Ácido graso omega 6 (Spanish Wikipedia)

Analysis of information sources in references of the Wikipedia article "Ácido graso omega 6" in Spanish language version.

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21doi.org

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16issn.org

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13nih.gov

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8sciencedirect.com

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4bmj.com

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3web.archive.org

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2ajcn.org

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2csuchico.edu

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ahajournals.org

Sanders, Thomas A.B. (21 de mayo de 2019). «Omega-6 Fatty Acids and Cardiovascular Disease». Circulation 139 (21): 2437-2439. doi:10.1161/CIRCULATIONAHA.119.040331. Consultado el 28 de abril de 2022.

ajcn.org

Hibbeln, Joseph R.; Nieminen, Levi R.G.; Blasbalg, Tanya L.; Riggs, Jessica A.; Lands, William E.M. (junio de 2006). «Healthy intakes of n−3 and n−6 fatty acids: estimations considering worldwide diversity». American Journal of Clinical Nutrition (American Society for Nutrition) 83 (6, supplement): 1483S-1493S. PMID 16841858. Archivado desde el original el 25 de junio de 2010.
Calder, Philip C. (junio de 2006). «n−3 polyunsaturated fatty acids, inflammation, and inflammatory diseases». American Journal of Clinical Nutrition (American Society for Nutrition) 83 (6, supplement): 1505S-1519S. PMID 16841861. Archivado desde el original el 30 de octubre de 2010.

bmj.com

openheart.bmj.com

DiNicolantonio, James J.; O’Keefe, James H. (1 de octubre de 2018). «Omega-6 vegetable oils as a driver of coronary heart disease: the oxidized linoleic acid hypothesis». Open Heart (en inglés) 5 (2): e000898. ISSN 2053-3624. PMID 30364556. doi:10.1136/openhrt-2018-000898. Consultado el 28 de abril de 2022.
DiNicolantonio, James J.; O’Keefe, James H. (1 de noviembre de 2018). «Importance of maintaining a low omega–6/omega–3 ratio for reducing inflammation». Open Heart (en inglés) 5 (2): e000946. ISSN 2053-3624. PMID 30564378. doi:10.1136/openhrt-2018-000946. Consultado el 4 de enero de 2023. «dietary LA significantly increases cyclooxygenase-2 (COX-2) expression in the aorta,2 converting arachidonic acid (AA) to proinflammatory eicosanoids».
DiNicolantonio, James J.; O’Keefe, James H. (1 de noviembre de 2018). «Importance of maintaining a low omega–6/omega–3 ratio for reducing inflammation». Open Heart (en inglés) 5 (2): e000946. ISSN 2053-3624. PMID 30564378. doi:10.1136/openhrt-2018-000946. Consultado el 4 de enero de 2023. «Additionally, there is an AA-independent pathway of inflammation promoted by the intake of omega-6 seed oils such as increased production of oxidised linoleic acid metabolites (OXLAMs) and proinflammatory LA CYP-eicosanoids».
DiNicolantonio, James J.; O’Keefe, James H. (1 de noviembre de 2018). «Importance of maintaining a low omega–6/omega–3 ratio for reducing inflammation». Open Heart (en inglés) 5 (2): e000946. ISSN 2053-3624. PMID 30564378. doi:10.1136/openhrt-2018-000946. Consultado el 4 de enero de 2023. «Omega-3 PUFAs also reduces adhesion molecules (VCAM-1 and ICAM-1), chemokines (MCP-1), matrix metalloproteinases and inflammatory cytokines».

csuchico.edu

Daley, C.A.; Abbott, A.; Doyle, P.; Nader, G.; Larson, S. (2004). A literature review of the value-added nutrients found in grass-fed beef products. California State University, Chico (College of Agriculture). Archivado desde el original el 6 de julio de 2008. Consultado el 23 de marzo de 2008.
California State University, Chico. [2]

