Total lipid nutritional quality of the adipose tissue from the orbital cavity in Nile tilapia from continental aquaculture

Sousa, Álison Bruno Borges de; Santos, Oscar de Oliveira; Visentainer, Jesuí Vergílio; Almeida, Neiva Maria de

doi:10.4025/actascianimsci.v39i4.36303

ABSTRACT.

This study aimed to determine the fatty acid composition and nutritional quality indexes of total lipids in adipose tissue from the orbital cavity of Nile tilapia from continental aquaculture in Paraiba State, Brazil. The tilapias were captured in six fish farms, and after slaughtering and bleeding, the adipose tissue from the orbital cavity was reserved, frozen and lyophilized for analysis of fatty acid composition by gas chromatography. By decreasing order, oleic, palmitic, linoleic, stearic, and palmitoleic acids were the most abundant ones. Monounsaturated fatty acids were the most prominent group in orbital cavity adipose tissue, where as polyunsaturated fatty acids were most abundant in the diet, with a percentage of linolenic acid ranging from 32.99 to 37.57%. Nutritional quality indexes of lipids varied from 0.491 to 0.575 for Atherogenicity Index, 0.543 to 0.741 for Thrombogenicity Index, and from 1.918 to 2.176 regarding the ratio of hypocholesterolemic/hypercholesterolemic. According to the composition of fatty acids and the nutritional quality of total lipids, the use of this byproduct can be recommended for human consumption or to elaborate products for animal intake.

Keywords:
fatty acids; atherogenicity index; thrombogenicity index; Oreochromis niloticus

RESUMO.

O objetivo deste estudo foi determinar a composição dos ácidos graxos e os índices de qualidade nutricional dos lipídios totais no tecido adiposo da tilápia do Nilo da aquicultura continental do Estado da Paraíba, Brasil. As tilápias foram capturadas em seis pisciculturas. Após o abate e sangria, o tecido adiposo da cavidade ocular foi reservado, congelado e liofilizado para análise da composição de ácidos graxos por cromatografia gasosa. Os ácidos graxos majoritários detectados em ordem decrescente foram: ácido oleico, ácido palmítico, ácido linoleico, ácido esteárico e ácido palmitoleico. O grupo mais abundante no tecido adiposo da cavidade ocular foi o dos ácidos graxos monoinsaturados, enquanto que na ração o grupo mais abundante foi o grupo dos ácidos graxos poli-insaturados, com percentual do ácido linolênico variando entre 32,99 e 37,57%. Os índices de qualidade nutricional dos lipídios variaram de 0,491 a 0,575 para o Índice de Aterogenicidade, 0,543 a 0,741 para o Índice de Trombogenicidade; e 1,918 até 2,176 para a razão entre hipocolesterolêmicos / hipercolesterolêmicos. De acordo com a composição dos ácidos graxos e a qualidade nutricional dos lipídios totais, é possível recomendar o uso deste subproduto para o consumo humano ou elaborar produtos para consumo animal.

Palavras-chave:
ácidos graxos; índice de aterogenicidade; índice de trombogenicidade; Oreochromis niloticus

Introduction

In 2013, Brazil produced 476,512 tons of fish by aquaculture. Continental aquaculture accounted for 82.37% (392,492 tons) and marine aquaculture was responsible for 17.63% (84,020 tons) of the production. The Northeast region was the largest producer of fish (140,748 tons), followed by the South region (107,448 tons). The continental aquaculture in Brazilis essentially represented by fish farming (Ministério da Pesca e Aquicultura Ministério da Pesca de Aquicultura (MPA). (2015). Plano de desenvolvimento da aquicultura brasileira - 2015/2020. Brasília, DF: MPA.[MPA], 2015).

The Food and Agriculture Organization of the United Nations (FAO) estimates that the Brazilian fish production may achieve an increase of 104% in fishing and aquaculture by 2025 (Food and Agriculture OrganizationFood and Agriculture Organization [FAO]. (2016). El estado mundial de la pesca y la acuicultura 2016. Contribuición a la seguridade alimentaria y la nutrición para todos. Roma, IT: FAO Press release. [FAO], 2016).

There is a concern to increase the fishery production, mainly through aquaculture activity, as an alternative to provide healthy food. It is also necessary to provide a subsidy for fishing communities to improve the fish products since 28% of the global fish production is used to prepare feed, or is considered as residues, which are discarded in the environment. Currently, about 50% of the biomass originated from fish processing in Brazil is discarded, without any type of reuse (Stevanato et al., 2007Stevanato, F. B., Petenucci, M. E., Matsushita, M., Mesomo, M. C., Souza, N. E., Visentainer, J. E. L., … Visentainer, J. V. (2007). Avaliação química e sensorial da farinha de resíduo de tilápias na forma de sopa. Food Science and Technology , 27, 567-571.).

Studies on these residues are relevant since tilapia has an important significance in the national fishery, and because they make possible the use of residues generated by this activity, besides adding value to byproducts. These studies also aim to improve the fish products intake, due to their nutritional characteristics, especially regarding the fatty acids considered essential to the diet, responsible for many health benefits. Meal fatty acids can reduce the risk of coronary and cardiovascular diseases (Lorgeril et al., 1994Lorgeril, M., Renaud, S., Mamelle, N., Salen, P., Martin, J. L., & Monjaud, I. (1994). Mediterranean alpha-linolenic acid-rich diet in secondary prevention of coronary heart disease. Lancet, 343, 1454-1459.; Singh, Niaz, Sharma, Kumar, & Rastogi, 1997Singh, R. B., Niaz, M. A., Sharma, J. P., Kumar, R., & Rastogi, V. (1997). Randomized, double-blind, placebo-controlled trial of fish oil and mustard oil in patients with suspected acute myocardial infarction: the Indian Experiment of Infarct Survival. Cardiovascular Drugs and Therapy, 11(3), 485-491. ); chronic neurodegenerative diseases (Youdim, Martin, & Joseph, 2000Youdim, K. A., Martin, A., & Joseph, J. A. (2000). Essential fatty acids and the brain: possible health implications. International Journal of Developmental Neuroscience, 18(4-5), 383-399.) such as Alzheimer’s (Tully et al., 2003Tully, A. M., Roche, H. M., Doyle, R., Fallon, C., Bruce, I., Lawlor, B., … Gibney, M. J. (2003). Low serum cholesteryl ester-docosahexaenoic acid levels in Alzheimer’s disease: a case - control study. British Journal of Nutrition, 89(4), 483-489.) and several types of cancer (Connolly, Coleman, & Rose, 1997Connolly, J. M., Coleman, M., & Rose, D. P. (1997). Effects of dietary fatty acids on DU145 human prostate cancer cell growth in athymic nude mice. Nutrition and Cancer, 29(2), 114-119.; Rose, & Connolly, 1999Rose, D. P., & Connolly, J. M. (1999). Omega-3 fatty acids as cancer chemopreventive agents. Pharmacology & Therapeutics, 83(3), 217-244.).

This study aimed to determine the fatty acid composition and nutritional quality of total lipids in the adipose tissue from the orbital cavity of Nile tilapia (Oreochromis niloticus) from continental aquaculture in the State of Paraíba, Brazil.

Material and methods

Raw material

Nile tilapia raised in an intensive system was used as raw material for this study. Fish were caught in six different fish farms in the State of Paraíba, Brazil. The slaughtering process was carried out by asphyxia in ice. The tilapias were washed, and the adipose tissue from the orbital cavity was taken, frozen and subjected to lyophilization (L101-Liotop Lyophilizer).Samples were stored at -18ºC until the analysis.

Sampling of the feed used by fish farmers

The sampling of the feed used by fish farmers was carried out, by chance, simultaneously with the fish sampling.

