[Abd El Tawab A.M., Kholif A.E., Khattab M.S.A., Shaaban M.M., Hadhoud F.I., Mostafa M.M.M., Olafadehan O.A. (2020). Feed utilization and lactational performance of Barki sheep fed diets containing thyme or celery. Small Rumin. Res., 192: 106249.]Search in Google Scholar
[Addis M., Cabiddu A., Pinna G., Decandia M., Piredda G., Pirisi A., Molle G. (2005). Milk and cheese fatty acid composition in sheep fed Mediterranean forages with reference to conjugated linoleic acid cis-9,trans-11. J. Dairy Sci., 88: 3443–3454.]Search in Google Scholar
[Altomonte I., Salari F., Licitra R., Martini M. (2018). Use of microalgae in ruminant nutrition and implications on milk quality – A review. Livest. Sci., 214: 25–35.]Search in Google Scholar
[Antonacci E.L., Bussetti M., Rodriguez A.M., Cano A.V., Gagliostro G.A. (2018). Effect of diet supplementation with combinations of soybean and linseed oils on milk production and fatty acid profile in lactating dairy ewes. Agric. Sci., 09: 200–220.]Search in Google Scholar
[Azzaz H.H., Kholif A.E., Abd El Tawab A.M., Khattab M.S.A., Murad H.A., Olafadehan O.A. (2020). A newly developed tannase enzyme from Aspergillus terreus versus commercial tannase in the diet of lactating Damascus goats fed diet containing pomegranate peel. Livest. Sci., 241: 104228.]Search in Google Scholar
[Azzaz H.H., Kholif A.E., Murad H.A., El-Bordeny N.E., Ebeid H.M., Hassaan N.A., Anele U.Y. (2021). A new pectinase produced from Aspergillus terreus compared with a commercial pectinase enhanced feed digestion, milk production and milk fatty acid profile of Damascus goats fed pectin-rich diet. Ann. Anim. Sci., 21: 639–656.]Search in Google Scholar
[Bernard L., Shingfield K.J., Rouel J., Ferlay A., Chilliard Y. (2009). Effect of plant oils in the diet on performance and milk fatty acid composition in goats fed diets based on grass hay or maize silage. Br. J. Nutr., 101: 213–224.]Search in Google Scholar
[Bernard L., Mouriot J., Rouel J., Glasser F., Capitan P., Pujos-Guillot E., Chardigny J.M., Chilliard Y. (2010). Effects of fish oil and starch added to a diet containing sunflower-seed oil on dairy goat performance, milk fatty acid composition and in vivo δ9-desaturation of [13C]vaccenic acid. Br. J. Nutr., 104: 346–354.]Search in Google Scholar
[Bernard L., Toral P., Rouel J., Chilliard Y. (2016). Effects of extruded linseed and level and type of starchy concentrate in a diet containing fish oil on dairy goat performance and milk fatty acid composition. Anim. Feed Sci. Technol., 222: 31–42.]Search in Google Scholar
[Bichi E., Hervás G., Toral P.G., Loor J.J., Frutos P. (2013). Milk fat depression induced by dietary marine algae in dairy ewes: Persistency of milk fatty acid composition and animal performance responses. J. Dairy Sci., 96: 524–532.]Search in Google Scholar
[Bodas R., Manso T., Mantecón A.R., Juárez M., De La Fuente M.Á., Gómez-Cortés P. (2010). Comparison of the fatty acid profiles in cheeses from ewes fed diets supplemented with different plant oils. J. Agric. Food Chem., 58: 10493–10502.]Search in Google Scholar
[Bu D.P., Wang J.Q., Dhiman T.R., Liu S.J. (2007). Effectiveness of oils rich in linoleic and linolenic acids to enhance conjugated linoleic acid in milk from dairy cows. J. Dairy Sci., 90: 998–1007.]Search in Google Scholar
[Cabiddu A., Addis M., Pinna G., Decandia M., Sitzia M., Piredda G., Pirisi A., Molle G. (2006). Effect of corn and beet pulp based concentrates on sheep milk and cheese fatty acid composition when fed Mediterranean fresh forages with particular reference to conjugated linoleic acid cis-9, trans-11. Anim. Feed Sci. Technol., 131: 292–311.]Search in Google Scholar