doi.org

dx.doi.org

Lands, William E.M. (diciembre de 2005). «Dietary fat and health: the evidence and the politics of prevention: careful use of dietary fats can improve life and prevent disease». Annals of the New York Academy of Sciences (Blackwell) 1055: 179-192. PMID 16387724. doi:10.1196/annals.1323.028.
Okuyama, Hirohmi; Ichikawa, Yuko; Sun, Yueji; Hamazaki, Tomohito; Lands, William E.M. (2007). «ω3 fatty acids effectively prevent coronary heart disease and other late-onset diseases: the excessive linoleic acid syndrome». World Review of Nutritional Dietetics (Karger) 96 (Prevention of Coronary Heart Disease): 83-103. ISBN 3-8055-8179-3. PMID 17167282. doi:10.1159/000097809.
Simopoulos, Artemis P. (octubre de 2002). «The importance of the ratio of omega-6/omega-3 essential fatty acids». Biomedicine & Pharmacotherapy 56 (8): 365-379. PMID 12442909. doi:10.1016/S0753-3322(02)00253-6.
name=" Smith2008">Smith, William L. (enero de 2008). «Nutritionally essential fatty acids and biologically indispensable cyclooxygenases». Trends in Biochemical Sciences (Elsevier) 33 (1): 27-37. PMID 18155912. doi:10.1016/j.tibs.2007.09.013.
Visioli, Francesco; Poli, Andrea (2020-12). «Fatty Acids and Cardiovascular Risk. Evidence, Lack of Evidence, and Diligence». Nutrients (en inglés) 12 (12): 3782. ISSN 2072-6643. doi:10.3390/nu12123782. Consultado el 28 de abril de 2022.
Marangoni, Franca; Agostoni, Carlo; Borghi, Claudio; Catapano, Alberico L.; Cena, Hellas; Ghiselli, Andrea; La Vecchia, Carlo; Lercker, Giovanni et al. (1 de enero de 2020). «Dietary linoleic acid and human health: Focus on cardiovascular and cardiometabolic effects». Atherosclerosis (en inglés) 292: 90-98. ISSN 0021-9150. doi:10.1016/j.atherosclerosis.2019.11.018. Consultado el 4 de enero de 2023. «It has been calculated that the lowest LA intake necessary to prevent signs of deficiency in humans is about 2 g/day, which is easily reachable with a typical adult diet».
Marangoni, Franca; Agostoni, Carlo; Borghi, Claudio; Catapano, Alberico L.; Cena, Hellas; Ghiselli, Andrea; La Vecchia, Carlo; Lercker, Giovanni et al. (1 de enero de 2020). «Dietary linoleic acid and human health: Focus on cardiovascular and cardiometabolic effects». Atherosclerosis (en inglés) 292: 90-98. ISSN 0021-9150. doi:10.1016/j.atherosclerosis.2019.11.018. Consultado el 4 de enero de 2023. «LA can be metabolized by the enzymes elongases and desaturases to generate PUFA with a longer carbon chain and a greater number of double bonds; among these, AA is the most abundant and physiologically relevant one».
Marangoni, Franca; Agostoni, Carlo; Borghi, Claudio; Catapano, Alberico L.; Cena, Hellas; Ghiselli, Andrea; La Vecchia, Carlo; Lercker, Giovanni et al. (1 de enero de 2020). «Dietary linoleic acid and human health: Focus on cardiovascular and cardiometabolic effects». Atherosclerosis (en inglés) 292: 90-98. ISSN 0021-9150. doi:10.1016/j.atherosclerosis.2019.11.018. Consultado el 4 de enero de 2023. «In humans, the conversion of LA to LC-PUFA (essentially AA) is very limited (<1%) [22]. Consequently, increasing the intake of dietary LA does not lead to a significant increase of AA tissue levels, nor contributes to the biosynthesis of prostaglandins or other AA metabolites [23,24].»
