos Marinos, otorgado por la Universidad de Las Palmas de Gran Canaria (ULPGC), el Instituto Canario de Ciencias Marinas (ICCM), y el Centro Internacional de Altos Estudios Agronómicos Mediterráneos de Zaragoza (CIHEAM)
Resumo:
[EN] Red porgy, Pagrus pagrus, is one of the marine fish species for the aquaculture diversification in the Mediterranean and Mid Atlantic coasts. Relevance of its nutrition has been demonstrated not only from growth and body composition, but also because it?s important role in fish skin colour and carotenoids deposition (Kalinowski et al., 2005; Pavlidis et al., 2006). Present study evaluate the influence of two different crab meals by products, marine and freshwater origin, as protein and pigment sources in experimental diets for red porgy and its effects on fish growth and feed utilization parameters, fish skin colour and fish composition. Both crab meals used in present study are suitability as partial replacers of fish meal in diets for the red porgy. Dietary inclusion levels of 10% and 20% of the dietary protein from these meals have no detrimental effects on growth and feed utilization parameters respect to a fish meal based diet, with high improvements in fish skin redness and skin colour saturation by increased inclusion levels. Digestibility and retention efficiency parameters are being analyzing at the moment.
Resumo:
[EN]Most marine fish larvae require high amounts of n-3 HUFA (highly unsaturated fatty acids) such as eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA) (Watanabe, 1982; Izquierdo, 1996). Fish larvae tissue lipids are also very high in n-3 HUFA, what implies a higher risk of peroxidation (Sargent et al. 1999) and cellular damage (Kanazawa, 1991), requiring then antioxidants to protect them intra- and extra-cellularly from free radical compounds. Vitamin E (Vit E) functions as a chain breaking antioxidant, reacting with the lipid peroxide radical produced and preventing the further reaction with a new PUFA. Hence their requirements are related with the dietary and tissue PUFA contents. The objective of the present study was to determine the effect of dietary Vit E on gilthead sea bream and sea bass survival, growth and stress, at different n-3 HUFA levels.
Resumo:
Watanabe et al. (1991 a,b) state that, vitamin E and carotenoids perform an essential role on the quality of egg spawning. Vitamin E is one of the main nutrients for the reproduction of fish (Izquierdo et al., 2001), and it has been proved that its inclusion in diets for broodstocks favors the quality of egg spawning in several species of fish (Watanabe and Takashima,1977; Takeuchi et al., 1981; Watanabe et al., 1985, 1991 a,b; Sutjaritvongsanon, 1987; Watanabe, 1990; Schimittou, 1993; Mushiake et al., 1993; Dube, 1996; Shiranee and Natarajan, 1996; Izquierdo et al., 2001; Morehead et al., 2001; Fernández- Palacios et al., 2005). On the other hand, the carotenoids which also perform an antioxidizing function (including the protection of lipids from oxidation), have been involved in the reproductive processes of marine organisms: crustaceans (Liñan-Cabello et al., 2002), marine fish (Watanabe y Kiron, 1995; Verakunpiriya et al., 1997 a,b; Vassallo-Agius et al., 2001 a,b,c, 2002; Watanabe and Vassallo-Agius 2003) and fresh water fish (Ahmadi et al., 2006). The results of this study suggest that the recommended levels of n-3 HUFA in diets for gilthead sea bream broodstocks could be increased up to 3,5 % when supplemented jointly with carotenoids from paprika oleoresin and vitamin E, thus favoring the quality of spawning.
Resumo:
[EN] The expression and regulation of intestinal oligopeptide transporter (PepT)-1 when vegetable sources are used as a substitute for fish meal in the diet of marine fish has not yet been explored. In the present study, as part of our ongoing work on elucidating PepT1 gene expression in relation to different dietary treatments, we have now isolated and deposited in Genbank database (accession no. GU733710) a cDNA sequence representing the PepT1 in the sea bream (Sparus aurata). The ?de novo? prediction of the three-dimensional structure of PepT1 protein is presented. We also analyzed diet-induced changes in the expression of PepT1 mRNA via real-time RT-PCR using the standard curve method. Sea bream were fed for 140 days with one of the following four diet formulations (43% protein/21% lipid): a control fast growth-promoting diet (C), and three diets with the same formulation but in which 15% of the fish meal was substituted by protein concentrates either from lupine (LPC), chick pea (CPC), or green pea (PPC). Fish fed PPC had significantly (p < 0.05) lower levels of PepT1 transcripts in the proximal intestine than the controls, whereas PepT1 transcript levels in fish fed LPC or CPC were not significantly different from the controls. Although growth was similar between fish fed with different diets during the first 72 days of feeding, growth of the fish fed with PPC was reduced during the second part of the trial and was significantly (p < 0.05) lower than fish fed LPC and CPC diets by the end of the experiment. Correlation between these results and fish growth performances highlights that the intestinal PepT1 mRNA level may serve as a useful marker of the dietary protein quality and absorption efficiency.