[Cabiddu A., Molle G., Decandia M., Spada S., Fiori M., Piredda G., Addis M. (2009). Responses to condensed tannins of flowering sulla (Hedysarum coronarium L.) grazed by dairy sheep. Part 2: Effects on milk fatty acid profile. Livest. Sci., 123: 230–240.]Search in Google Scholar
[Cannas A. (2009). Feeding of lactating ewes. In: Dairy sheep nutrition. CABI, Wallingford, pp. 79–108.]Search in Google Scholar
[Castro T., Martinez D., Isabel B., Cabezas A., Jimeno V. (2019). Vegetable oils rich in polyunsaturated fatty acids supplementation of dairy cows’ diets: Effects on productive and reproductive performance. Animals, 9: 205.]Search in Google Scholar
[Chilliard Y., Glasser F., Ferlay A., Bernard L., Rouel J., Doreau M. (2007). Diet, rumen biohydrogenation and nutritional quality of cow and goat milk fat. Eur. J. Lipid Sci. Technol., 109: 828–855.]Search in Google Scholar
[Chilliard Y., Martin C., Rouel J., Doreau M. (2009). Milk fatty acids in dairy cows fed whole crude linseed, extruded linseed, or linseed oil, and their relationship with methane output. J. Dairy Sci., 92: 5199–5211.]Search in Google Scholar
[de la Torre-Santos S., Royo L.J., Martínez-Fernández A., Chocarro C., Vicente F. (2020). The mode of grass supply to dairy cows impacts on fatty acid and antioxidant profile of milk. Foods, 9: 1256.]Search in Google Scholar
[De Renobales M., Amores G., Arranz J., Virto M., Barrón L.J.R., Bustamante M.A., Ruiz De Gordoa J.C., Nájera A.I., Valdivielso I., Abilleira E., Beltrán De Heredia I., Pérez-Elortondo F.J., Ruiz R., Albisu M., Mandaluniz N. (2012). Part-time grazing improves sheep milk production and its nutritional characteristics. Food Chem., 130: 90–96.]Search in Google Scholar
[Dewhurst R.J., Moloney A.P. (2013). Modification of animal diets for the enrichment of dairy and meat products with omega-3 fatty acids, in: Food Enrichment with Omega-3 Fatty Acids. Elsevier, pp. 257–287.]Search in Google Scholar
[El-Zaiat H.M., Kholif A.E., Mohamed D.A., Matloup O.H., Anele U.Y., Sallam S.M.A. (2019). Enhancing lactational performance of Holstein dairy cows under commercial production: malic acid as an option. J. Sci. Food Agric., 99: 885–892.]Search in Google Scholar
[El-Zaiat H.M., Kholif A.E., Moharam M.S., Attia M.F., Abdalla A.L., Sallam S.M.A. (2020). The ability of tanniniferous legumes to reduce methane production and enhance feed utilization in Barki rams: in vitro and in vivo evaluation. Small Rumin. Res., 193: 106259.]Search in Google Scholar
[Erdman J., Oria M., Pillsbury L. (2011). Eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA). In: Nutrition and traumatic brain injury: improving acute and subacute health outcomes in military personnel, J. Erdman, M. Oria, L. Pillsbury (eds). The National Academies Press, Washington, DC, pp. 188–204.]Search in Google Scholar
[Fahim N.H., Kholif A.E., Azzaz H.H. (2022). Fennel and ginger improved nutrient digestibility and milk yield and quality in early lactating Egyptian buffaloes. Ann. Anim. Sci., 22: 255–270.]Search in Google Scholar
[Gebreyowhans S., Lu J., Zhang S., Pang X., Lv J. (2019). Dietary enrichment of milk and dairy products with n-3 fatty acids: A review. Int. Dairy J., 97: 158–166.]Search in Google Scholar
[Glover K.E., Budge S., Rose M., Rupasinghe H.P.V., MacLaren L., Green-Johnson J., Fredeen A.H. (2012). Effect of feeding fresh forage and marine algae on the fatty acid composition and oxidation of milk and butter. J. Dairy Sci., 95: 2797–2809.]Search in Google Scholar
