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Importance of the proportions of dietary polyunsaturated fatty acids and antioxidants in larval PDF

242 Pages·2008·3.06 MB·English
by  AtalahEyad
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aAD DE LAS PALMAS DE GRAN CANARIA Departamento de Biología Grupode Investigación en Acuicultura Las Palmas de Gran Canaria, Spain 2008 DEPARTAMENTO DE BIOLOGIA Universidad de Las Palmas de Gran Canaria Anexo I D. JUAN LUIS GÓMEZ PINCHETTI SECRETARIO DEL DEPARTAMENTO DE BIOLOGíA DE LA UNIVERSIDAD DE LAS PALMAS DE GRAN CANARIA, CERTIFICA, Que el Consejo de Doctores del Departamento en su sesión de fecha hoy tomó el acuerdo de dar el consentimiento para su tramitación, a la tesis doctoral titulada "IMPORTANCE OF THE PROPORTIONS OF DIETARY POLYUNSATURATED FATTY ACIDS ANO ANTIOXIDANTS IN LARVAL DEVELOPMENT OF MARINE FISH" presentada por el doctorando D. EYAD ATALAH, a dirigida por la Doctora Da M SOLEDAD IZQUIERDO LÓPEZ y a codirigida por la Doctora Da CARMEN M HERNÁNDEZ CRUZ. CAMPUS UNIVERSITARIO DE TAFIRA-35017Las Palmas-Islas Canarias-España-Tlf.: 34-92845 29 11 -Fax: 34-92845 2922 - UNIVERSIDAD DE LAS PALMAS DE GRAN CANARIA Departamento: Biologia & Instituto Universitario de Sanidad animales (lUSA) Programa de Doctorado: Acuicultura: producción controlada de animales acuáticos Titulo de la Tesis Importance of the proportions of dietary polyunsaturated fatty acids and antioxidants in larval development of marine fish Tesis Doctoral presentada por D. Eyad Atalah Dirigida por la Catedrática. Marisol Izquierdo López Codirigida por Prof. Carmen María Hernández Cruz La Direct~ra La Codirectora El Doctorando ,1. , / Las palmas de gran canaria, a 5 de Noviembre de 2008 aD CANARIA DELASPAlMASDEGRAN DepartamentodeBiología Importance of the proportions of dietary polyunsaturated fatty acids and antioxidants in larval development of marine fish EYAD ATALAH Grupo de Investigación en Acuicultura Instituto Canario de Ciencias Marinas Universidad de Las Palmas de Gran Canaria Being a thesis submitted for the degree of Doctor of Philosophy In the University of Las Palmas de Gran Canaria, 2008 Directors: Prof. Marisol Izquierdo & Prof. Carmen María Hernández Cruz TABLE OF CONTENTS List of tables ……………………………………………………….. III List of figures ...…………………………………………………….. V List of abbreviations ……………………………………………….. VIII Acknowledgements ……………………………………………….. IX 1. Chapter 1: Introduction 1 1.1. Importance of fish lipid nutrition for aquaculture development ………………………………………... 1 1.2. Essential fatty acids ………………………………… 2 1.3. Specific importance of DHA, EPA and ARA ……… 5 1.4. Importance of different ratios of DHA, EPA and ARA ………………………………………………… 6 1.5. Importance of antioxidant vitamins in lipid nutrition . 8 1.6. Vitamin E …………………………………………… 9 1.7. Vitamin C …………………………………………... 11 1.8. Relation vitamin E and C …………………………... 12 1.9. Objectives……………………………………….…… 13 1.10. References…………………………………………… 18 2. Chapter 2: Materials and Methods 39 2.1. Fish …………………………………………………. 39 2.1.1. Gilthead sea bream ………………………… 39 2.1.2. Sea bass …………………………………….. 39 2.2. Experimental conditions ……………………………. 39 2.3. Diet and Feeding ……………………………………. 40 2.3.1. Diet formulation …………………………… 40 2.3.2. Microdiets preparation …………………….. 40 2.4. Larval feeding ……………………………………… 41 2.5. Sampling …………………………………………… 41 2.6. Activity test and survival …………………………... 42 2.7. Growth evaluations …………………………………. 42 2.8. Biochemical Analysis ………………………………. 42 2.8.1. Moisture …………………………………… 42 2.8.2. Protein ……………………………………... 43 2.8.3. Total Lipid ………………………………… 43 2.8.4. Separation of polar lipids…………………... 43 2.8.5. Fatty acid methyl esters preparation and quantification ………………………………. 43 2.9. Statistical analysis …………………………………. 44 I 3. Chapter 3: Effect of different dietary EPA/DHA ratios on incorporation of essential fatty acid in gilthead sea bream larvae Sparus aurata (Linnaeus, 1758) ……………………… 49 4. Chapter 4: Importance of relative levels of dietary ARA and EPA for culture performance of gilthead seabream (Sparus aurata) larvae ……………………………………...………….. 71 5. Chapter 5: Importance of dietary arachidonic acid for survival, growth and stress resistance of larval European sea bass fed high dietary docosahexaenoic and eicosapentaenoic acids …… 89 6. Chapter 6: The effect of vitamin E and different DHA levels on growth, survival, and stress resistance in sea bass (Dicentrarchus labrax) larvae …………………………...……. 