[Abramović H., Butinar B., Nikolić V. (2007). Changes occurring in phenolic content, tocopherol composition and oxidative stability of Camelina sativa oil during storage. Food. Chem., 104: 903-909.]Search in Google Scholar
[Ajuyah A.O., Lee K.H., Hardin R.T., Sim J.S. (1991). Influence of dietary full-fat seeds and oils on total lipid, cholesterol and fatty acid composition of broiler meats. Can. J. Anim. Sci., 71: 1011-1019.]Search in Google Scholar
[AOAC (1995), Official Methods of Analysis of the Association of Official Analytical Chemists, 16th edition (ed. K. Helrich), Arlington, Virginia, USA.]Search in Google Scholar
[Ayerza R., Coates W., Lauria M. (2002). Chia seed (Salvia hispanica L.) as an ω-3 fatty acid source for broilers: Influence on fatty acid composition, cholesterol and fat content of white and dark meats, growth performance and sensory characteristics. Poultry Sci., 81: 826-837.]Search in Google Scholar
[Azcona O.J., Schang M.J., Gracia P.T., Gallinger C., Ayerza R. Jr., Coates W. (2008). Omega-3 enriched broiler meat: The influence of dietary α-linolenic-ω-3 fatty acid sources on growth, performance and meat fatty acid composition. Can J. Anim. Sci., 88: 257-269.]Search in Google Scholar
[Aziza A.E., Quezada N., Cherian G. (2010 a). Feeding Camelina sativa meal to meat type chickens: Effect on production performance and tissue fatty acid composition. Poultry Sci., 19: 157-168.10.3382/japr.2009-00100]Search in Google Scholar
[Aziza A.E., Quezada N., Cherian G. (2010 b). Antioxidative effect of dietary Camelina meal in fresh, stored, or cooked broiler chicken meat. Poultry Sci., 89: 2711-2718.10.3382/ps.2009-0054821076111]Search in Google Scholar
[Baillie R.A., Takada R., Nakamura M., Clark S.D. (1999). Coordinate induction of peroxisomal acyl-Co Aoxidase and UPC-3 by dietary fish oil: Amechanism for decreased body fat deposition. Prostaglandins Leukotr. Essent. Fatty Acids, 60: 351-356.]Search in Google Scholar
[Barowicz T., Brzóska F., Pietras M., Gąsior R. (1997). The hypocholesterolemic effect of whole flax seed used in the diet for pigs (in Polish). Med. Weter., 53: 164-167.]Search in Google Scholar
[Barowicz T., Pieszka M., Pietras M., Migdał W., Kędzior W. (2002). Conjugated linoleic acid utilization for improvement of chemical composition and dietetic value of pork meat. Ann. Anim. Sci., 2: 123-130.]Search in Google Scholar
[Bećkova R., Vaclavkova E. (2010). The effect of linseed diet on carcass value traits and fatty acid composition in muscle and fat tissue of fattening pigs. Czech J. Anim. Sci., 55 (8): 313-320.]Search in Google Scholar
[Burdge G.C. (2006). Metabolism of α-linolenic acid in humans. Prostaglandins Leukot. Essent. Fatty Acids, 75: 161-168.]Search in Google Scholar
[Chichłowska J., Florysiak M., Szkudelski T., Kilber A. (1997). The changes of lipid metabolism indicators in rats fed on diet supplemented with seed of flax and hemp (in Polish). Mat. XIX Konf. Nauk.: Rośliny oleiste. Poznań, 15-16.04.1997, p. 30.]Search in Google Scholar
[Crespo N., Esteve - Garcia E. (2002). Dietary linseed oil produces lower abdominal fat deposition but higher de novo fatty acid synthesis in broiler chickens. Poultry Sci., 81: 1555-1562.]Search in Google Scholar
[Crowley J.G., Fröhlich A. (1998). Factors affecting the composition and use of camelina. A Teagasc publication. Crops Research Centre, Oak Park, Carlow, Ireland.]Search in Google Scholar
[Flachovsky G., Schone F., Schaarmann G., Lubbe F., Bohme H. (1997). Influence of oilseeds in combination with vitamin Esupplementation in the diet on backfat quality of pigs. Anim.]Search in Google Scholar
[Feed Sci. Technol., 64: 91-100.]Search in Google Scholar
[Folch J., Lees M., Stanley G.H.S. (1957). Asimple method for the isolation and purification of total lipids from animal tissues. J. Biol. Chem., 226, p. 497.]Search in Google Scholar
[Grau A., Guardiola F., Grimpa S., Barroeta A.C., Codony R. (2001). Oxidative stability of dark chicken meat through frozen storage: Influence of dietary fat and alpha-tocopherol and ascorbic acid supplementation. Poultry Sci., 80: 1630-1642.]Search in Google Scholar
[Gray J.I., Gomaa A.E., Buckley D.J. (1996). Oxidative quality and shelf life of meats. Meat Sci., 43: 111-123.]Search in Google Scholar
[Hrastar R., Cheng L.Z., Xu X., Miller R.L., Kośir I.J. (2011). Camelina sativa oil deodorization: balance between free fatty acids and color reduction and isomerized byproducts formation. J. Am. Oil Chem. Soc., 88: 581-588.]Search in Google Scholar