[Gomaa A.S., Kholif A.E., Kholif A.M., Salama R., El-Alamy H.A., Olafadehan O.A. (2018). Sunflower oil and Nannochloropsis oculata microalgae as sources of unsaturated fatty acids for mitigation of methane production and enhancing diets’ nutritive value. J. Agric. Food Chem., 66: 1751–1759.]Search in Google Scholar
[Gómez-Cortés P., Cívico A., De La Fuente M.A., Núñez Sánchez N., Peña Blanco F., Martinez Marin A.L. (2018). Effects of dietary concentrate composition and linseed oil supplementation on the milk fatty acid profile of goats. Animal, 12: 2310–2317.]Search in Google Scholar
[Gutiérrez S., Svahn S.L., Johansson M.E. (2019). Effects of omega-3 fatty acids on immune cells. Int. J. Mol. Sci., 20: 5028.]Search in Google Scholar
[Heidarian Miri V., Tyagi A.K., Ebrahimi S.H., Mohini M. (2013). Effect of cumin (Cuminum cyminum) seed extract on milk fatty acid profile and methane emission in lactating goat. Small Rumin. Res., 113: 66–72.]Search in Google Scholar
[Hristov A.N., Lee C., Cassidy T., Heyler K., Tekippe J.A., Varga G.A., Corl B., Brandt R.C. (2013). Effect of Origanum vulgare L. leaves on rumen fermentation, production, and milk fatty acid composition in lactating dairy cows. J. Dairy Sci., 96: 1189–1202.]Search in Google Scholar
[Hurtaud C., Faucon F., Couvreur S., Peyraud J.L. (2010). Linear relationship between increasing amounts of extruded linseed in dairy cow diet and milk fatty acid composition and butter properties. J. Dairy Sci., 93: 1429–1443.]Search in Google Scholar
[Jones E.L., Shingfield K.J., Konen C., Jones A.K., Lupoli B., Grandison A.S., Beever D.E., Williams C.M., Calder P.C., Yaqoob P. (2005). Chemical, physical, and sensory properties of dairy products enriched with conjugated linoleic acid. J. Dairy Sci., 88: 2923–2937.]Search in Google Scholar
[Kalač P., Samková E. (2010). The effects of feeding various forages on fatty acid composition of bovine milk fat: A review. Czech J. Anim. Sci., 55: 521–537.]Search in Google Scholar
[Khattab M.S.A., El-Zaiat H.M., El Tawab A.M.A., Matloup O.H., Morsy A.S., Abdou M.M., Ebeid H.M., Attia M.F.A., Sallam S.M.A. (2017). Impact of lemongrass and galangal as feed additives on performance of lactating Barki goats. Int. J. Dairy Sci., 12: 184–189.]Search in Google Scholar
[Kholif A.E., Gouda G.A., Morsy T.A., Salem A.Z.M., Lopez S., Kholif A.M. (2015). Moringa oleifera leaf meal as a protein source in lactating goat’s diets: Feed intake, digestibility, ruminal fermentation, milk yield and composition, and its fatty acids profile. Small Rumin. Res., 129: 129–137.]Search in Google Scholar
[Kholif A.E., Morsy T.A., Abd El Tawab A.M., Anele U.Y., Galyean M.L. (2016 a). Effect of supplementing diets of Anglo-Nubian goats with soybean and flaxseed oils on lactational performance. J. Agric. Food Chem., 64: 6163–6170.10.1021/acs.jafc.6b0262527415418]Search in Google Scholar
[Kholif A.E., Morsy T.A., Gouda G.A., Anele U.Y., Galyean M.L. (2016 b). Effect of feeding diets with processed Moringa oleifera meal as protein source in lactating Anglo-Nubian goats. Anim. Feed Sci. Technol., 217: 45–55.10.1016/j.anifeedsci.2016.04.012]Search in Google Scholar
[Kholif A.E., Matloup O.H., Morsy T.A., Abdo M.M., Abu Elella A.A., Anele U.Y., Swanson K.C. (2017 a). Rosemary and lemongrass herbs as phytogenic feed additives to improve efficient feed utilization, manipulate rumen fermentation and elevate milk production of Damascus goats. Livest. Sci., 204: 39–46.10.1016/j.livsci.2017.08.001]Search in Google Scholar