Marangoni, Franca; Agostoni, Carlo; Borghi, Claudio; Catapano, Alberico L.; Cena, Hellas; Ghiselli, Andrea; La Vecchia, Carlo; Lercker, Giovanni et al. (1 de enero de 2020). «Dietary linoleic acid and human health: Focus on cardiovascular and cardiometabolic effects». Atherosclerosis (en inglés) 292: 90-98. ISSN 0021-9150. doi:10.1016/j.atherosclerosis.2019.11.018. Consultado el 4 de enero de 2023. «Another critical point is the competition of fatty acids belonging to different series (n-3, n-6, n-9) as substrates for desaturases and elongases, which preferentially use n-3 fatty acids as substrate, followed by n-6 and n-9 [25]. The activity of these enzymes is influenced by several factors, which may increase (glucose, insulin, diets lacking in essential fatty acids) or reduce it (age, adrenaline, glucagon, steroids, diets rich in cholesterol and oxysterols, marine oils).»
Marangoni, Franca; Agostoni, Carlo; Borghi, Claudio; Catapano, Alberico L.; Cena, Hellas; Ghiselli, Andrea; La Vecchia, Carlo; Lercker, Giovanni et al. (1 de enero de 2020). «Dietary linoleic acid and human health: Focus on cardiovascular and cardiometabolic effects». Atherosclerosis (en inglés) 292: 90-98. ISSN 0021-9150. doi:10.1016/j.atherosclerosis.2019.11.018. Consultado el 4 de enero de 2023. «After hydrolysis by lipase enzymes and/or emulsification by bile salts, dietary LA (as well as all dietary fats) is absorbed by enterocytes from the lumen of the small intestine. Within enterocytes, LA is re-esterified into triglycerides (TG) or, to a lesser extent, into phospholipids or cholesteryl esters, which are then incorporated into chylomicrons and reach the bloodstream. The subsequent hydrolysis by the lipoprotein lipase enzyme (LPL) releases fatty acids (including LA), which are used for energy purposes by muscle tissue or stored in adipose tissue.»
Marangoni, Franca; Agostoni, Carlo; Borghi, Claudio; Catapano, Alberico L.; Cena, Hellas; Ghiselli, Andrea; La Vecchia, Carlo; Lercker, Giovanni et al. (1 de enero de 2020). «Dietary linoleic acid and human health: Focus on cardiovascular and cardiometabolic effects». Atherosclerosis (en inglés) 292: 90-98. ISSN 0021-9150. doi:10.1016/j.atherosclerosis.2019.11.018. Consultado el 4 de enero de 2023. «Within cells, LA can be incorporated into cell membrane lipids or, alternatively, used as a substrate for metabolic reactions, according to the type of tissue and its requirements. In blood, LA is mainly present in plasma (~30%), where it is transported by LDL (35%) and HDL (30%), and - to a lesser extent - in platelets and red blood cell membranes (9.3% and 9.7%, respectively). In plasma, LA is esterified predominantly in cholesteryl esters (~50%), followed by phospholipids (40%) and TG (10%) [30]. In cell membranes, LA is incorporated in the sn-2 position in phospholipids, TG and cholesteryl esters. The time-course of dietary-induced changes in LA concentrations in erythrocytes is similar to that in plasma and platelet lipids [31].»
Sanders, Thomas A.B. (21 de mayo de 2019). «Omega-6 Fatty Acids and Cardiovascular Disease». Circulation 139 (21): 2437-2439. doi:10.1161/CIRCULATIONAHA.119.040331. Consultado el 28 de abril de 2022.
Liput, Kamila P.; Lepczyński, Adam; Ogłuszka, Magdalena; Nawrocka, Agata; Poławska, Ewa; Grzesiak, Agata; Ślaska, Brygida; Pareek, Chandra S. et al. (2021-01). «Effects of Dietary n–3 and n–6 Polyunsaturated Fatty Acids in Inflammation and Cancerogenesis». International Journal of Molecular Sciences (en inglés) 22 (13): 6965. ISSN 1422-0067. doi:10.3390/ijms22136965. Consultado el 28 de abril de 2022.