Extraction of Total Lipids

Total lipid extraction was carried out according to Bligh and Dyer (1959Bligh, E. G., & Dyer, W. J. (1959). A rapid method of total lipid extraction and purification. Canadian Journal of Biochemistry and Physiology, 37(1), 911-917.). The total lipids were stored in amber bottles, under N₂atmosphere, identified and stored in a freezer at -18ºC until the analyses.

Fatty Acid Methyl Esters

The preparation of fatty acid methyl esters was made according to the method proposed by Joseph and Ackman (1992Joseph, J. D., & Ackman, R. G. (1992). Capillary column gas chromatographic method for analysis of encapsulated fish oils and fish oil ethyl esters: collaborative study. Journal of AOAC International, 75(3), 488-506.), by using BF₃/methanol. All the stages of the process were carried out under N₂atmosphere.

Fatty acid analysis

The fatty acid methyl esters were separated using a Gas chromatograph Varian 3380, equipped with flame ionization and fused-silica capillary column CP - 7420 (Select FAME) (100 m in length, 0.25 mm in internal diameter and 0.25 μm of cyanopropyl). The flux of H₂ (mobile gas) was 1.0 mL min^-1, with 30 mL min^-1 N₂ (make up); and 300 mL min^-1 synthetic air, for the detector flame. The volume injected was 1.0 μL, by using 1:80 split, and the injector and detector temperatures were 220 and 240^oC, respectively. The column temperature was 165^oC for 18 min. and increased to 235^oC at a rate of 4^oC min.^-1, which was kept for 24.5 min. Fatty acids were identified by comparison of retention times with Sigma standard (USA) and spiking coelution of standards together with the sample, and the ECL values were calculated from previously corrected retention time of the samples, which were compared with values available in the literature (Stransky, Jursik, & Vitek, 1997Stransky, K., Jursik, T., & Vitek, A. (1997). Standard equivalent chain length values of monoenic and polyenic (methylene interrupted) fatty acids. Journal of High Resolution Chromatography, 20(3), 143-158.; Thompson, 1997Thompson, R. H. (1997). Simplifying fatty acid analyses using a standard set of gas-liquid chromatographic conditions: II. Equivalent chain length values for cis- and trans- isomers of monoethylenic C18 fatty acid methyl esters for Carbowax-20M liquid phase. Journal of Chromatographic Science, 35, 598-602.). The concentrations were determined through the integration of peak areas using the Software Varian Workstation Star, version 5.0, and the results were expressed as percentages of thetotal lipid relative area.

Nutritional Quality Indices of Lipids (NQI)

The nutritional quality of the lipid fraction was determined in fatty acids by using the composition data from three indices:

Atherogenicity Index (AI) = [(C12:0 + 4xC14:0+C16:0)] / (ΣMUFA+ Σn-6+Σn-3);

Thrombogenicity Index (TI) = (C14:0+C16:0+C18:0) / [(0.5xΣMUFA)+(0.5xΣn-6) + (3xΣn-3) + (Σn-3/n-6)];

MUFA = monounsaturated fatty acids.

Ratio between Hypocholesterolemic / Hypercholesterolemic Fatty Acids (H/H) = (C18:1n-9+C18:2n-6+C20:4n-6+C18:3n-3+C20:5n-3+C22:5n-3+C22:6n-6) /(C14:0+C16:0).

The a therogenicity and thrombogenicity indices were calculated according to Ulbricht and Southgate (1991Ulbricht, T. L. V., & Southgate, D. A. T. (1991). Coronary heart disease: seven dietary factors. Lancet , 338(8773), 985-992.), and the ratio between Hypocholesterolemic / Hypercholesterolemic fatty acids according to Santos-Silva, Bessa and Santos-Silva (2002Santos-Silva, J., Bessa, R. J. B., & Santos-Silva, F. (2002). Effect of genotype, feeding system and slaughter weight on the quality of light lambs: II. Fatty acid composition of meat.Livestock Production Science, 77(2-3), 187-194.).

Statistical analysis

Data were analyzed by analysis of variance complemented by the Tukey test at 5% significance level using the SAS system, Licensed by the Federal University of Paraiba (Statistical Analisys System Statistical Analisys System [SAS]. (2004). SAS/STAT User guide, Version 9.1.2. Cary, NC: SAS Institute Inc.[SAS], 2004).

Results and discussion

Fatty acid composition in the adipose tissue from the orbital cavity

The total lipid fatty acid composition detected in the orbital cavity adipose tissue in Nile tilapia is shown in Table 1. Twenty-six components were detected in the total lipids of adipose tissue from the orbital cavity. Oleic (18:1n-9), palmitic (16:0), linolenic (LA, 18:2n-6), stearic (18:0) and palmitoleic acids (16:1n-7), in decreasing order, were the most abundant fatty acids detected.

Stevanato et al. (2008Stevanato, F. V., Almeida, V. V., Matsushita, M., Oliveira, C. C., Souza, N. E., & Visentainer, J. V. (2008). Fatty acids and nutrients in the flour made from tilapia (Oreochromis niloticus) heads. Food Science and Technology, 28(2), 440-443. ) identified 31 fatty acids in the head of fresh tilapia. The authors stated that there was a predominance of the following fatty acids: palmitic acid (16:0), with values varying from 22.73 to 25.27%; oleic acid (18:1n-9) ranging from 35.56 to 33.60%; and linoleic acid (18:2n-6), ranging from 11.58 to 11.69%.

A high content of palmitic fatty acid (16:0), among the group of saturated fatty acids, was found in the adipose tissue from the orbital cavity, with an average percentage of 24.31% (Table 1). Similar results were found in tucunaré (Cichlaocelaris) by Inhamuns, Franco and Batista (2009Inhamuns, A. J., Franco, M. R. B., & Batista, W. S. (2009). Seasonal variations in total fatty acid composition of muscles and eye sockets of tucunaré (Cichla sp.) from the Brazilian Amazon area. Food Chemistry , 117(2), 272-275.); mapará (Hypophthalmussp.) by Inhamuns and Franco (2008Inhamuns, A. J., & Franco, M. R. B. (2008). EPA and DHA quantification in two species of freshwater fish from Central Amazonia. Food Chemistry , 107(2), 587-591.); tambaqui (Colossoma Macropomum) by Almeida, Visentainer and Franco (2008Almeida, N. M., Visentainer, J. V., & Franco, M. R. B. (2008). Composition of total, neutral and phospholipids in wild and farmed tambaqui (Colossoma macropomum) in the Brazilian Amazon area. Journal of the Science of Food and Agriculture , 88(10), 1739-1747.); and matrinxã (Bryconcephalus) by Almeida and Franco (2007).

The fatty acids considered essential and belonging to the omega 3 family have shown values for α-linolenic (1.12 to 1.87), eicosapentaenoic acid (0.76 to 2.19), and docosahexaenoic acid (0.32 to 0.63). Several authors confirmed the presence of those essential fatty acids in residues of tilapia (Cengiz, Kan, Kizmaz, Bashan, & Yanar, 2012Cengiz, E. I., Kan, Y., Kizmaz, V., Bashan, M., & Yanar, M. (2012). The protective role of vitamin E on the fatty acid composition of phospholipid structure in gill and liver tissues of Oreochromisniloticus exposed to deltamethrin. Ecotoxicology and Environmental Safety, 80(1), 381-385.; Stevanato et al., 2008Stevanato, F. V., Almeida, V. V., Matsushita, M., Oliveira, C. C., Souza, N. E., & Visentainer, J. V. (2008). Fatty acids and nutrients in the flour made from tilapia (Oreochromis niloticus) heads. Food Science and Technology, 28(2), 440-443. ; Navarro et al., 2012Navarro, R. D., Navarro, F. K. S. P., Ribeiro Filho, O. P., Ferreira, W. M., Pereira, M. M., & Seixas Filho, J. T. (2012). Quality of polyunsaturated fatty acids in Nile tilapias (Oreochromisniloticus) fed with vitamin E supplementation. Food Chemistry , 134(1), 215-218.; Tonial, Matsushita, Furuya, Souza, & Visentainer, 2012Tonial, I. B., Matsushita, M., Furuya, W. M., Souza, N. E., & Visentainer, J. V. (2012). Fatty Acid Contents in Fractions of Neutral Lipids and Phospholipids of Fillets of Tilapia Treated with Flaxseed Oil. Journal of the American Oil Chemists’ Society, 89, 1495-1500.).