[Kholif A.E., Morsy T.A., Matloup O.H., Anele U.Y., Mohamed A.G., El-Sayed A.B. (2017 b). Dietary Chlorella vulgaris microalgae improves feed utilization, milk production and concentrations of conjugated linoleic acids in the milk of Damascus goats. J. Agric. Sci., 155: 508–518.10.1017/S0021859616000824]Search in Google Scholar
[Kholif A.E., Gouda G.A., Olafadehan O.A., Abdo M.M. (2018 a). Effects of replacement of Moringa oleifera for berseem clover in the diets of Nubian goats on feed utilisation, and milk yield, composition and fatty acid profile. Animal, 12: 964–972.10.1017/S175173111700233628988560]Search in Google Scholar
[Kholif A.E., Kassab A.Y., Azzaz H.H., Matloup O.H., Hamdon H.A., Olafadehan O.A., Morsy T.A. (2018 b). Essential oils blend with a newly developed enzyme cocktail works synergistically to enhance feed utilization and milk production of Farafra ewes in the subtropics. Small Rumin. Res., 161: 43–50.10.1016/j.smallrumres.2018.02.011]Search in Google Scholar
[Kholif A.E., Morsy T.A., Abdo M.M. (2018 c). Crushed flaxseed versus flaxseed oil in the diets of Nubian goats: Effect on feed intake, digestion, ruminal fermentation, blood chemistry, milk production, milk composition and milk fatty acid profile. Anim. Feed Sci. Technol., 244: 66–75.10.1016/j.anifeedsci.2018.08.003]Search in Google Scholar
[Kholif A.E., Gouda G.A., Galyean M.L., Anele U.Y., Morsy T.A. (2019). Extract of Moringa oleifera leaves increases milk production and enhances milk fatty acid profile of Nubian goats. Agrofor. Syst., 93: 1877–1886.]Search in Google Scholar
[Kholif A.E., Gouda G.A., Hamdon H.A. (2020 a). Performance and milk composition of Nubian goats as affected by increasing level of Nannochloropsis oculata microalgae. Animals, 10: 1–14.10.3390/ani10122453776743433371450]Search in Google Scholar
[Kholif A.E., Hamdon H.A., Kassab A.Y., Farahat E.S.A., Azzaz H.H., Matloup O.H., Mohamed A.G., Anele U.Y. (2020 b). Chlorella vulgaris microalgae and/or copper supplementation enhanced feed intake, nutrient digestibility, ruminal fermentation, blood metabolites and lactational performance of Boer goat. J. Anim. Physiol. Anim. Nutr. (Berl.), 104: 1595–1605.10.1111/jpn.1337832388911]Search in Google Scholar
[Kholif A.E., Olafadehan O.A. (2021). Essential oils and phytogenic feed additives in ruminant diet: chemistry, ruminal microbiota and fermentation, feed utilization and productive performance. Phytochem. Rev., 20: 1087–1108.]Search in Google Scholar
[Kholif A.E., Hassan A.A., El Ashry G.M., Bakr M.H., El-Zaiat H.M., Olafadehan O.A., Matloup O.H., Sallam S.M.A. (2021 a). Phytogenic feed additives mixture enhances the lactational performance, feed utilization and ruminal fermentation of Friesian cows. Anim. Biotechnol., 32: 708–718.10.1080/10495398.2020.174632232248772]Search in Google Scholar
[Kholif A.E., Hassan A.A., Matloup O.H., El Ashry G.M. (2021 b). Top-dressing of chelated phytogenic feed additives in the diet of lactating Friesian cows to enhance feed utilization and lactational performance. Ann. Anim. Sci., 21: 657–667.10.2478/aoas-2020-0086]Search in Google Scholar
[Kholif A.E., Kassab A.Y., Hamdon H.A. (2021 c). Chlorella vulgaris microalgae and copper mixture supplementation enhanced the nutrient digestibility and milk attributes in lactating boer goats. Ann. Anim. Sci., 21: 939–957.10.2478/aoas-2020-0089]Search in Google Scholar