Kopp, Wolfgang (24 de octubre de 2019). «How Western Diet And Lifestyle Drive The Pandemic Of Obesity And Civilization Diseases». Diabetes, Metabolic Syndrome and Obesity: Targets and Therapy 12: 2221-2236. ISSN 1178-7007. PMC 6817492. PMID 31695465. doi:10.2147/DMSO.S216791. Consultado el 28 de abril de 2022.
Marangoni, Franca; Agostoni, Carlo; Borghi, Claudio; Catapano, Alberico L.; Cena, Hellas; Ghiselli, Andrea; La Vecchia, Carlo; Lercker, Giovanni et al. (1 de enero de 2020). «Dietary linoleic acid and human health: Focus on cardiovascular and cardiometabolic effects». Atherosclerosis (en inglés) 292: 90-98. ISSN 0021-9150. doi:10.1016/j.atherosclerosis.2019.11.018. Consultado el 28 de abril de 2022.
Liao, Li-zhen; Li, Wei-dong; Liu, Ying; Li, Jia-ping; Zhuang, Xiao-dong; Liao, Xin-xue (10 de febrero de 2020). «Exploring the causal pathway from omega-6 levels to coronary heart disease: A network Mendelian randomization study». Nutrition, Metabolism and Cardiovascular Diseases (en inglés) 30 (2): 233-240. ISSN 0939-4753. doi:10.1016/j.numecd.2019.09.013. Consultado el 28 de abril de 2022.
Grootveld, Martin; Addis, Paul B.; Le Gresley, Adam (2022). «Editorial: Dietary Lipid Oxidation and Fried Food Toxicology». Frontiers in Nutrition 9: 858063. ISSN 2296-861X. PMC 8931324. PMID 35308283. doi:10.3389/fnut.2022.858063. Consultado el 4 de enero de 2023. «a recent review has summarized intelligibly, the massive amount of evidence adversely implicating omega-6 rich vegetable oils in the development, progression and pathogenesis of human CVDs (2), citing the fact that the introduction of soybean oil in the USA coincides clearly with an increased incidence of this non-communicable chronic disease (NCD).»
DiNicolantonio, James J.; O’Keefe, James H. (1 de octubre de 2018). «Omega-6 vegetable oils as a driver of coronary heart disease: the oxidized linoleic acid hypothesis». Open Heart (en inglés) 5 (2): e000898. ISSN 2053-3624. PMID 30364556. doi:10.1136/openhrt-2018-000898. Consultado el 28 de abril de 2022.
DiNicolantonio, James J.; O’Keefe, James H. (1 de noviembre de 2018). «Importance of maintaining a low omega–6/omega–3 ratio for reducing inflammation». Open Heart (en inglés) 5 (2): e000946. ISSN 2053-3624. PMID 30564378. doi:10.1136/openhrt-2018-000946. Consultado el 4 de enero de 2023. «dietary LA significantly increases cyclooxygenase-2 (COX-2) expression in the aorta,2 converting arachidonic acid (AA) to proinflammatory eicosanoids».
DiNicolantonio, James J.; O’Keefe, James H. (1 de noviembre de 2018). «Importance of maintaining a low omega–6/omega–3 ratio for reducing inflammation». Open Heart (en inglés) 5 (2): e000946. ISSN 2053-3624. PMID 30564378. doi:10.1136/openhrt-2018-000946. Consultado el 4 de enero de 2023. «Additionally, there is an AA-independent pathway of inflammation promoted by the intake of omega-6 seed oils such as increased production of oxidised linoleic acid metabolites (OXLAMs) and proinflammatory LA CYP-eicosanoids».
DiNicolantonio, James J.; O’Keefe, James H. (1 de noviembre de 2018). «Importance of maintaining a low omega–6/omega–3 ratio for reducing inflammation». Open Heart (en inglés) 5 (2): e000946. ISSN 2053-3624. PMID 30564378. doi:10.1136/openhrt-2018-000946. Consultado el 4 de enero de 2023. «Omega-3 PUFAs also reduces adhesion molecules (VCAM-1 and ICAM-1), chemokines (MCP-1), matrix metalloproteinases and inflammatory cytokines».