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Table 1
Total lipid fatty acid composition (%) in adipose tissue from the orbital cavity of Nile tilapia.

The docosahexaenoic acid (DHA) is a very important fatty acid responsible for the physical properties of the brain membranes, the features of their receptors, the cellular interactions and the enzymatic activity (Yehuda, Rabinovitz, Carasso, & Mostofsky, 2002Yehuda, S., Rabinovitz, S., Carasso, R. L., & Mostofsky, D. I. (2002). The role of polyunsaturated fatty acids in restoring the aging neuronal membrane. Neurobiology of Aging, 23, 843-853.).

Among the polyunsaturated fatty acids, there was a high content of linoleic acid (18:2n-6) in all the samples. Almeida et al. (2008Almeida, N. M., Visentainer, J. V., & Franco, M. R. B. (2008). Composition of total, neutral and phospholipids in wild and farmed tambaqui (Colossoma macropomum) in the Brazilian Amazon area. Journal of the Science of Food and Agriculture , 88(10), 1739-1747.) and Almeida and Franco (2007Almeida, N. M., & Franco, M. R. B. (2007). Fatty acid composition of total lipids, neutral lipids and phospholipids in wild and farmed matrinxã (Bryconcephalus) in the Brazilian Amazon area. Journal of the Science of Food and Agriculture, 87(14), 2596-2603.) found values of 9.57 and 9.35% for 18:2n-6 in the orbitalcavity of tambaqui and matrinxã, respectively, in the Brazilian Amazon. It is interesting to note that the values of 18:2n-6 in the feed were between 32.99 and 37.57%. The diets provided to fish can affect the lipid content, especially the fatty acid composition (Om et al., 2001Om, A. D., Umino, T., Nakagawa, H., Sasaki, T., Okada, K., Asano, M., & Nakagawa, A. (2001). The effects of dietary EPA and DHA fortification on lipolysis activity and physiological function in juvenile black sea bream Acanthopagrusschlegeli (Bleeker). Aquaculture Research, 32(1), 255-262.).

High proportions of n-6 polyunsaturated fatty acids characterize the fatty acid composition of freshwater fish, especially linoleic and arachidonic acids (Steffens, 1997Steffens, W. (1997). Effects of variation in essential fatty acids in fish feeds on nutritive value of fresh water fish for humans. Aquaculture , 151, 97-119.).

The arachidonic acid (AA) is related to the development of brain and retina during the period of gestation and the first years of human life. The values for arachidonic acid (AA, 20:4n-6) obtained in this research were considered low. The values varied from0.06 to 0.14% among fish from different fish farms.

AGMI presented high proportions of the fatty acid groups, characterized the total lipids in the orbital cavity. According to Ewin (1997Ewin, J. (1997). O lado sadio das gorduras. Rio de Janeiro, RJ: Campus Ltda. Press.),from the nutritional point of view, the ingestion of saturated fatty acids increases the content of serum cholesterol in humans; however, the total cholesterol content in plasma decreases when the ingestion of saturated fatty acids is replaced with monounsaturated fatty acids.

The relations or proportions between fatty acids have been studied to assess and identify the risk factor of food regarding the increase of cholesterol level in human blood. The biological effect of essential fatty acids depends on the ratio between LC-PUFA/SFA. This relationship helps to determine the risk factors in food (Marques et al., 2007Marques, A. V. M. S., Costa, R. G., Silva, A. M. A., Pereira Filho, J. M., Madruga, M. S., & Lira Filho, G. E. (2007). Rendimento, composição tecidual e musculosidade da carcaça de cordeiros Santa Inês alimentados com diferentes níveis de feno de flor-de-seda na dieta. Revista Brasileira de Zootecnia, 36(3), 610-617.).

The n-6 and n-3 fatty acids influenced the metabolism of eicosanoids, the gene expression, and the inter-cellular communication. The composition of LC-PUFA in the cellular membranes considerably depends on the amount ingested. In this sense, it is important to consider the recommendations of the appropriate amount of these fatty acids for the daily intake, as well as the balance of the n-6/n-3ratio, which is essential for the human metabolism, preventing cardiovascular and chronic degenerative diseases, leading to a better mental health (Simopoulus, 2000Simopoulus, A. P. (2000). Human Requirement for N-3 Polyunsaturated Fatty Acids. Poultry Science, 79, 961-970.).

Many countries, such as Germany, Canada, Japan, and the USA, have already made recommendations on the omega 6/omega 3 ratio for human health. In Canada, the recommended proportion of n-6/n-3 should be between 4.0 and 10, according to the Scientific Review Committee (1990Scientific Review Committee (1990). Nutrition recommendations. Ottawa, Canada, CA: Canadian Government Publishing Centre, Suply and Services. ).

Fatty acid composition of feed

The fatty acids composition and the sum of SFA, MUFA, LC-PUFA, fatty acids n-6 and n-3, and the LC-PUFA/SFA and n-6/n-3ratiosin the feed are listed in Table 2.

Twenty-six components were detected in the total lipids of feed. In decreasing order, linolenic acid (LA, 18:2n-6), oleic acid (18:1n-9), palmitic acid (16:0), alpha linoleic acid (18:3n-3), vaccenic acid (18:1n-7), palmitoleic acid (16:1n-7) and myristic acid (14:0) were the most abundant fatty acids detected.

Lipids are fundamental to the health, survival, and success of fish populations. The functions of these molecules in fish growth are well defined, namely: energetic, structural, hormonal, precursors of eicosanoids and among others (Haliloglu, Bayır, Sirkecioǧlu, Aras, & Atamanalp, 2003Haliloglu, H. I., Bayır, A., Sirkecioǧlu, A. N., Aras, N. M., & Atamanalp, M. (2003). Comparisons of fatty acid composition in some tissues of rainbow (Oncorhynchus mykiss) living in seawater and freshwater. Food Chemistry, 86(1), 55-59.). Among lipids, polyunsaturated fatty acids are required for normal growth and development, mainly by maintaining the structural and functional integrity of membranes (Sargent, Bell, McEvoy, Tocher, & Estevez, 1999Sargent, J., Bell, G., McEvoy, L., Tocher, D., & Estevez, A. (1999). Recent developments in the essential fatty acid nutrition of fish. Aquaculture , 177, 191-199.).

High proportions of LC-PUFA with values of 36.85 and 41.459% respectively for fish from farm II and for fish from farm V characterized the total lipids in the feed. The linolenic acid was the main responsible for the high content of LC-PUFA (Table 2).

Diets given to fish directly affect the muscle composition, especially regarding the lipid content and the composition of fatty acids (Om et al., 2001Om, A. D., Umino, T., Nakagawa, H., Sasaki, T., Okada, K., Asano, M., & Nakagawa, A. (2001). The effects of dietary EPA and DHA fortification on lipolysis activity and physiological function in juvenile black sea bream Acanthopagrusschlegeli (Bleeker). Aquaculture Research, 32(1), 255-262.). The importance of lipids in diets for aquatic organisms is associated with the increase of palatability, the improvement of the muscle tissue texture and the fatty acids profile (Martino & Portz, 2006Martino, R. C., & Portz, L. (2006). Estratégias para desenvolvimento de rações para peixes carnívoros de água doce: fontes de proteína e lipídios. Tópicos Especiais em Biologia Aquática e Aquicultura, Aquaciência 2004, 125-138.; Martino & Takahashi, 2001Martino, R., & Takahashi, N. S. (2001). A importância da adição de lipídios em rações para a aquicultura. Óleos e Grãos, 58, 32-37.). Rainuzzo, Reitan, and Olsen (1997Rainuzzo, J. R., Reitan, K. I., & Olsen, I. (1997). The significant of lipids at early stages of marine fish: a review. Aquaculture, 155(1), 103-115.) emphasized the importance of knowing type and amount of lipid in the diet of animals because of their influence on the quality and quantity of PUFA in the tissues.