Resumo:
trabajo realizado por Medina Alcaraz, C., Castro, J.J., Sosa, P. A.
Resumo:
[ES] Main deformities such as lordosis, opercular deformities and upper/lower jaws shortening are considered as quality descriptors in commercial marine fish fry production and seem to be related with larval culture conditions in early larval stages. The aim of this work was to obtain information about the contribution of the diet and rearing system to the apparition of these abnormalities in gilthead sea bream (Sparus aurata) larvae in semi-industrial scale facilities. For that purpose, two different larval rearing systems semi-intensive and intensive were compared; besides, two different rotifer enrichments, DHA Protein Selco, (Inve Aquaculture, Dendermonde, Belgium) (R1) and Red Pepper Paste, (Bernaqua bvba, Turnhout, Belgium) were tested in the intensive system. Biochemical composition of larvae, preys and commercial products was analysed. At 50 days post hatching six hundred fish per treatment were individually studied under stereoscope and deformity frequency recorded. Besides at 95 days post hatching fry were soft X ray monitored. Both rotifer enrichment and rearing system affected survival, growth and deformity frequency. Rearing system did not affect total larvae fatty acid content except at 20 dah, where DHA were significantly higher and EPA significantly lower in Semi-intensive system. A significantly lower percentage of deformity rates together with better survival and growth were obtained in the semi-intensive system. In dietary treatment, rotifer enrichment significantly affected larval survival. R1 rotifers enrichment significantly (P<0.05) improved survival when compared to fed R2 larvae. The content of DPA was significantly (P<0.05) higher in R2 fed larvae reflecting the R2 rotifers content of this fatty acid. The level of this FA tended to decrease in concordance with the rotifers replacement by artemia in the diet. The effects n-3-HUFA and DPA (22:5n-6) over larval survival and skeletal deformities development is discussed.
Resumo:
[EN] Red porgy is one of the most interested new species for Spanish and other Mediterranean countries. Although no industrial procedures for fry production has been yet developed. The aim of this work was to develop an industrial scale larval rearing protocols testing the viability of two different rearing techniques (semi-intensive vs intensive) in pilot scale facilities. The second objective was to obtain information about the contribution of rearing system to the apparition of morphological abnormalities such as lordosis, opercular deformities and upper/lower jaws shortening which are considered as quality descriptors in commercial marine fish fry production and seem to be related with larval culture conditions in early larval stages. For that purpose, two different larval rearing systems semi-intensive and intensive were compared using the same live feed enrichments. Biochemical composition of larvae, preys and commercial products was analysed. At 50 days post hatching six hundred fish per treatment was individually studied under stereoscope and abnormalities frequency recorded. At 95 days post hatching fry were soft X ray monitored as well. Survival and abnormalities frequency were similar between treatments although a better growth in terms of total length was obtained in the semi-intensive system.
Resumo:
[EN] Main deformities such as lordosis, opercular deformities and upper/lower jaws shortening are considered as quality descriptors in commercial marine fish fry production and seem to be related at least with larval culture conditions in early larval stages. The aim of this work was to obtain information about the contribution of the diet and rearing system to the apparition of these abnormalities in gilthead sea bream (Sparus aurata) larvae in semi-industrial scale facilities. For that purpose, two different larval rearing systems semi-intensive and intensive were compared by duplicate and with the same live feed enrichments; besides, two different rotifer enrichments were tested in an intensive system. Biochemical composition of larvae, preys and commercial products was analysed. At 50 days post hatching six hundred fish per treatment were individually studied under stereoscope and abnormalities frequency recorded. At 95 days post hatching fry were soft X ray monitored as well. Survival and malformation frequency were significantly different between treatments, the effect of diet and system are discussed. A significantly lower percentage of deformity rates together with better survival and growth were obtained in the semi-intensive system, whereas the rotifer enrichment significantly affected larval survival.
Resumo:
Máster en Oceanografía