[Kholif A.E., Matloup O.H., Hadhoud F.I., Kassab A.Y., Adegbeye M.J., Hamdon H.A. (2021 d). Lemongrass supplementation to Farafra ewes improved feed utilization, lactational performance and milk nutritive value in the subtropics. Anim. Biotechnol., https://doi.org/10.1080/10495398.2020.187048510.1080/10495398.2020.187048533529081]Search in Google Scholar
[Kliem K.E., Morgan R., Humphries D.J., Shingfield K.J., Givens D.I. (2008). Effect of replacing grass silage with maize silage in the diet on bovine milk fatty acid composition. Animal, 2: 850–1858.]Search in Google Scholar
[Kliem K.E., Humphries D.J., Kirton P., Givens D.I., Reynolds C.K. (2019). Differential effects of oilseed supplements on methane production and milk fatty acid concentrations in dairy cows. Animal, 13: 309–317.]Search in Google Scholar
[Kupczyński R., Szołtysik M., Janeczek W., Chrzanowska J., Kinal S., Króliczewska B. (2011). Effect of dietary fish oil on milk yield, fatty acids content and serum metabolic profile in dairy cows. J. Anim. Physiol. Anim. Nutr. (Berl.), 95: 512–522.]Search in Google Scholar
[Lum K.K., Kim J., Lei X.G. (2013). Dual potential of microalgae as a sustainable biofuel feedstock and animal feed. J. Anim. Sci. Biotechnol., 4: 1–7.]Search in Google Scholar
[Martínez Marín A.L., Gómez-Cortés P., Gómez Castro A.G., Juárez M., Pérez Alba L.M., Pérez Hernández M., de la Fuente M.A. (2011). Animal performance and milk fatty acid profile of dairy goats fed diets with different unsaturated plant oils. J. Dairy Sci., 94: 5359–5368.]Search in Google Scholar
[Moate P.J., Williams S.R.O., Hannah M.C., Eckard R.J., Auldist M.J., Ribaux B.E., Jacobs J.L., Wales W.J. (2013). Effects of feeding algal meal high in docosahexaenoic acid on feed intake, milk production, and methane emissions in dairy cows. J. Dairy Sci., 96: 3177–3188.]Search in Google Scholar
[Mohammed R., Stanton C.S., Kennelly J.J., Kramer J.K.G., Mee J.F., Glimm D.R., O’Donovan M., Murphy J.J. (2009). Grazing cows are more efficient than zero-grazed and grass silage-fed cows in milk rumenic acid production. J. Dairy Sci., 92: 3874–3893.]Search in Google Scholar
[Moran C.A., Morlacchini M., Keegan J.D., Fusconi G. (2018). The effect of dietary supplementation with Aurantiochytrium limacinum on lactating dairy cows in terms of animal health, productivity and milk composition. J. Anim. Physiol. Anim. Nutr. (Berl.), 102: 576–590.]Search in Google Scholar
[Morsy T.A., Kholif S.M., Kholif A.E., Matloup O.H., Salem A.Z.M., Elella A.A. (2015). Influence of sunflower whole seeds or oil on ruminal fermentation, milk production, composition, and fatty acid profile in lactating goats. Asian-Australasian J. Anim. Sci., 28: 1116–1122.]Search in Google Scholar
[Morsy T.A., Kholif A.E., Kholif S.M., Kholif A.M., Sun X., Salem A.Z.M. (2016). Effects of two enzyme feed additives on digestion and milk production in lactating Egyptian buffaloes. Ann. Anim. Sci., 16: 209–222.]Search in Google Scholar
[Morsy T.A., Kholif A.E., Matloup O.H., Elella A.A., Anele U.Y., Caton J.S. (2018). Mustard and cumin seeds improve feed utilisation, milk production and milk fatty acids of Damascus goats. J. Dairy Res., 85: 142–151.]Search in Google Scholar
[Mozzon M., Frega N.G., Fronte B., Tocchini M. (2002). Effect of dietary fish oil supplements on levels of n-3 polyunsaturated fatty acids, trans acids and conjugated linoleic acid in ewe milk. Food Technol. Biotechnol., 40: 213–219.]Search in Google Scholar
[Nelson K.A.S., Martini S. (2009). Increasing omega fatty acid content in cow’s milk through diet manipulation: Effect on milk flavor. J. Dairy Sci., 92: 1378–1386.]Search in Google Scholar