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Table 2.Total
lipid fatty acid composition (%) in feed of Nile tilapia.

Lipid Nutritional Quality

The thrombogenicity index and atherogenicity index were proposed by Ulbricht and Southgate (1991Ulbricht, T. L. V., & Southgate, D. A. T. (1991). Coronary heart disease: seven dietary factors. Lancet , 338(8773), 985-992.) with the aim of considering not only the family of fatty acids but also their biological effect. Thus, TI relates the content of saturated fatty acids 14:0 16:0 and 18:0 (prothrombotic) with the content of monounsaturated and polyunsaturated fatty acids n-3 and n-6 (antithrombotic), indicating the contribution the food product may have in the formation of clots in the blood vessels (Senso, Suarez, Ruiz-Cara, & Garcia-Gallego, 2007Senso, L., Suarez, M. D., Ruiz-Cara, T., & Garcia-Gallego, M. (2007). On the possible effects of harvesting season and chilled storage on the fatty acid profile of the fillet of farmed gilthead sea bream (Sparus aurata). Food Chemistry , 101(1), 298-307.). On the other hand, AI is based on the information about the effect the several fatty acids have on the plasmatic cholesterol, specifically in the formation of LDL and HDL.

The values of the atherogenicity index (AI), thrombogenicity index (TI) and theratio between hypocholesterolemic and hypercholesterolemic fatty acids (H/H) are shown in Table 3.

Lipid nutritional quality indicesfor the adipose tissue from the orbital cavity of tilapia ranged from 0.49 to 0.58 for AI; 0.55 and 0.74 for TI. The ratio between hypocholesterolemic and hypercho-lesterolemic fatty acids presented values above 2 for fish farms I and VI (Table 3).

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Table 3
Total lipid nutritional quality indexes in adipose tissue from the orbital cavity of Nile tilapia.

The atherogenicity index results found by Tonial et al. (2011Tonial, I. B., Bravo, C. E., Souza, N. E., Matsushita, M., Furuya, W., & Visentainer, J. V. (2011). Qualidade nutricional dos lipídios de tilápias (Oreochromis niloticus) alimentadas com ração suplementada com óleo de soja. Alimentos e Nutrição, 22(1), 103-112.), in fillets of tilapiafed diets supplemented with soybean oil, varied from 0.67 to 0.49, from 0 to 90 days, respectively. Senso et al. (2007Senso, L., Suarez, M. D., Ruiz-Cara, T., & Garcia-Gallego, M. (2007). On the possible effects of harvesting season and chilled storage on the fatty acid profile of the fillet of farmed gilthead sea bream (Sparus aurata). Food Chemistry , 101(1), 298-307.) reported values from 0.21 to 0.29 for AI in Sparusarata. These studies presentedlower values, which can be justified by the factthatthe fish tissue (fillet) has less polyunsaturated fatty acids compared to the fish eye, as well as by the interference of other factors, such as diet.

There are no recommended values for the AI and TI. It is considered that low values are related to more favorable fatty acids, in terms of health. Therefore, low values of these indices represent a beneficial effect on human health since they help to prevent the occurrence of coronary diseases (Turan, Sönmez, & Kaya, 2007Turan, H., Sӧnmez, G., & Kaya, Y. (2007). Fatty acid profile and proximate composition of the thornback ray (Raja clavata, L. 1758) from the Sinop coast in the Black Sea. Journal of Fisheries Sciences, 1(2), 97-103.).

Values between 1.87 and 2.18were found for the H/H ratio in the adipose tissue from the orbital cavity analyzed. These values were higher than those observed by Ramos, Ramos, Hiane, and Souza (2008Ramos, M. M., Ramos Filho, M. I. L., Hiane, P. A., & Souza, E. M. T. (2008). Perfil lipídico de quatro espécies de peixes da região pantaneira de Mato Grosso do Sul. Food Science and Technology (Campinas), 28(2), 361-365. ), in freshwater fish raised in Pantanal, State of Mato Grosso, Brazil, who verified values ranging from 1.49 to 1.84 in themuscleof Salminus maxillosus and Pseudoplatystoma coruscans, respectively.

According to the literature, the higher the H/H index, the more suitable is the fat for the human diet. It is worth emphasizing that, for meat products, the ideal value should be close to 2 (Bentes, Souza, Mendonça, & Simões, 2009Bentes, A. S., Souza, H. A. L., Mendonça, X. M. F. D., & Simões, M. G. (2009). Caracterização física e química e perfil lipídico de três espécies de peixes amazônicos. Revista Brasileira de Tecnologia Agroindustrial, 3(2), 97-108.). The H/H ratio in the adipose tissue from the orbital cavity of fish was strongly influenced by the content of oleic acid.

Conclusion

The LC-PUFA/SFA ratio of the adipose tissue of the orbital cavity was considered satisfactory for the humandiet because it presented values within the recommended levels, which are above 0.45.The adipose tissue of the orbital cavity of fish presented essential fatty acids, such as linoleic acid and alpha-linolenic acid, in addition to fatty acids of important nutritional value such as arachidonic acid, eicosapentaenoic acid, and docosahexaenoic acid. Regarding the lipid nutritional quality, through atherogenicity and thrombogenicity indexes and the H/Hratio, the tilapia residue analyzed in the present study can be recommended for human consumption or to elaborate products for animal feeding.

Acknowledgements

The authors would like to thank Conselho Nacional de Desenvolvimento Científico e Tecnológico- CNPq for support and scholarships.

