[AOAC (1990). Official methods of analysis. 15 ed., Association of Official Analytical Chemists, Arlington, USA.]Search in Google Scholar
[Burbaitė L., Cs ányi S. (2009). Roe deer population and harvest changes in Europe. Est. J. Ecol., 58: 169-180.]Search in Google Scholar
[Cordain L., Watkins B.A., Florant G.L., Kelher M., Rogers L., Li Y. (2002). Fatty acid analysis of wild ruminant tissues: evolutionary implications for reducing diet-related chronic disease. Eur. J. Clin. Nutr., 56: 181-191.]Search in Google Scholar
[Cygan-Szczegielniak D., Janicki B. (2009). Influence of age and sex on the cholesterol content in roe deer’s meat. Med. Weter., 65: 179-180.]Search in Google Scholar
[Dannenberger D., Nuernberg G., Nuernberg K., Hagemann E. (2013). The effects of gender, age and region on macro- and micronutrient contents and fatty acid profiles in the muscles of roe deer and wild boar in Mecklenburg-Western Pomerania (in Germany). Meat Sci., 94: 39-46.]Search in Google Scholar
[Daszkiewicz T., Janiszewski P., Wajda S. (2009). Quality characteristics of meat from wild red deer (Cervus elaphus L.) hinds and stags. J. Muscle Foods, 20: 428-448. ]Search in Google Scholar
[Du C., Sato A., Watanabe S., Wu C-Z., Ikemoto A., Ando K., Kikugawa K., Fujii Y., Okuyama H. (2003). Cholesterol synthesis in mice is suppressed but lipofuscin formation is not affected by long-term feeding of n-3 fatty acid-enriched oils compared with lard and n-6 fatty acid-enriched oils. Biol. Pharm. Bull., 26: 766-770.]Search in Google Scholar
[Fern ández M., Ordó ñez J.A., Cambero I., Santos C., Pin C., Dela Hoz L. (2007). Fatty acid compositions of selected varieties of Spanish dry ham related to their nutritional implications. Food Chem., 101: 107-112.]Search in Google Scholar
[Folch J., Less M., Sloane - Stanley G.H. (1957). Asimple method for the isolation and purification of total lipids from animal tissues. J. Biol. Chem., 226: 497-509.]Search in Google Scholar
[Givens D.I., Kliem K.E., Gibbs R.A. (2006). The role of meat asasource of n-3 polyunsaturated fatty acids in the human diet. Meat Sci., 74: 209-218.]Search in Google Scholar
[Hathwar S.C., Rai A.K., Modi V.K., Narayan B. (2012). Characteristics and consumer acceptance of healthier meat and meat product formulations -areview. J. Food Sci. Technol., 49: 653-664.]Search in Google Scholar
[Hoffman L.C., Wiklund E. (2006). Game and venison - meat for the modern consumer. Meat Sci., 74: 197-208.]Search in Google Scholar
[Hutchison C.L., Mulley R.C., Wiklund E., Flesh J.S. (2010). Consumer evaluation of venison sensory quality: Effects of sex, body condition score and carcase suspension method. Meat Sci., 86: 311-316.]Search in Google Scholar
[Kang M.J., Shin M.S., Park J.N., Lee S.S. (2005). The effects of polyunsaturated: saturated fatty acids ratios and peroxidisability index values of dietary fats on serum lipid profiles and hepatic enzyme activities in rats. Brit. J. Nutr., 94: 526-532.]Search in Google Scholar
[Kelly F.D., Sinclair A.J., Mann N.J., Turner A.H., Abedin L., Li D. (2001). Astearic acid-rich diet improves thrombogenic and atherogenic risk factor profiles in healthy males. Eur. J. Clin. Nutr., 55: 88-96.]Search in Google Scholar
[Kolar K. (1990). Colorimetric determination of hydroxyproline as measure of collagen content in meat and meat products: NMKLcollaborative study. J. Assoc. Anal. Chem., 73: 54-57.]Search in Google Scholar
[La Neve F., Vivera T., Mucci N., Bottero M.T. (2008). Authentication of meat from game and domestic species by SNa Psot minisequencing analysis. Meat Sci., 80: 216-224.]Search in Google Scholar