[Novotná K., Fantová M., Nohejlová L., Borková M., Stádník L., Ducháček J. (2017). Effect of Chlorella vulgaris and Japonochytrium sp. microalgae supplementation on composition and fatty acid profile of goat milk. Acta Univ. Agric. Silvic. Mendelianae Brun., 65: 1585–1593.]Search in Google Scholar
[Nudda A., Battacone G., Neto O.B., Cannas A., Francesconi A.H.D., Atzori A.S., Pulina G. (2014). Feeding strategies to design the fatty acid profile of sheep milk and cheese. Rev. Bras. Zootec., 43: 445–456.]Search in Google Scholar
[Pajor F., Egerszegi I., Steiber O., Bodnár Á., Póti P. (2019). Effect of marine algae supplementation on the fatty acid profile of milk of dairy goats kept indoor and on pasture. J. Anim. Feed Sci., 28: 169–176.]Search in Google Scholar
[Pajor F., Egerszegi I., Szűcs Á., Póti P., Bodnár Á. (2021). Effect of marine algae supplementation on somatic cell count, prevalence of udder pathogens, and fatty acid profile of dairy goats’ milk. Animals, 11: 1097.]Search in Google Scholar
[Pi Y., Gao S.T., Ma L., Zhu Y.X., Wang J.Q., Zhang J.M., Xu J.C., Bu D.P. (2016). Effectiveness of rubber seed oil and flaxseed oil to enhance the α-linolenic acid content in milk from dairy cows. J. Dairy Sci., 99: 5719–5730.]Search in Google Scholar
[Pintus S., Murru E., Carta G., Cordeddu L., Batetta B., Accossu S., Pistis D., Uda S., Ghiani M.E., Mele M., Secchiari P., Almerighi G., Pintus P., Banni S. (2013). Sheep cheese naturally enriched in α-linolenic, conjugated linoleic and vaccenic acids improves the lipid profile and reduces anandamide in the plasma of hypercholesterolaemic subjects. Brit. J. Nutr., 109: 1453–1462.]Search in Google Scholar
[Pulina G., Nudda A., Battacone G., Cannas A. (2006). Effects of nutrition on the contents of fat, protein, somatic cells, aromatic compounds, and undesirable substances in sheep milk. Anim. Feed Sci. Technol., 131: 255–291.]Search in Google Scholar
[Rego O.A., Cabrita A.R.J., Rosa H.J.D., Alves S.P., Duarte V., Fonseca A.J.M., Vouzela C.F.M., Pires F.R., Bessa R.J.B. (2016). Changes in milk production and milk fatty acid composition of cows switched from pasture to a total mixed ration diet and back to pasture. Ital. J. Anim. Sci., 15: 76–86.]Search in Google Scholar
[Rojo R., Kholif A.E., Salem A.Z.M., Elghangour M.M.Y., Odongo N.E., Montes de Oca R., Rivero N., Alonso M.U. (2015). Influence of cellulase addition to dairy goat diets on digestion and fermentation, milk production and fatty acid content. J. Agric. Sci., 153: 1514–1523.]Search in Google Scholar
[Sallam S.M.A., Attia M.F.A., Nour El-Din A.N.M., El-Zarkouny S.Z., Saber A.M., El-Zaiat H.M., Zeitoun M.M. (2019). Involvement of Quebracho tannins in diet alters productive and reproductive efficiency of postpartum buffalo cows. Anim. Nutr., 5: 80–86.]Search in Google Scholar
[Sallam S.M.A., Kholif A.E., Kadoom M.H.A., Nour El-Din A.N.M., Attia M.F.A., Matloup O.H., Olafadehan O.A. (2021). Effect of different levels of protected palmitic acid-enriched fat supplement on lactational performance of Holstein cows and feed utilization of Barki sheep. Agric. Conspec. Sci., 86: 153–163.]Search in Google Scholar
[Salles M.S.V., D’abreu L.F., Júnior L.C.R., César M.C., Guimarães J.G.L., Segura J.G., Rodrigues C., Zanetti M.A., Pfrimer K., Netto A.S. (2019). Inclusion of sunflower oil in the bovine diet improves milk nutritional profile. Nutrients, 11: 481.]Search in Google Scholar