References

Almeida, N. M., & Franco, M. R. B. (2007). Fatty acid composition of total lipids, neutral lipids and phospholipids in wild and farmed matrinxã (Bryconcephalus) in the Brazilian Amazon area. Journal of the Science of Food and Agriculture, 87(14), 2596-2603.
Almeida, N. M., Visentainer, J. V., & Franco, M. R. B. (2008). Composition of total, neutral and phospholipids in wild and farmed tambaqui (Colossoma macropomum) in the Brazilian Amazon area. Journal of the Science of Food and Agriculture , 88(10), 1739-1747.
Bentes, A. S., Souza, H. A. L., Mendonça, X. M. F. D., & Simões, M. G. (2009). Caracterização física e química e perfil lipídico de três espécies de peixes amazônicos. Revista Brasileira de Tecnologia Agroindustrial, 3(2), 97-108.
Bligh, E. G., & Dyer, W. J. (1959). A rapid method of total lipid extraction and purification. Canadian Journal of Biochemistry and Physiology, 37(1), 911-917.
Cengiz, E. I., Kan, Y., Kizmaz, V., Bashan, M., & Yanar, M. (2012). The protective role of vitamin E on the fatty acid composition of phospholipid structure in gill and liver tissues of Oreochromisniloticus exposed to deltamethrin. Ecotoxicology and Environmental Safety, 80(1), 381-385.
Connolly, J. M., Coleman, M., & Rose, D. P. (1997). Effects of dietary fatty acids on DU145 human prostate cancer cell growth in athymic nude mice. Nutrition and Cancer, 29(2), 114-119.
Ewin, J. (1997). O lado sadio das gorduras Rio de Janeiro, RJ: Campus Ltda. Press.
Food and Agriculture Organization [FAO]. (2016). El estado mundial de la pesca y la acuicultura 2016 Contribuición a la seguridade alimentaria y la nutrición para todos Roma, IT: FAO Press release.
Haliloglu, H. I., Bayır, A., Sirkecioǧlu, A. N., Aras, N. M., & Atamanalp, M. (2003). Comparisons of fatty acid composition in some tissues of rainbow (Oncorhynchus mykiss) living in seawater and freshwater. Food Chemistry, 86(1), 55-59.
Inhamuns, A. J., & Franco, M. R. B. (2008). EPA and DHA quantification in two species of freshwater fish from Central Amazonia. Food Chemistry , 107(2), 587-591.
Inhamuns, A. J., Franco, M. R. B., & Batista, W. S. (2009). Seasonal variations in total fatty acid composition of muscles and eye sockets of tucunaré (Cichla sp.) from the Brazilian Amazon area. Food Chemistry , 117(2), 272-275.
Joseph, J. D., & Ackman, R. G. (1992). Capillary column gas chromatographic method for analysis of encapsulated fish oils and fish oil ethyl esters: collaborative study. Journal of AOAC International, 75(3), 488-506.
Lorgeril, M., Renaud, S., Mamelle, N., Salen, P., Martin, J. L., & Monjaud, I. (1994). Mediterranean alpha-linolenic acid-rich diet in secondary prevention of coronary heart disease. Lancet, 343, 1454-1459.
Marques, A. V. M. S., Costa, R. G., Silva, A. M. A., Pereira Filho, J. M., Madruga, M. S., & Lira Filho, G. E. (2007). Rendimento, composição tecidual e musculosidade da carcaça de cordeiros Santa Inês alimentados com diferentes níveis de feno de flor-de-seda na dieta. Revista Brasileira de Zootecnia, 36(3), 610-617.
Martino, R. C., & Portz, L. (2006). Estratégias para desenvolvimento de rações para peixes carnívoros de água doce: fontes de proteína e lipídios. Tópicos Especiais em Biologia Aquática e Aquicultura, Aquaciência 2004, 125-138.
Martino, R., & Takahashi, N. S. (2001). A importância da adição de lipídios em rações para a aquicultura. Óleos e Grãos, 58, 32-37.
Ministério da Pesca de Aquicultura (MPA). (2015). Plano de desenvolvimento da aquicultura brasileira - 2015/2020 Brasília, DF: MPA.
Navarro, R. D., Navarro, F. K. S. P., Ribeiro Filho, O. P., Ferreira, W. M., Pereira, M. M., & Seixas Filho, J. T. (2012). Quality of polyunsaturated fatty acids in Nile tilapias (Oreochromisniloticus) fed with vitamin E supplementation. Food Chemistry , 134(1), 215-218.
Om, A. D., Umino, T., Nakagawa, H., Sasaki, T., Okada, K., Asano, M., & Nakagawa, A. (2001). The effects of dietary EPA and DHA fortification on lipolysis activity and physiological function in juvenile black sea bream Acanthopagrusschlegeli (Bleeker). Aquaculture Research, 32(1), 255-262.
Rainuzzo, J. R., Reitan, K. I., & Olsen, I. (1997). The significant of lipids at early stages of marine fish: a review. Aquaculture, 155(1), 103-115.
Ramos, M. M., Ramos Filho, M. I. L., Hiane, P. A., & Souza, E. M. T. (2008). Perfil lipídico de quatro espécies de peixes da região pantaneira de Mato Grosso do Sul. Food Science and Technology (Campinas), 28(2), 361-365.
Rose, D. P., & Connolly, J. M. (1999). Omega-3 fatty acids as cancer chemopreventive agents. Pharmacology & Therapeutics, 83(3), 217-244.
Sargent, J., Bell, G., McEvoy, L., Tocher, D., & Estevez, A. (1999). Recent developments in the essential fatty acid nutrition of fish. Aquaculture , 177, 191-199.
Santos-Silva, J., Bessa, R. J. B., & Santos-Silva, F. (2002). Effect of genotype, feeding system and slaughter weight on the quality of light lambs: II. Fatty acid composition of meat.Livestock Production Science, 77(2-3), 187-194.
Scientific Review Committee (1990). Nutrition recommendations Ottawa, Canada, CA: Canadian Government Publishing Centre, Suply and Services.
Senso, L., Suarez, M. D., Ruiz-Cara, T., & Garcia-Gallego, M. (2007). On the possible effects of harvesting season and chilled storage on the fatty acid profile of the fillet of farmed gilthead sea bream (Sparus aurata). Food Chemistry , 101(1), 298-307.
Simopoulus, A. P. (2000). Human Requirement for N-3 Polyunsaturated Fatty Acids. Poultry Science, 79, 961-970.
Singh, R. B., Niaz, M. A., Sharma, J. P., Kumar, R., & Rastogi, V. (1997). Randomized, double-blind, placebo-controlled trial of fish oil and mustard oil in patients with suspected acute myocardial infarction: the Indian Experiment of Infarct Survival. Cardiovascular Drugs and Therapy, 11(3), 485-491.
Statistical Analisys System [SAS]. (2004). SAS/STAT User guide, Version 9.1.2 Cary, NC: SAS Institute Inc.
Steffens, W. (1997). Effects of variation in essential fatty acids in fish feeds on nutritive value of fresh water fish for humans. Aquaculture , 151, 97-119.
Stevanato, F. V., Almeida, V. V., Matsushita, M., Oliveira, C. C., Souza, N. E., & Visentainer, J. V. (2008). Fatty acids and nutrients in the flour made from tilapia (Oreochromis niloticus) heads. Food Science and Technology, 28(2), 440-443.
Stevanato, F. B., Petenucci, M. E., Matsushita, M., Mesomo, M. C., Souza, N. E., Visentainer, J. E. L., … Visentainer, J. V. (2007). Avaliação química e sensorial da farinha de resíduo de tilápias na forma de sopa. Food Science and Technology , 27, 567-571.
Stransky, K., Jursik, T., & Vitek, A. (1997). Standard equivalent chain length values of monoenic and polyenic (methylene interrupted) fatty acids. Journal of High Resolution Chromatography, 20(3), 143-158.
Thompson, R. H. (1997). Simplifying fatty acid analyses using a standard set of gas-liquid chromatographic conditions: II. Equivalent chain length values for cis- and trans- isomers of monoethylenic C18 fatty acid methyl esters for Carbowax-20M liquid phase. Journal of Chromatographic Science, 35, 598-602.
Tonial, I. B., Matsushita, M., Furuya, W. M., Souza, N. E., & Visentainer, J. V. (2012). Fatty Acid Contents in Fractions of Neutral Lipids and Phospholipids of Fillets of Tilapia Treated with Flaxseed Oil. Journal of the American Oil Chemists’ Society, 89, 1495-1500.
Tonial, I. B., Bravo, C. E., Souza, N. E., Matsushita, M., Furuya, W., & Visentainer, J. V. (2011). Qualidade nutricional dos lipídios de tilápias (Oreochromis niloticus) alimentadas com ração suplementada com óleo de soja. Alimentos e Nutrição, 22(1), 103-112.
Tully, A. M., Roche, H. M., Doyle, R., Fallon, C., Bruce, I., Lawlor, B., … Gibney, M. J. (2003). Low serum cholesteryl ester-docosahexaenoic acid levels in Alzheimer’s disease: a case - control study. British Journal of Nutrition, 89(4), 483-489.
Turan, H., Sӧnmez, G., & Kaya, Y. (2007). Fatty acid profile and proximate composition of the thornback ray (Raja clavata, L. 1758) from the Sinop coast in the Black Sea. Journal of Fisheries Sciences, 1(2), 97-103.
Ulbricht, T. L. V., & Southgate, D. A. T. (1991). Coronary heart disease: seven dietary factors. Lancet , 338(8773), 985-992.
Yehuda, S., Rabinovitz, S., Carasso, R. L., & Mostofsky, D. I. (2002). The role of polyunsaturated fatty acids in restoring the aging neuronal membrane. Neurobiology of Aging, 23, 843-853.
Youdim, K. A., Martin, A., & Joseph, J. A. (2000). Essential fatty acids and the brain: possible health implications. International Journal of Developmental Neuroscience, 18(4-5), 383-399.

