El objetivo de este estudio fue determinar el nivel máximo de inclusión de aceite de canola (AC) en dietas para cerdos en finalización, para incrementar el contenido de ácido oleico y ácidos grasos insaturados y mejorar la relación Ω6: Ω3 en la carne, sin afectar el comportamiento productivo, características de la canal y fisicoquímicas de la carne. Los tratamientos fueron: la sustitución gradual de aceite de soya (6%) por AC en dietas para cerdos en etapa de finalización I y II (0, 2, 4 y 6% de AC). Las unidades experimentales fueron 48 cerdos machos castrados con peso vivo inicial de 50.00 ± 4.5 kg, evaluados durante cuatro semanas en cada etapa. Con los datos obtenidos se realizó un ANDEVA y se detectaron tendencias lineales o cuadráticas (P≤0.10). En finalización I la ganancia de peso disminuyó con la inclusión de 2% de AC, aunque la incorporación de 2 y 4% de AC no tuvo efecto. En finalización II, un nivel entre 2-4% de AC redujo el consumo de alimento y mejoró la conversión alimenticia (P≤0.05). La adición de AC no modificó las características de la canal y no afectó las características fisicoquímicas de la carne (P≥0.10). El AC en la dieta aumentó la concentración de ácidos grasos monoinsaturados (AGMI) y ácido oleico (P≤0.05); redujo el ácido linoleico (P≤0.03), ácidos grasos poliinsaturados (P≤0.07) y la relación Ω6:Ω3 (P≤0.01). En conclusión, la adición de AC (2-6%) en la dieta de cerdos en finalización incrementa gradualmente el contenido de ácido oleico y de AGMI, además, mejora la relación Ω6:Ω3 en la carne de cerdo, sin afectar las variables productivas y la calidad de la carne.

Jasinska K, Kurek A. The effect of oil plants supplementation in pig diet on quality and nutritive value of pork meat. Anim Sci Pap Rep 2017;35(2):137-146.

Clarke R, Frost C, Collins R, Appleby P, Peto R. Dietary lipids and blood cholesterol: Quantitative meta–analysis of metabolic ward studies. Br Med J 1997;314(7074):112-117.

Vehovsky K, Stupka R, Zadinova K, Sprysl M, Okrouhla M, Lebedova N, et al. Effect of dietary rapeseed and soybean oil on growth performance, carcass traits, and fatty acid composition of pigs. R Bras Zootec 2019;48:e20180131.

Saini RK, Keum YS. Omega-3 and omega-6 polyunsaturated fatty acids: Dietary sources, metabolism, and significance- A review. Life Sci 2018;203:255-267.

Simopoulos AP. Evolutionary aspects of diet, the omega-6/omega-3 ratio and genetic variation: nutritional implications for chronic diseases. Biomed Pharmacother 2006;60(9):502-507.

Sales-Campos H, Reis SP, Crema PB, Santana SJ, Ribeiro CC. An overview of the modulatory effects of oleic acid in health and disease. Mini Rev Med Chem 2013;13(2):201-210.

Karacor K, Cam M. Effects of oleic acid. Medical Sci Discovery 2015;2(1):125-132.

Castellanos L, Rodriguez M. El efecto de omega 3 en la salud humana y consideraciones en la ingesta. Rev Chil Nutr 2015;42(1):90-95.

Skiba G, Polawska E, Sobol M, Raj S, Weremko D. Omega-6 and omega-3 fatty acids metabolism pathways in de body of pigs fed diets with different sources of fatty acids. Arch Anim Nutr 2015;69(1):1-16.

Teye GA, Sheard PR, Whittington FM, Nute GR, Stewart A, Wood JD. Influence of dietary oils and protein level on pork quality. 1. Effects on muscle fatty acid composition, carcass, meat and eating quality. Meat Sci 2006;73(1):157-165.

Apple JK, Maxwell CV, Galloway DL, Hamilton CR, Yancey JWS. Interactive effects of dietary fat source and slaughter weight in growing-finishing swine: II. Fatty acid composition of subcutaneous fat. J Anim Sci 2009;87(4):1423-1440.

Apple JK, Maxwell CV, Galloway DL, Hamilton CR, Yancey JWS. Interactive effects of dietary fat source and slaughter weight in growing-finishing swine: III. Carcass and fatty acid compositions. J Anim Sci 2009;87(4):1441-1454.

Benz JM, Tokach MD, Dritz SS, Nelssen JL, DeRouchey JM, Sulabo RC, et al. Effects of choice white grease and soybean oil on growth performance, carcass characteristics, and carcass fat quality of growing-finishing pigs. J Anim Sci 2011;89(2):404-413.

Dugan ME, Vahmani P, Turner TD, Mapiye C, Juárez M, Prieto N, et al. Pork as a source of omega-3 (n-3) fatty acids. J Clin Med 2015;4(12):1999-2011.

Leikus R, Juskiene V, Juska R, Juodka R, Stankeviciene D, Nainiene R, et al. Effect of linseed oil sediment in the diet of pigs on the growth performance and fatty acid profile of meat. R Bras Zootec 2018;47:e20170104.

Kolacz R, Korniewicz A, Dobrzański Z, Bykowski P, Kolacz D, Korniewicz D. Effect of dietary fish and rapeseed oils on sensory and physicochemical characteristics of pigs M. Longissimus dorsi and fatty acid composition. J Anim Feed Sci 2004;13(143):143-152.

Corino C, Magni S, Pagliarini E, Rossi R, Pastorelli G, Chiesa LM. Effects of dietary fats on meat quality and sensory characteristics of heavy pig. Meat Sci 2002;60(1):1-8.

Pastorelli G, Magni S, Rossi R, Pagliarini E, Baldini P, Dirinck P, et al. Influence of dietary fat, on fatty acid composition and sensory properties of dry-cured Parma ham. Meat Sci 2003;65(1):571-580.