107 7. Chapter 7: Enhancement of gilthead seabream (Sparus aurata) larval growth by dietary vitamin E in relation to two different levels of essential fatty acids …………………………………. 127 8. Chapter 8: Combined effect of vitamin C and vitamin E microdiets for gilthead sea bream Sparus aurata …………….… 149 9. Chapter 9: General Conclusions ………………………………. 171 10. Capítulo 10: Resumen amplio en Español ……………………. 173 10.1. Introducción ………………………………………... 174 10.2. Materiales y Métodos …………………………...…. 193 10.3. Resultados y discusión …………………………….. 203 10.4. Bibliografía………………………………………….. 207 II LIST OF TABLES Table 1.1 Optimal EPA/DHA or DHA/EPA ratio for different fish species …... 15 Table 1.2. Optimal vitamin E for different fish species ………………………... 16 Table 1.3. Optimal vitamin C for different fish species ………………………... 17 Table 2.1. Main fatty acids of the major dietary lipid sources used in these experiments …………………………………………………………….. 45 Table 2.2. Mixture of attractants, minerals and vitamins ………………………. 46 Table 3.1. Lipid sources (% total ingredients) and crude lipid (% dry basis) and moisture (% wet basis) content of the experimental diets ………… 52 Table 3.2. Main fatty acid composition of the experimental diets for gilthead seabream fed microdiets containing different EPA/DHA proportions … 53 Table 3.3. Effect of dietary EPA and DHA levels on average survival and resistance to handling stress of larval gilthead seabream ……………… 56 Table 3.4. Effect of dietary EPA and DHA levels on final total length and body weight of gilthead sea bream …………………………………………... 56 Table 3.5. Average final lipid and fatty acid composition of larval gilthead seabream ……………………………………………………………….. 61 Table 4.1. Lipid sources (% total ingredients), crude lipid (% dry basis), crude protein (% dry basis) and moisture (% wet basis) content of the experimental diets …………………..………………………………….. 74 Table 4.2. Fatty acid composition of experimental diets for larval gilthead seabream ….…………………………………………………………….. 75 Table 4.3. Lipid content and fatty acid composition of total lipids from gilthead seabream larvae after 14 days of feeding several EPA/ARA levels …… 82 Table 5.1. Main lipid ingredients composition and analyzed lipid and protein contents of the experimental diets ……………………………………… 93 Table 5.2. Fatty acid composition of experimental diets for larval European sea bass ……………………………………………………………………... 94 Table 5.3. Effect of dietary ARA levels on survival, growth and stress resistance of European sea bass larvae …………………………………. 95 III Table 5.4. Lipid content and fatty acid composition of total lipids of European sea bass larvae fed several ARA levels ………………………………… 96 Table 6.1. Main lipid ingredients composition and vitamin E contents of the experimental diets ……………….…………………………………… 110 Table 6.2. Fatty acid composition of the experimental diets for European sea bass (g/100 g diet dry weight) ………………………………………….. 111 Table 6.3. Effect of different dietary DHA/vit E contents on larval growth, and results of the two-way anova statistical analysis ……………….…..... 114 Table 6.4. Fatty acid composition of total lipid of the larval European sea bass (% total fatty acid)..…………………………………………………...… 118 Table 7.1. Lipid sources (% total ingredients), α-tocopherol (mg/kg) and crude lipid (% dry basis) content of the experimental diets …………………... 130 Table 7.2. Fatty acid composition of the experimental diets for gilthead seabream (g/100 g diet dry weight) …………………………………….. 130 Table 7.3. Effect of different dietary DHA/EPA and vit E contents on larval growth, and results of the two-way anova statistical analysis …………. 135 Table 7.4. Fatty acid composition of polar lipid of the larval gilthead seabream 139 Table 8.1. Dietary vitamin E and C composition ………………………………. 152 Table 8.2. Fatty acid composition of the experimental diets for gilthead seabream ………………………………………………………………... 153 Table 8.3. Fatty acid composition of polar lipid of the larval gilthead seabream 159 Tabla 10.1. Relación Óptima de EPA/DHA, DHA/EPA, DHA/EPA/ARA y ARA para las diferentes especies de peces …………………………… 189 Tabla 10.2. Óptimo de vitamina E para las diferentes especies de peces ……… 190 Tabla 10.3. Óptimo de vitamina C para las diferentes especies de peces ……… 191 Tabla 10.4. Principales ácidos grasos dietéticos de las principales fuentes lípidicas utilizadas en los experimentos ………………………………... 200 Tabla 10.5. Mezcla de atractantes, minerales y vitaminas…………………….... 