Publication Dates

Publication in this collection
Dec 2017

History

Received
19 Mar 2017
Accepted
24 May 2017

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Almeida, N. M., & Franco, M. R. B. (2007). Fatty acid composition of total lipids, neutral lipids and phospholipids in wild and farmed matrinxã (Bryconcephalus) in the Brazilian Amazon area. Journal of the Science of Food and Agriculture, 87(14), 2596-2603.

[2] Almeida, N. M., Visentainer, J. V., & Franco, M. R. B. (2008). Composition of total, neutral and phospholipids in wild and farmed tambaqui (Colossoma macropomum) in the Brazilian Amazon area. Journal of the Science of Food and Agriculture , 88(10), 1739-1747.

[3] Bentes, A. S., Souza, H. A. L., Mendonça, X. M. F. D., & Simões, M. G. (2009). Caracterização física e química e perfil lipídico de três espécies de peixes amazônicos. Revista Brasileira de Tecnologia Agroindustrial, 3(2), 97-108.

[4] Bligh, E. G., & Dyer, W. J. (1959). A rapid method of total lipid extraction and purification. Canadian Journal of Biochemistry and Physiology, 37(1), 911-917.

[5] Cengiz, E. I., Kan, Y., Kizmaz, V., Bashan, M., & Yanar, M. (2012). The protective role of vitamin E on the fatty acid composition of phospholipid structure in gill and liver tissues of Oreochromisniloticus exposed to deltamethrin. Ecotoxicology and Environmental Safety, 80(1), 381-385.

[6] Connolly, J. M., Coleman, M., & Rose, D. P. (1997). Effects of dietary fatty acids on DU145 human prostate cancer cell growth in athymic nude mice. Nutrition and Cancer, 29(2), 114-119.

[7] Ewin, J. (1997). O lado sadio das gorduras Rio de Janeiro, RJ: Campus Ltda. Press.

[8] Food and Agriculture Organization [FAO]. (2016). El estado mundial de la pesca y la acuicultura 2016 Contribuición a la seguridade alimentaria y la nutrición para todos Roma, IT: FAO Press release.

[9] Haliloglu, H. I., Bayır, A., Sirkecioǧlu, A. N., Aras, N. M., & Atamanalp, M. (2003). Comparisons of fatty acid composition in some tissues of rainbow (Oncorhynchus mykiss) living in seawater and freshwater. Food Chemistry, 86(1), 55-59.

[10] Inhamuns, A. J., & Franco, M. R. B. (2008). EPA and DHA quantification in two species of freshwater fish from Central Amazonia. Food Chemistry , 107(2), 587-591.

[11] Inhamuns, A. J., Franco, M. R. B., & Batista, W. S. (2009). Seasonal variations in total fatty acid composition of muscles and eye sockets of tucunaré (Cichla sp.) from the Brazilian Amazon area. Food Chemistry , 117(2), 272-275.

[12] Joseph, J. D., & Ackman, R. G. (1992). Capillary column gas chromatographic method for analysis of encapsulated fish oils and fish oil ethyl esters: collaborative study. Journal of AOAC International, 75(3), 488-506.

[13] Lorgeril, M., Renaud, S., Mamelle, N., Salen, P., Martin, J. L., & Monjaud, I. (1994). Mediterranean alpha-linolenic acid-rich diet in secondary prevention of coronary heart disease. Lancet, 343, 1454-1459.

[14] Marques, A. V. M. S., Costa, R. G., Silva, A. M. A., Pereira Filho, J. M., Madruga, M. S., & Lira Filho, G. E. (2007). Rendimento, composição tecidual e musculosidade da carcaça de cordeiros Santa Inês alimentados com diferentes níveis de feno de flor-de-seda na dieta. Revista Brasileira de Zootecnia, 36(3), 610-617.

[15] Martino, R. C., & Portz, L. (2006). Estratégias para desenvolvimento de rações para peixes carnívoros de água doce: fontes de proteína e lipídios. Tópicos Especiais em Biologia Aquática e Aquicultura, Aquaciência 2004, 125-138.

[16] Martino, R., & Takahashi, N. S. (2001). A importância da adição de lipídios em rações para a aquicultura. Óleos e Grãos, 58, 32-37.

[17] Ministério da Pesca de Aquicultura (MPA). (2015). Plano de desenvolvimento da aquicultura brasileira - 2015/2020 Brasília, DF: MPA.

[18] Navarro, R. D., Navarro, F. K. S. P., Ribeiro Filho, O. P., Ferreira, W. M., Pereira, M. M., & Seixas Filho, J. T. (2012). Quality of polyunsaturated fatty acids in Nile tilapias (Oreochromisniloticus) fed with vitamin E supplementation. Food Chemistry , 134(1), 215-218.

[19] Om, A. D., Umino, T., Nakagawa, H., Sasaki, T., Okada, K., Asano, M., & Nakagawa, A. (2001). The effects of dietary EPA and DHA fortification on lipolysis activity and physiological function in juvenile black sea bream Acanthopagrusschlegeli (Bleeker). Aquaculture Research, 32(1), 255-262.

[20] Rainuzzo, J. R., Reitan, K. I., & Olsen, I. (1997). The significant of lipids at early stages of marine fish: a review. Aquaculture, 155(1), 103-115.

[21] Ramos, M. M., Ramos Filho, M. I. L., Hiane, P. A., & Souza, E. M. T. (2008). Perfil lipídico de quatro espécies de peixes da região pantaneira de Mato Grosso do Sul. Food Science and Technology (Campinas), 28(2), 361-365.

[22] Rose, D. P., & Connolly, J. M. (1999). Omega-3 fatty acids as cancer chemopreventive agents. Pharmacology & Therapeutics, 83(3), 217-244.

[23] Sargent, J., Bell, G., McEvoy, L., Tocher, D., & Estevez, A. (1999). Recent developments in the essential fatty acid nutrition of fish. Aquaculture , 177, 191-199.

[24] Santos-Silva, J., Bessa, R. J. B., & Santos-Silva, F. (2002). Effect of genotype, feeding system and slaughter weight on the quality of light lambs: II. Fatty acid composition of meat.Livestock Production Science, 77(2-3), 187-194.

[25] Scientific Review Committee (1990). Nutrition recommendations Ottawa, Canada, CA: Canadian Government Publishing Centre, Suply and Services.

[26] Senso, L., Suarez, M. D., Ruiz-Cara, T., & Garcia-Gallego, M. (2007). On the possible effects of harvesting season and chilled storage on the fatty acid profile of the fillet of farmed gilthead sea bream (Sparus aurata). Food Chemistry , 101(1), 298-307.

[27] Simopoulus, A. P. (2000). Human Requirement for N-3 Polyunsaturated Fatty Acids. Poultry Science, 79, 961-970.

[28] Singh, R. B., Niaz, M. A., Sharma, J. P., Kumar, R., & Rastogi, V. (1997). Randomized, double-blind, placebo-controlled trial of fish oil and mustard oil in patients with suspected acute myocardial infarction: the Indian Experiment of Infarct Survival. Cardiovascular Drugs and Therapy, 11(3), 485-491.

[29] Statistical Analisys System [SAS]. (2004). SAS/STAT User guide, Version 9.1.2 Cary, NC: SAS Institute Inc.

[30] Steffens, W. (1997). Effects of variation in essential fatty acids in fish feeds on nutritive value of fresh water fish for humans. Aquaculture , 151, 97-119.