Bertol TM, De Campos RML, Ludke JV, Terra NN, De Figueiredo EAP, Coldebella A, et al. Effects of genotype and dietary oil supplementation on performance, carcass traits, pork quality and fatty acid composition of backfat and intramuscular fat. Meat Sci 2013;93(3):507-516.

García E. Modificaciones al sistema de clasificación de Köppen. 5a ed. México DF: Instituto de Geografía, Universidad Nacional Autónoma de México; 2004.

Microsof Excel. Microsoft Corporation. 1985-2001. Redmond WA, USA. 2007.

NRC. National Research Council. Nutrient requirements tables and feed ingredient composition. Nutrient requirements of swine. 11th ed. Washington, DC, USA: National Academy Press; 2012.

Burson D, Berg E. Procedures for estimating pork carcass composition. Pork quality facts. Des Moines, IA, USA: National Pork Producers Council; 2001.

SAGARPA. Secretaría de Agricultura, Ganadería, Desarrollo Rural, Pesca y Alimentación. Norma Oficial Mexicana NOM-033-SAG/ZOO-2014. Métodos para dar muerte a los animales domésticos y silvestres. México. 2014. En: https://www.dof.gob.mx/nota_detalle.php?codigo=5405210&fecha=26/08/2015 Consultado 26 Nov, 2019.

Mancini RA, Hunt M. Current research in meat color. Meat Sci 2005;71(1):100-121.

Braña VD, Ramírez RE, Rubio LMS, Sánchez EA, Torrescano UA, Arenas MML, et al. Manual de análisis de calidad en muestras de carne. 1er ed. Querétaro, México. Centro Nacional de Investigación Disciplinaria en Fisiología y Mejoramiento Animal; 2011.

Guerrero LI, Ponce AE, Pérez ML. Curso práctico de tecnología de carnes y pescado. México DF: Universidad Metropolitana, Unidad Iztapalapa; 2002.

Folch J, Lees M, Sloane SGH. A simple method for the isolation and purification of total lipids from animal tissues. J Biol Chem 1957;226:497-509.

SAS. SAS/STAT User’s Guide (9.4) Cary NC, USA: SAS Inst. Inc. 2010.

Olivares A, Daza A, Rey AI, Lopez-Bote CJ. Interactions between genotype, dietary fat saturation and vitamin A concentration on intramuscular fat content and fatty acid composition in pigs. Meat Sci 2009;82(1):6-12.

Rossi R, Corino C. Influence of long-term nutrition with different dietary fats on fatty acid composition of heavy pigs backfat. Ital J Anim Sci 2002;1(1):7-16.

De Sousa RV, Ribeiro O, Zangeronimo MG, De Sousa VC, Da Silva MSF, Pereira LJ. Total cholesterol and its fractions in the blood of finishing pigs fed diets with different levels of canola oil. Acta Sci Vet 2013;41(1):1-6.

Myer RO, Lamkey JW, Walker WR, Brendemuhl JH, Coms GE. Performance and carcass characteristics of swine when fed diets containing canola oil and added copper to alter the unsaturated:saturated ratio of pork fat. J Anim Sci 1992;70(5):1417-1423.

Guerrero LI. Meat spoilage detection. In Nollet L, Toldrá F editors. Handbook of processed meat and poultry analysis. Boca Raton, Florida USA: CRC Pres; 2009:445-460.

Pérez MI, Larrea V, Quiles A, Llunch MA. Microstructure of muscle foods. In: Nollet L, Toldrá F, editors. Handbook of processed meat and poultry analysis. Boca Raton, Florida USA: CRC Pres; 2009:335-352.

Lo Fiego DP, Macchioni P, Santero P, Pastorelli G, Corino CC. Effect of dietary conjugated linoleic acid (CLA) supplementation on CLA isomers content and fatty acid composition of dry-cured Parma ham. Meat Sci 2005;70(2):285-291.

Lisiak D, Grzeskowiak E, Borzuta K, Raj S, Janiszewski P, Skiba G. Effects of supplementary vegetable and animal fats on the slaughter values of fatteners, meat quality, and fatty acid profile in pigs. Czech J Anim Sci 2013;58(11):497-511.

Apple JK, Maxwell CV, Galloway DL, Hutchison S, Hamilton CR. Interactive effects of dietary fat source and slaughter weight in growing-finishing swine: I. Growth performance and Longissimus muscle fatty acid composition. J Anim Sci 2009;87(4): 1407-1422.

Juárez M, Dugan MER, Aldai N, Aalhus JL, Patience JF, Zijlstra RT, et al. Feeding co-extruded flaxseed to pigs: Effects of duration and feeding level on growth performance and backfat fatty acid composition of grower-finisher pigs. Meat Sci 2010;84(3):578-584.

Romans JR, Wulf DM, Johnson RC, Libal GW, Costello WJ. Effects of ground flaxseed in swine diets on pig performance and on physical and sensory characteristics and omega-3 fatty acid content of pork: II. Duration of 15% dietary flaxseed. J Anim Sci 1995;73(7):1987-1999.

Kouba M, Enser M, Whittington FM, Nute GR, Wood JD. Effect of a high-linolenic acid diet on lipogenic enzyme activities, fatty acid composition, and meat quality in the growing pig. J Anim Sci 2003;81(8):1967-1979.

Allee GL, Baker DH, Leveille GA. Influence of level of dietary fat on adipose tissue lipogenesis and enzymatic activity in the pig. J Anim Sci 1971;33(6):1248-1254.

Smith DR, Knabe DA, Smith SB. Depression of lipogenesis in swine adipose tissue by specific dietary fatty acids. J Anim Sci 1996;74(5):975-983.