201 IV LIST OF FIGURES Figure 2.1. Tanks used for larval rearing during feeding experiments ………… 47 Figure 2.2. Larval microdiet formulated and prepared for the feeding experiments…………………………………………………………… 47 Figure 3.1. Effect of dietary EPA (% d.w.) on survival of gilthead seabream larvae fed different EPA/DHA ratio……………………………………. 55 Figure 3.2. Effect of dietary EPA and DHA (% d.w.) on survival of gilthead seabream larvae fed different EPA/DHA ratio…………………………. 55 Figure 3.3. Effect of dietary n-3 HUFA (% d.w.) on average final total length of gilthead seabream larvae fed different EPA/DHA ratio…………….. 57 Figure 3.4. Effect of (EPA+DHA+ARA)*(DHA/EPA)/ARA on total length of gilthead seabream larvae fed several EPA/DHA ratio at the end of trial1…………………………………………………………………….. 57 Figure. 3.5 Evolution of dietary oleic acid (% fatty acid) in diet and gilthead seabream larvae (% fatty acid) fed different EPA/DHA ratio………….. 58 Figure 3.6. Evolution of EPA in diets and gilthead seabream larvae fed different EPA/DHA ratio……………………………………………….. 58 Figure 3.7. Graphical representation of EPA (x axis) and DHA (y axis) contents on diets fed to gilthead seabream and the larval growth (SGR, secondary y)………………………………………………………….. 59 Figure 3.8. Graphical representation of EPA (x axis) and DHA (y axis) contents on diets fed to gilthead seabream and the larval survival (secondary y)……………………………………………………………. 60 Figure 4.1. Dietary ARA. EPA and DHA % dry basis………………………… 76 Figure 4.2. The survival rate of fish fed the different experimental diets………. 77 Figure 4.3. Dry whole body weight after 7 days of feeding……………………. 77 Figure 4.4. Final dry whole body weight of fish fed the different experimental diets……………………………………………………………………... 78 Figure 4.5. Specific growth rate of fish fed the different experimental diets…... 78 Figure 4.6. Final standard length of fish fed the different experimental diets….. 79 Figure 4.7. Final biomass of fish fed the different experimental diets………… 80 V Figure 4.8. Incorporation of dietary ARA in larvae tissues…………………….. 81 Figure 4.9. Incorporation of dietary EPA in larvae tissue………………………. 81 Figure 5.1. Evolution of body weight of fish fed the different experimental diets…………………………………………………………………… 97 Figure 5.2. Evolution of standard length of fish fed the different experimental diets…………………………………………………………………… 98 Figure 5.3. Effect of dietary ARA level on larval survival after handling stress at the end of the experiment…………………………………………….. 98 Figure 5.4. Effect of dietary ARA level on larval survival……………………... 99 Figure 6.1. Survival rate of fish fed the experimental diets containing several vit E and DHA………………………………………………………….. 113 Figure 6.2. Survival after 24h of air activity test of fish fed the different experimental diets………………………………………………………. 114 Figure 6.3. Final total length of fish fed the different experimental diet……….. 115 Figure 6.4. Final dry whole body weight of fish fed the different experimental diets…………………………………………………………………….. 115 Figure 6.5. Specific growth rate (SGR) of fish fed the different experimental diets…………………………………………………………………… 116 Figure 6.6. Final biomass of fish fed the different experimental diets…………. 117 Figure 6.7. Correlation between dietary DHA levels (in the 1500 mg vit E diets) and survival of fish fed the different experimental diets………… 120 Figure 7.1. Survival rate of fish fed the experimental diets containing several vit E and DHA/EPA…………………………………………………….. 133 Figure 7.2. Correlation between the vitamin E levels (in the 5/2.5 diets) and survival of fish fed the different experimental diets…………………… 134 Figure 7.3. Final total length of fish fed the different experimental diets……… 134 Figure 7.4. Final dry whole body weight of fish fed the different experimental diets……………………………………………………………………. 135 Figure 7.5. Specific growth rate of fish fed the different experimental diets… 136 Figure 7.6. Final biomass of fish fed the different experimental diets………… 137 Figure 7.7. Survival after 24h of air activity test of fish fed the different experimental diets..................................................................................... 137 Figure 7.8. Survival after 24h of exposure to a temperature reduction in fish VI

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tramitación, a la tesis doctoral titulada "IMPORTANCE OF THE . Table 1.1 Optimal EPA/DHA or DHA/EPA ratio for different fish species … Table 1.2
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