[31] Stevanato, F. V., Almeida, V. V., Matsushita, M., Oliveira, C. C., Souza, N. E., & Visentainer, J. V. (2008). Fatty acids and nutrients in the flour made from tilapia (Oreochromis niloticus) heads. Food Science and Technology, 28(2), 440-443.

[32] Stevanato, F. B., Petenucci, M. E., Matsushita, M., Mesomo, M. C., Souza, N. E., Visentainer, J. E. L., … Visentainer, J. V. (2007). Avaliação química e sensorial da farinha de resíduo de tilápias na forma de sopa. Food Science and Technology , 27, 567-571.

[33] Stransky, K., Jursik, T., & Vitek, A. (1997). Standard equivalent chain length values of monoenic and polyenic (methylene interrupted) fatty acids. Journal of High Resolution Chromatography, 20(3), 143-158.

[34] Thompson, R. H. (1997). Simplifying fatty acid analyses using a standard set of gas-liquid chromatographic conditions: II. Equivalent chain length values for cis- and trans- isomers of monoethylenic C18 fatty acid methyl esters for Carbowax-20M liquid phase. Journal of Chromatographic Science, 35, 598-602.

[35] Tonial, I. B., Matsushita, M., Furuya, W. M., Souza, N. E., & Visentainer, J. V. (2012). Fatty Acid Contents in Fractions of Neutral Lipids and Phospholipids of Fillets of Tilapia Treated with Flaxseed Oil. Journal of the American Oil Chemists’ Society, 89, 1495-1500.

[36] Tonial, I. B., Bravo, C. E., Souza, N. E., Matsushita, M., Furuya, W., & Visentainer, J. V. (2011). Qualidade nutricional dos lipídios de tilápias (Oreochromis niloticus) alimentadas com ração suplementada com óleo de soja. Alimentos e Nutrição, 22(1), 103-112.

[37] Tully, A. M., Roche, H. M., Doyle, R., Fallon, C., Bruce, I., Lawlor, B., … Gibney, M. J. (2003). Low serum cholesteryl ester-docosahexaenoic acid levels in Alzheimer’s disease: a case - control study. British Journal of Nutrition, 89(4), 483-489.

[38] Turan, H., Sӧnmez, G., & Kaya, Y. (2007). Fatty acid profile and proximate composition of the thornback ray (Raja clavata, L. 1758) from the Sinop coast in the Black Sea. Journal of Fisheries Sciences, 1(2), 97-103.

[39] Ulbricht, T. L. V., & Southgate, D. A. T. (1991). Coronary heart disease: seven dietary factors. Lancet , 338(8773), 985-992.

[40] Yehuda, S., Rabinovitz, S., Carasso, R. L., & Mostofsky, D. I. (2002). The role of polyunsaturated fatty acids in restoring the aging neuronal membrane. Neurobiology of Aging, 23, 843-853.

[41] Youdim, K. A., Martin, A., & Joseph, J. A. (2000). Essential fatty acids and the brain: possible health implications. International Journal of Developmental Neuroscience, 18(4-5), 383-399.

Fatty acid	Fish Farm
Fatty acid	I	II	III	IV	V	VI
14:0	2.58±0,06^c	2.94±0.02^abc	2.82±0.01^bc	3.34±0.08^a	3.16±0.07^ab	3.07±0.16^ab
14:1n-9	0.17±0.00^b	0.42±0.00^a	0.17±0.01^b	0.28±0.05^b	0.20±0.02^b	0.17±0.00^b
14:1n-7	0.13±0.00^b	0.16±0.01^ab	0.16±0.00a^b	0.20±0.03^a	0.19±0.00^a	0.16±0.01^ab
15:0	0.26±0,02^b	0.57±0.01^a	0.24±0.00^b	0.29±0.01^b	0.30±0.01^b	0.28±0.02^b
16:0	22.56±0.39^b	24.82±0.34^ab	24.30±0.05^ab	25.89±0.30^a	24.20±0.48^ab	24.08±1.2^ab
16:1n-9	0.67±0,01^b	0.85±0.01^a	0.62±0.01^b	0.67±0.01^b	0.69±0.02^b	0.67±0.04^b
16:1n-7	4.56±0.06^b	6.13±0.02^a	5.01±0.02^bc	5.74±0.08^ab	5.58±0.11^ab	5.12±0.3^b
17:0	0.645±0.01^b	1.19±0.02^a	0.51±0.02^b	0.59±0.01^ab	0.55±0.01^b	0.57±0.02^bc
17:1n-9	0.31±0.00^b	0.43±0.01^a	0.21±0.01^c	0.31±0.00^b	0.25±0.00^c	0.23±0.02^c
18:0	5.61±0.13^b	0.75±0.00^d	6.72±0.03^a	0.30±0.00^d	0.70±0.00^d	3.47±0.14^b
18:1n-9	29.59±0.44^b	29.62±0.27^b	33.08±0.22^a	34.22±0.06^a	33.53±0.52^a	29.35±0.20^b
18:1n-7	3.49±0.07^b	4.29±0.00^a	3.73±0.04^ab	4.16±0.17^a	3.89±0.08^ab	3.84±0.2^ab
18:2n-6	21.46±1.06^a	20.74±0.76^a	16.17±0.47^a	17.36±0.75^a	19.99±1.79^a	18.92±2.62^a
18:3n-6	1.42±0.14^a	1.06±0.02^a	0.79±0.00a	0.91±0.05^a	0.85±0.02^a	0.82±0.06^a
18:3n-3	1.25±0.02^a	1.87±0.05^a	1.14±0.01^b	1.13±0.02^b	1.13±0.02^b	1.12±0.06^b
20:0	0.30±0.01^b	0.44±0.01^a	0.30±0.02^b	0.32±0.02^b	0.27±0.01^b	0.27±0.02^b
20:1n-9	0.18±0.00^a	0.20±0.01 ^a	0.10±0.01^b	0.95±0.01^b	0.10±0.00^b	0.10±0.00^b
21:0	0.71±0.02^a	0.99±0.01^a	0.76±0.01^a	0.89±0.00^a	0.77±0.01^a	0.81±0.14^a
20:3n-3	0.80±0.02^a	0.77±0.02^a	0.73±0.00^a	0.70±0.00^a	0.71±0.00^a	0.69±0.05^a
20:2n-6	0.91±0.02^a	0.79±0.03^a	0.83±0.01^a	0.60±0.01^b	0.85±0.01^a	0.92±0.06^a
20:4n-6	0.12±0.00^a	0.07±0.00^b	0.14±0.01^a	0.06±0.0^b	0.06±0.00^b	0.08±0.00^b
20:5n-3	1.01±0.09^b	0.45±0.08^b	0.76±0.06^b	1.08±0.17^b	1.40±0.31^ab	2.19±024^a
22:4n-6	0.54±0.02^a	0.05±0.01^b	0.43±0.12^a	0.41±0.07^a	0.50±0.02^a	0.525±0.04^a
24:0	0.41±0.01^a	0.47±0.02^a	0.36±0.00^a	0.40±0.00^a	0.42±0.05^a	0.41±0.04^a
24:1n-9	0.03±0.00^a	0.06±0.00^a	0.03±0.01^a	0.03±0.00^a	0.04±0.01^a	0.03±0.00^a
22:6n-3	0.32±0.01^c	0.63±0.03^a	0.39±0.00^c	0.51±0.01^b	0.37±0.01^c	0.37±0.03^c
SFA	33.07±0.61^b	31.48±0.38^ab	35.99±0.06^a	31.73±0.42^ab	29.72±0.53^b	32.80±1.73^ab
MUFA	39.14±0.59^b	42.13±0.32^ab	43.09±0.22^ab	45.69±0.40^a	44.45±0.72^ab	41.80±2.5^ab
LC-PUFA	27.80±1.20^a	26.39±0.70^ab	20.92±0.15^c	22.58±0.81^bc	25.85±1.24^abc	25.40±0.78^abc
ΣFAn-6	24.44±1.16^a	22.70±0.71^a	18.22±0.21^a	19.18±0.47^a	22.24±1.77^a	21.25±2.46^a
ΣFAn-3	3.37±0.03ª	3.70±0.01^a	2.71±0.37^a	3.41±0.35^a	3.60±0.54^a	4.16±1.69^a
LC-PUFA/SFA	0.84±0.05ª	0.84±0.03^a	0.58±0.00^b	0.72±0.03^ab	0.87±0.06^a	0.78±0.02^ab
n-6/n-3	7.27±0.27ª	6.14±0.21^a	6.87±1.0^a	5.68±0.44^a	6.40±1.45^a	6.41±3.19^a