[Huang F.R., Zhan Z.P., Luo J., Liu Z.X., Peng J. (2008). Duration of dietary linseed feeding affects the intramuscular fat, muscle mass and fatty acid composition in pig muscle. Livest. Sci., 118: 132-139.]Search in Google Scholar
[Jaśkiewicz T., Matyka S. (2003). Application of Camelina sativa, its seeds, extrudate and oil cake in diets for broiler chickens and the effect on rearing indices and carcass quality. Ann. Anim. Sci., Suppl. 2: 181-184.]Search in Google Scholar
[Karvonen H.M., Aro A., Tapola N.S., Salminen I., Uusitupa M.I., Sarkkinen E.S. (2002). Effect of alpha-linolenic acid-rich Camelina sativa oil on serum fatty acids composition and serum lipids in hypercholesterolemic subjects. Metabolism, 51 (10): 1253-1260.]Search in Google Scholar
[Kouba M., Mourot J. (2011). Areview of nutritional effects on fat composition of animal products with special emphasis on n-3 polyunsaturated fatty acids. Biochimie, 93 (1): 13-17.]Search in Google Scholar
[Leeson S., Atteh J.O. (1995). Utilization of fat and fatty acids by turkey. Poultry Sci., 74: 2003-2010.]Search in Google Scholar
[Leskanich C.O., Noble R.C. (1997). Manipulation of the n-3 polyunsaturated fatty acids composition of avian eggs and meat. World Poultry Sci., 53: 154-182.]Search in Google Scholar
[Lopez- Ferrer S., Baucells M.D., Barroeta A., Cgrashorn M.A. (1999). n-3 enrichment of chicken meat using fish oil: Alternative substitution with rapeseed and linseed oils. Poultry Sci., 78: 356-365.]Search in Google Scholar
[Lopez- Ferrer S., Baucells M.D., Barroeta A.C., Galobart J., Grashorn M.A. (2001). n-3 enrichment of chicken meat. 2. Use of precursors of long-chain polyunsaturated fatty acids: linseed oils. Poultry Sci., 80: 753-761.]Search in Google Scholar
[Morrison W.R., Smith L.M. (1964). Preparation of fatty acid methyl esters and dimethylacetals from lipids with boron fluoride-methanol. J. Lipid Res., 5: 600-608.]Search in Google Scholar
[Morrissey P.A., Brandon S., Buckley D.J., Sheehy P.J.A., Frigg M. (1997). Tissue content of alpha-tocopherol and oxidative stability of broilers receiving dietary alpha-tocopheryl acetate supplement for various periods pre-slaughter. Br. Poultry Sci., 38: 84-88.]Search in Google Scholar
[Palmquist D.L. (2009). Omega-3 fatty acids in metabolism, health, and nutrition and for modified animal product foods. Prof. Anim. Sci., 25: 207-249.]Search in Google Scholar
[Pietras M. (2001). The effect of the addition of probiotic in different periods of broiler chickens growth on performance (in Polish). Biul. Inf. IZ. Konf. Nauk. Balice 24-25.04.2001, p. 94.]Search in Google Scholar
[Pikul J. (1993). Technological assessment of raw materials and products of the poultry industry (in Polish). Wyd. AR Poznań, Poznań, pp. 104-118.]Search in Google Scholar
[Rokka T., Alen K., Valaja J., Ryhanen E.-L. (2002). The effect ofa Camelina sativa enriched diet on the composition and sensory quality of hen eggs. Food Res. Int., 35: 253-256.]Search in Google Scholar
[Salih M., Smith D.M., Price J.F., Dawson L.E. (1987). Modified extraction 2-thiobarbituric acid method for measuring lipid oxidation in poultry. Poultry Sci., 66: 1183-1188.]Search in Google Scholar
[Sanz M., Flores A., Lopez- Bote C.J. (2000 a). The metabolic use of energy from dietary fat in broilers is affected by fatty acid saturation. Br. Poultry Sci., 41: 61-68.10.1080/0007166008641110821524]Search in Google Scholar
[Sanz M., Lopez- Bote C.J., Menoyo D., Bautista J.M. (2000 b). Abdominal fat deposition and fatty acid synthesis are lower and β-oxidation is higher in broiler chickens fed diets containing unsaturated rather than saturated fat. J. Nutr., 130: 3034-3037.10.1093/jn/130.12.303411110864]Search in Google Scholar
[Schneiderová J., Zelenka D., Markvicova E. (2007). Poultry meat production asafunctional food withavoluntary n-6 and n-3 polyunsaturated fatty acids ratio. Czech J. Anim. Sci., 52: 203-213.]Search in Google Scholar
[Wood J.D., Enser M., Fisher A.V., Nute G.R., Sheard P.R., Richardson R.I., Hug-hes S.I., Whittington F.M. (2008). Fat deposition, fatty acid composition and meat quality: Areview. Meat Sci., 78: 343-358.]Search in Google Scholar
[Zubr J., Matthaus B. (2002). Effects of growth conditions on fatty acids and tocopherols in Camelina sativa oil. Ind. Crop Prod., 15: 155-162.]Search in Google Scholar
[Zuidhof M.J., Betti M., Korver D.R., Hernandez F.I.L., Schneider B.L., Carney V.L., Renema R.A. (2009). Omega-3 enriched broiler meat: 1. Optimization ofaproduction system. Poultry Sci., 88: 1108-1120. ]Search in Google Scholar