issn.org

portal.issn.org

Visioli, Francesco; Poli, Andrea (2020-12). «Fatty Acids and Cardiovascular Risk. Evidence, Lack of Evidence, and Diligence». Nutrients (en inglés) 12 (12): 3782. ISSN 2072-6643. doi:10.3390/nu12123782. Consultado el 28 de abril de 2022.
Marangoni, Franca; Agostoni, Carlo; Borghi, Claudio; Catapano, Alberico L.; Cena, Hellas; Ghiselli, Andrea; La Vecchia, Carlo; Lercker, Giovanni et al. (1 de enero de 2020). «Dietary linoleic acid and human health: Focus on cardiovascular and cardiometabolic effects». Atherosclerosis (en inglés) 292: 90-98. ISSN 0021-9150. doi:10.1016/j.atherosclerosis.2019.11.018. Consultado el 4 de enero de 2023. «It has been calculated that the lowest LA intake necessary to prevent signs of deficiency in humans is about 2 g/day, which is easily reachable with a typical adult diet».
Marangoni, Franca; Agostoni, Carlo; Borghi, Claudio; Catapano, Alberico L.; Cena, Hellas; Ghiselli, Andrea; La Vecchia, Carlo; Lercker, Giovanni et al. (1 de enero de 2020). «Dietary linoleic acid and human health: Focus on cardiovascular and cardiometabolic effects». Atherosclerosis (en inglés) 292: 90-98. ISSN 0021-9150. doi:10.1016/j.atherosclerosis.2019.11.018. Consultado el 4 de enero de 2023. «LA can be metabolized by the enzymes elongases and desaturases to generate PUFA with a longer carbon chain and a greater number of double bonds; among these, AA is the most abundant and physiologically relevant one».
Marangoni, Franca; Agostoni, Carlo; Borghi, Claudio; Catapano, Alberico L.; Cena, Hellas; Ghiselli, Andrea; La Vecchia, Carlo; Lercker, Giovanni et al. (1 de enero de 2020). «Dietary linoleic acid and human health: Focus on cardiovascular and cardiometabolic effects». Atherosclerosis (en inglés) 292: 90-98. ISSN 0021-9150. doi:10.1016/j.atherosclerosis.2019.11.018. Consultado el 4 de enero de 2023. «In humans, the conversion of LA to LC-PUFA (essentially AA) is very limited (<1%) [22]. Consequently, increasing the intake of dietary LA does not lead to a significant increase of AA tissue levels, nor contributes to the biosynthesis of prostaglandins or other AA metabolites [23,24].»
Marangoni, Franca; Agostoni, Carlo; Borghi, Claudio; Catapano, Alberico L.; Cena, Hellas; Ghiselli, Andrea; La Vecchia, Carlo; Lercker, Giovanni et al. (1 de enero de 2020). «Dietary linoleic acid and human health: Focus on cardiovascular and cardiometabolic effects». Atherosclerosis (en inglés) 292: 90-98. ISSN 0021-9150. doi:10.1016/j.atherosclerosis.2019.11.018. Consultado el 4 de enero de 2023. «Another critical point is the competition of fatty acids belonging to different series (n-3, n-6, n-9) as substrates for desaturases and elongases, which preferentially use n-3 fatty acids as substrate, followed by n-6 and n-9 [25]. The activity of these enzymes is influenced by several factors, which may increase (glucose, insulin, diets lacking in essential fatty acids) or reduce it (age, adrenaline, glucagon, steroids, diets rich in cholesterol and oxysterols, marine oils).»
Marangoni, Franca; Agostoni, Carlo; Borghi, Claudio; Catapano, Alberico L.; Cena, Hellas; Ghiselli, Andrea; La Vecchia, Carlo; Lercker, Giovanni et al. (1 de enero de 2020). «Dietary linoleic acid and human health: Focus on cardiovascular and cardiometabolic effects». Atherosclerosis (en inglés) 292: 90-98. ISSN 0021-9150. doi:10.1016/j.atherosclerosis.2019.11.018. Consultado el 4 de enero de 2023. «After hydrolysis by lipase enzymes and/or emulsification by bile salts, dietary LA (as well as all dietary fats) is absorbed by enterocytes from the lumen of the small intestine. Within enterocytes, LA is re-esterified into triglycerides (TG) or, to a lesser extent, into phospholipids or cholesteryl esters, which are then incorporated into chylomicrons and reach the bloodstream. The subsequent hydrolysis by the lipoprotein lipase enzyme (LPL) releases fatty acids (including LA), which are used for energy purposes by muscle tissue or stored in adipose tissue.»