[Lands B., Lamoreaux E. (2012). Using 3-6 differences in essential fatty acids rather than 3/6 ratios gives useful food balance scores. Nutr. Metab., 9: 46.]Search in Google Scholar
[Lorenzo J.M., Pateiro M. (2013). Influence of type of muscles on nutritional value of foal meat. Meat. Sci., 93: 630-638.]Search in Google Scholar
[Nuernberg K., Nuernberg G., Dannenberger D. (2009). Nutrient and lipid composition of muscle in wild animals. Fleischwirtschaft, 89: 99-102.]Search in Google Scholar
[Pavan E., Ducket S.K. (2013). Fatty acid composition and interrelationships among eight retail cuts of grass-feed beef. Meat Sci., 93: 371-377.]Search in Google Scholar
[Pietras M.P., Orczewska- Dudek S. (2013). The effect of dietary Camelina sativa oil on quality of broiler chicken meat. Ann. Anim. Sci., 13: 869-882.]Search in Google Scholar
[Ramanzin M., Amici A., Casoli C., Esposito L., Lupi P., Marsico G., Mattiello S., Olivieri O., Ponzetta M.P., Russo C., Marinucci M.T. (2010). Meat from wild ungulates: ensuring quality and hygiene of an increasing resource. Ital. J. Anim. Sci., 9: e61: 318-331.]Search in Google Scholar
[Razmaitė V., Švirmickas G.J. (2012). Comparison of fatty acid composition in different pig tissues. Vet. Med. Zoot., 58: 77-82.]Search in Google Scholar
[Razmaitė V., Švirmickas G.J., Šiukš čius A. (2012). Effect of weight, sex and hunting period on fatty acid composition of intramuscular and subcutaneous fat from wild boar. Ital. J. Anim. Sci., 11: 174-179.]Search in Google Scholar
[R ødbotten M., Kubber ød E., Lea P., Ueland Ø. (2004). Asensory map of the meat universe. Sensory profile of meat from 15 species. Meat Sci., 68: 137-144.]Search in Google Scholar
[Sales J. (1998). Fatty acid composition and cholesterol content of different ostrich muscles. Meat Sci., 49: 489-492.]Search in Google Scholar
[Simopoulos A.P., Bourne P.G., Faergeman O. (2013). Bellagio report on healthy agriculture, healthy nutrition, healthy people. Nutrients, 5: 411-423.]Search in Google Scholar
[Tholstrup T. (2005). Influence of stearic acid on hemostatic risk factors in humans. Lipids, 40: 1229-1235. Ulbricht T.L.V., Southgate D.A.T. (1991). Coronary disease seven dietary factors. Lancet., 338: 985-992.10.1007/s11745-005-1490-116477807]Search in Google Scholar
[Vavrišinova K., PrivaraŠ., Čubon J., Ha š čik P., Foltys V. (2013). Veal quality and fatty acid content in Holstein calves. Vet. Med. Zoot., 61: 89-95.]Search in Google Scholar
[Weiner J. (1973). Dressing percentage, gross body composition and caloric value of the roe deer. Acta Theriol., 18: 209-222.]Search in Google Scholar
[Wood J.D., Richardson R.I., Nute G.R., Fisher A.V., Campo M.M., Kasapidou E., Sheard P.R., Enser M. (2004). Effects of fatty acids on meat quality:areview. Meat Sci., 66: 21-32.]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
[Yanovych D., Czech A., Zasadna Z. (2013). The effect of dietary fish oil on the lipid and fatty acid composition and oxidative stability of goose leg muscles. Ann. Anim. Sci., 13: 155-165.]Search in Google Scholar
[Zomborszky Z., Szentmih ályi G., Sarudi I., Horn P., Szab ó C.S. (1996). Nutrient composition of muscles in deer and boar. J. Food Sci., 61: 625-627.]Search in Google Scholar
[Żochowska - Kujawska J., Lachowicz K., Sobczak M., Gajowiecki L. (2007). Effects of carcass weight and muscle on texture, structure, rheological properties and myofibre characteristics of roe deer. Am. J. Anim. Vet., 2: 114-120. ]Search in Google Scholar