[Shaaban M.M., Kholif A.E., Abd El Tawab A.M., Radwan M.A., Hadhoud F.I., Khattab M.S.A., Saleh H.M., Anele U.Y. (2021). Thyme and celery as potential alternatives to ionophores use in livestock production: their effects on feed utilization, growth performance and meat quality of Barki lambs. Small Rumin. Res., 200: 106400.]Search in Google Scholar
[Sofi F., Buccioni A., Cesari F., Gori A.M., Minieri S., Mannini L., Casini A., Gensini G.F., Abbate R., Antongiovanni M. (2010). Effects of a dairy product (pecorino cheese) naturally rich in cis-9, trans-11 conjugated linoleic acid on lipid, inflammatory and haemorheological variables: A dietary intervention study. Nutr. Metab. Cardiovasc. Dis., 20: 117–124.]Search in Google Scholar
[Stamey J.A., Shepherd D.M., de Veth M.J., Corl B.A. (2012). Use of algae or algal oil rich in n-3 fatty acids as a feed supplement for dairy cattle. J. Dairy Sci., 95: 5269–5275.]Search in Google Scholar
[Suksombat W., Thanh L.P., Meeprom C., Mirattanaphrai R. (2016). Effect of linseed oil supplementation on performance and milk fatty acid composition in dairy cows. Anim. Sci. J., 87: 1545–1553.]Search in Google Scholar
[Thanh L.P., Suksombat W. (2015). Milk yield, composition, and fatty acid profile in dairy cows fed a high-concentrate diet blended with oil mixtures rich in polyunsaturated fatty acids. Asian-Australas. J. Anim. Sci., 28: 796–806.]Search in Google Scholar
[Till B.E., Huntington J.A., Kliem K.E., Taylor-Pickard J., Sinclair L.A. (2020). Long term dietary supplementation with microalgae increases plasma docosahexaenoic acid in milk and plasma but does not affect plasma 13,14-dihydro-15-keto PGF2α concentration in dairy cows. J. Dairy Res., 87: 14–22.]Search in Google Scholar
[Toral P.G., Hervás G., Gómez-Cortés P., Frutos P., Juárez M., de la Fuente M.A. (2010). Milk fatty acid profile and dairy sheep performance in response to diet supplementation with sunflower oil plus incremental levels of marine algae. J. Dairy Sci., 93: 1655–1667.]Search in Google Scholar
[Toral P.G., Hervás G., Belenguer A., Bichi E., Frutos P. (2013). Effect of the inclusion of quebracho tannins in a diet rich in linoleic acid on milk fatty acid composition in dairy ewes. J. Dairy Sci., 96: 431–439.]Search in Google Scholar
[Toral P.G., Rouel J., Bernard L., Chilliard Y. (2014). Interaction between fish oil and plant oils or starchy concentrates in the diet: Effects on dairy performance and milk fatty acid composition in goats. Anim. Feed Sci. Technol., 198: 67–82.]Search in Google Scholar
[Tripathi M.K. (2015). Effect of nutrition on production, composition, fatty acids and nutraceutical properties of milk. Adv. Dairy Res., 2: 1–11.]Search in Google Scholar
[Vafa T.S., Naserian A.A., Moussavi A.R.H., Valizadeh R., Mesgaran M.D. (2012). Effect of supplementation of fish and canola oil in the diet on milk fatty acid composition in early lactating Holstein cows. Asian-Australas. J. Anim. Sci., 25: 311–319.]Search in Google Scholar
[Vargas-Bello-Pérez E., Cancino-Padilla N., Geldsetzer-Mendoza C., Vyhmeister S., Morales M.S., Leskinen H., Romero J., Garnsworthy P.C., Ibáñez R.A. (2019). Effect of feeding cows with unsaturated fatty acid sources on milk production, milk composition, milk fatty acid profile, and physicochemical and sensory characteristics of ice cream. Animals, 9: 568.]Search in Google Scholar
[Vlaeminck B., Fievez V., Cabrita A.R.J., Fonseca A.J.M., Dewhurst R.J. (2006). Factors affecting odd- and branched-chain fatty acids in milk: A review. Anim. Feed Sci. Technol., 131: 389–417.]Search in Google Scholar