Marangoni, Franca; Agostoni, Carlo; Borghi, Claudio; Catapano, Alberico L.; Cena, Hellas; Ghiselli, Andrea; La Vecchia, Carlo; Lercker, Giovanni et al. (1 de enero de 2020). «Dietary linoleic acid and human health: Focus on cardiovascular and cardiometabolic effects». Atherosclerosis (en inglés) 292: 90-98. ISSN 0021-9150. doi:10.1016/j.atherosclerosis.2019.11.018. Consultado el 4 de enero de 2023. «Within cells, LA can be incorporated into cell membrane lipids or, alternatively, used as a substrate for metabolic reactions, according to the type of tissue and its requirements. In blood, LA is mainly present in plasma (~30%), where it is transported by LDL (35%) and HDL (30%), and - to a lesser extent - in platelets and red blood cell membranes (9.3% and 9.7%, respectively). In plasma, LA is esterified predominantly in cholesteryl esters (~50%), followed by phospholipids (40%) and TG (10%) [30]. In cell membranes, LA is incorporated in the sn-2 position in phospholipids, TG and cholesteryl esters. The time-course of dietary-induced changes in LA concentrations in erythrocytes is similar to that in plasma and platelet lipids [31].»
Liput, Kamila P.; Lepczyński, Adam; Ogłuszka, Magdalena; Nawrocka, Agata; Poławska, Ewa; Grzesiak, Agata; Ślaska, Brygida; Pareek, Chandra S. et al. (2021-01). «Effects of Dietary n–3 and n–6 Polyunsaturated Fatty Acids in Inflammation and Cancerogenesis». International Journal of Molecular Sciences (en inglés) 22 (13): 6965. ISSN 1422-0067. doi:10.3390/ijms22136965. Consultado el 28 de abril de 2022.
Kopp, Wolfgang (24 de octubre de 2019). «How Western Diet And Lifestyle Drive The Pandemic Of Obesity And Civilization Diseases». Diabetes, Metabolic Syndrome and Obesity: Targets and Therapy 12: 2221-2236. ISSN 1178-7007. PMC 6817492. PMID 31695465. doi:10.2147/DMSO.S216791. Consultado el 28 de abril de 2022.
Marangoni, Franca; Agostoni, Carlo; Borghi, Claudio; Catapano, Alberico L.; Cena, Hellas; Ghiselli, Andrea; La Vecchia, Carlo; Lercker, Giovanni et al. (1 de enero de 2020). «Dietary linoleic acid and human health: Focus on cardiovascular and cardiometabolic effects». Atherosclerosis (en inglés) 292: 90-98. ISSN 0021-9150. doi:10.1016/j.atherosclerosis.2019.11.018. Consultado el 28 de abril de 2022.
Liao, Li-zhen; Li, Wei-dong; Liu, Ying; Li, Jia-ping; Zhuang, Xiao-dong; Liao, Xin-xue (10 de febrero de 2020). «Exploring the causal pathway from omega-6 levels to coronary heart disease: A network Mendelian randomization study». Nutrition, Metabolism and Cardiovascular Diseases (en inglés) 30 (2): 233-240. ISSN 0939-4753. doi:10.1016/j.numecd.2019.09.013. Consultado el 28 de abril de 2022.
Grootveld, Martin; Addis, Paul B.; Le Gresley, Adam (2022). «Editorial: Dietary Lipid Oxidation and Fried Food Toxicology». Frontiers in Nutrition 9: 858063. ISSN 2296-861X. PMC 8931324. PMID 35308283. doi:10.3389/fnut.2022.858063. Consultado el 4 de enero de 2023. «a recent review has summarized intelligibly, the massive amount of evidence adversely implicating omega-6 rich vegetable oils in the development, progression and pathogenesis of human CVDs (2), citing the fact that the introduction of soybean oil in the USA coincides clearly with an increased incidence of this non-communicable chronic disease (NCD).»
DiNicolantonio, James J.; O’Keefe, James H. (1 de octubre de 2018). «Omega-6 vegetable oils as a driver of coronary heart disease: the oxidized linoleic acid hypothesis». Open Heart (en inglés) 5 (2): e000898. ISSN 2053-3624. PMID 30364556. doi:10.1136/openhrt-2018-000898. Consultado el 28 de abril de 2022.
DiNicolantonio, James J.; O’Keefe, James H. (1 de noviembre de 2018). «Importance of maintaining a low omega–6/omega–3 ratio for reducing inflammation». Open Heart (en inglés) 5 (2): e000946. ISSN 2053-3624. PMID 30564378. doi:10.1136/openhrt-2018-000946. Consultado el 4 de enero de 2023. «dietary LA significantly increases cyclooxygenase-2 (COX-2) expression in the aorta,2 converting arachidonic acid (AA) to proinflammatory eicosanoids».
DiNicolantonio, James J.; O’Keefe, James H. (1 de noviembre de 2018). «Importance of maintaining a low omega–6/omega–3 ratio for reducing inflammation». Open Heart (en inglés) 5 (2): e000946. ISSN 2053-3624. PMID 30564378. doi:10.1136/openhrt-2018-000946. Consultado el 4 de enero de 2023. «Additionally, there is an AA-independent pathway of inflammation promoted by the intake of omega-6 seed oils such as increased production of oxidised linoleic acid metabolites (OXLAMs) and proinflammatory LA CYP-eicosanoids».
DiNicolantonio, James J.; O’Keefe, James H. (1 de noviembre de 2018). «Importance of maintaining a low omega–6/omega–3 ratio for reducing inflammation». Open Heart (en inglés) 5 (2): e000946. ISSN 2053-3624. PMID 30564378. doi:10.1136/openhrt-2018-000946. Consultado el 4 de enero de 2023. «Omega-3 PUFAs also reduces adhesion molecules (VCAM-1 and ICAM-1), chemokines (MCP-1), matrix metalloproteinases and inflammatory cytokines».