Fatty acid	Fish Farm
Fatty acid	I	II	III	IV	V	VI
14:0	1.15±0.02^bc	1.43±0.02^a	1.19±0.04^b	1.065±0.02^cd	1.25±0.01^b	1.02±0.03^d
14:1n-9	0.15±0.0^b	0.29±0.03^a	0.15±0.00^b	0.135±0.01^b	0.18±0.00^b	0.14±0.01^b
14:1n-7	0.10±0.0^d	0.15±0.0^a	0.13±0.00^b	0.12±0.0b^c	0.12±0.00^bc	0.11±0.00^cd
15:0	0.25±0.01^b	0.33±0.0^a	0.20±0.00^c	0.20±0.01^c	0.30±0.00^a	0.20±0.00^c
16:0	18.82±0.15^ab	19.11±0.27^a	18.20±0.36^ab	17.90±0.07^b	18.85±0.04^ab	17.79±0.05^b
16:1n-9	0.30±0.01^a	0.22±0.02^a	0.22±0.03^a	0.14±0.01^a	0.20±0.08^a	0.13±0.01^a
16:1n-7	1.64±0.01^a	1.41±0.03^bc	1.47±0.04^b	1.26±0.02^d	1.04±0.04^e	1.26±0.01^cd
17:0	0.70±0.01^b	0.77±0.01^a	0.49±0.01^c	0.49±0.01^c	2.67±0.01^b	0.49±0.00^c
17:1n-9	0.14±0.0^b	0.19±0.01^a	0.16±0.01^b	0.15±0.00^b	0.18±0.00^a	0.15±0.00^b
18:0	9.06±0.07^bc	10.55±0.2^a	8.40±0.12^d	8.49±0.01^cd	9.70±0.04^b	8.55±0.14^cd
18:1n-9	25.81±0.07^a	25.86±0.51^a	27.29±0.53^a	28.54±0.27^a	23.10±0.08^a	22.93±5.82^a
18:1n-7	2.08±0.03^a	1.96±0.0^a	2.22±0.05^a	2.42±0.25^a	1.96±0.08^a	2.37±0.14^a
18:2n-6	35.20±0.55^ab	32.99±0.89^b	35.74±1.13^ab	34.81±0.22^ab	37.57±0.20^a	34.74±0.13^ab
18:3n-6	0.09±0.01^a	0.05±0.01^a	0.09±0.03^a	0.04±0.01^a	0.04±0.01^a	0.04±0.00^a
18:3n-3	2.36±0.02^c	2.11±0.04^d	2.40±0.04^c	2.63±0.0^c	3.00±0.03^a	2.63±0.02^c
20:0	0.65±0.00^a	0.65±0.02^a	0.50±0.01^b	0.52±0.0^b	0.50±0.02^b	0.51±0.01^b
20:1n-9	0.03±0.01	0.02±0.00^a	0.02±0.01^a	0.02±0.0^a	0.34±0.03^a	0.20±0.19^a
21:0	0.13±0.01^a	0.13±0.01^a	0.13±0.02^a	0.07±0.01^a	0.75±0.00^a	0.11±0.02^a
20:3n-3	0.09±0.0^a	0.05±0.01^c	0.10±0.01^a	0.75±0.0^ab	0.05±0.00^bc	0.75±0.00^ab
20:2n-6	0.39±0.0^a	0.23±0.01^b	0.22±0.01^bc	0.15±0.0^c	0.21±0.02^bc	0.17±0.02^bc
20:4n-6	0.1±0.0^b	0.85±0.00^b	0.09±0.01^b	0.06±0.0^c	0.16±0.00^a	0.60±0.00^c
20:5n-3	0.37±0.18^b	1.05±0.15^a	0.27±0.05^a	0.09±0.03^b	0.12±0.07^b	0.08±0.02^b
22:4n-6	0.18±0.00^a	0.19±0.01^a	0.14±0.0^c	0.17±0.01^abc	0.15±0.00^bc	0.17±0.00^ab
24:0	0.02±0.00^a	0.02±0.01^a	0.02±0.0^a	0.19±0.08^a	0.01±0.00^a	0.01±0.00^a
24:1n-9	0.09±0.01^abc	0.11±0.0^ab	0.09±0.01^bc	0.07±0.00^c	0.12±0.00^a	0.07±0.0^c
22:6n-3	0.14±0.00^ab	0.11±0.0^c	0.12±0.00^bc	0.07±0.00^d	0.16±0.00^a	0.07±0.01^c
SFA	30.77±0.25^bc	32.97±0.47^a	29.11±0.55^cd	29.08±0.25^cd	31.34±0.0^ab	28.66±0.06^d
MUFA	30.33±0.11^b	30.19±0.5^b	31.73±0.60^ab	38.84±0.0^a	27.22±0.14^c	33.30±0.10^a
LC-PUFA	38.91±0.37^ab	36.85±0.97^b	39.17±1.15^ab	38.09±0.24^ab	41.45±0.14^a	38.04±0.16^ab
ΣFAn-6	35.96±0.55^ab	33.54±0.87^b	36.29±1.15^ab	35.22±0.21^ab	38.12±0.18^a	35.19±0.15^ab
ΣFAn-3	2.95±0.19^a	3.31±0.10^a	2.88±0.00^a	2.87±0.03^a	3.33±0.04^a	2.85±0.02^a
LC-PUFA/SFA	1.27±0.03^ab	1.12±0.04^b	1.35±0.06^a	1.31±0.02^ab	1.33±0.01^a	1.33±0.01^a
n-6/n-3	12.28±0.96^ab	10.14±0.05^b	12.60±0.40^a	12.29±0.06^ab	11.45±0.19^ab	12.33±0.0^ab

Fish Farms	Indices and Ratio
Fish Farms	AI	TI	H/H
I	0.49±0.014^b	0.63±0.020^b	2.18±0.072^a
II	0.54±0.006^ab	0.56±0.010^bc	1.92±0.039^a
III	0.56±0.002^ab	0.74±0.004^a	1.92±0,028^a
IV	0.58±0.013^a	0.61±0.016^bc	1.870±0.053^a
V	0.53±0.015^ab	0.55±0.015^c	2.085±0,075^a
VI	0.54±0.013^ab	0.61±0.001^bc	1.945±0.186^a

Brasil

Brasil

Total lipid nutritional quality of the adipose tissue from the orbital cavity in Nile tilapia from continental aquaculture

Qualidade nutricional dos lipídios totais no tecido adiposo da cavidade ocular da tilápia do Nilo da aquicultura continental

ABSTRACT.

RESUMO.

Introduction

Material and methods

Raw material

Sampling of the feed used by fish farmers

Extraction of Total Lipids

Fatty Acid Methyl Esters

Fatty acid analysis

Nutritional Quality Indices of Lipids (NQI)

Statistical analysis

Results and discussion

Fatty acid composition in the adipose tissue from the orbital cavity

Fatty acid composition of feed

Lipid Nutritional Quality

Conclusion

Acknowledgements

References

Publication Dates

History