mdpi.com

Visioli, Francesco; Poli, Andrea (2020-12). «Fatty Acids and Cardiovascular Risk. Evidence, Lack of Evidence, and Diligence». Nutrients (en inglés) 12 (12): 3782. ISSN 2072-6643. doi:10.3390/nu12123782. Consultado el 28 de abril de 2022.
Liput, Kamila P.; Lepczyński, Adam; Ogłuszka, Magdalena; Nawrocka, Agata; Poławska, Ewa; Grzesiak, Agata; Ślaska, Brygida; Pareek, Chandra S. et al. (2021-01). «Effects of Dietary n–3 and n–6 Polyunsaturated Fatty Acids in Inflammation and Cancerogenesis». International Journal of Molecular Sciences (en inglés) 22 (13): 6965. ISSN 1422-0067. doi:10.3390/ijms22136965. Consultado el 28 de abril de 2022.

nih.gov

ncbi.nlm.nih.gov

Lands, William E.M. (diciembre de 2005). «Dietary fat and health: the evidence and the politics of prevention: careful use of dietary fats can improve life and prevent disease». Annals of the New York Academy of Sciences (Blackwell) 1055: 179-192. PMID 16387724. doi:10.1196/annals.1323.028.
Hibbeln, Joseph R.; Nieminen, Levi R.G.; Blasbalg, Tanya L.; Riggs, Jessica A.; Lands, William E.M. (junio de 2006). «Healthy intakes of n−3 and n−6 fatty acids: estimations considering worldwide diversity». American Journal of Clinical Nutrition (American Society for Nutrition) 83 (6, supplement): 1483S-1493S. PMID 16841858. Archivado desde el original el 25 de junio de 2010.
Okuyama, Hirohmi; Ichikawa, Yuko; Sun, Yueji; Hamazaki, Tomohito; Lands, William E.M. (2007). «ω3 fatty acids effectively prevent coronary heart disease and other late-onset diseases: the excessive linoleic acid syndrome». World Review of Nutritional Dietetics (Karger) 96 (Prevention of Coronary Heart Disease): 83-103. ISBN 3-8055-8179-3. PMID 17167282. doi:10.1159/000097809.
Simopoulos, Artemis P. (octubre de 2002). «The importance of the ratio of omega-6/omega-3 essential fatty acids». Biomedicine & Pharmacotherapy 56 (8): 365-379. PMID 12442909. doi:10.1016/S0753-3322(02)00253-6.
Calder, Philip C. (junio de 2006). «n−3 polyunsaturated fatty acids, inflammation, and inflammatory diseases». American Journal of Clinical Nutrition (American Society for Nutrition) 83 (6, supplement): 1505S-1519S. PMID 16841861. Archivado desde el original el 30 de octubre de 2010.
name=" Smith2008">Smith, William L. (enero de 2008). «Nutritionally essential fatty acids and biologically indispensable cyclooxygenases». Trends in Biochemical Sciences (Elsevier) 33 (1): 27-37. PMID 18155912. doi:10.1016/j.tibs.2007.09.013.
Kopp, Wolfgang (24 de octubre de 2019). «How Western Diet And Lifestyle Drive The Pandemic Of Obesity And Civilization Diseases». Diabetes, Metabolic Syndrome and Obesity: Targets and Therapy 12: 2221-2236. ISSN 1178-7007. PMC 6817492. PMID 31695465. doi:10.2147/DMSO.S216791. Consultado el 28 de abril de 2022.
Grootveld, Martin; Addis, Paul B.; Le Gresley, Adam (2022). «Editorial: Dietary Lipid Oxidation and Fried Food Toxicology». Frontiers in Nutrition 9: 858063. ISSN 2296-861X. PMC 8931324. PMID 35308283. doi:10.3389/fnut.2022.858063. Consultado el 4 de enero de 2023. «a recent review has summarized intelligibly, the massive amount of evidence adversely implicating omega-6 rich vegetable oils in the development, progression and pathogenesis of human CVDs (2), citing the fact that the introduction of soybean oil in the USA coincides clearly with an increased incidence of this non-communicable chronic disease (NCD).»
DiNicolantonio, James J.; O’Keefe, James H. (1 de octubre de 2018). «Omega-6 vegetable oils as a driver of coronary heart disease: the oxidized linoleic acid hypothesis». Open Heart (en inglés) 5 (2): e000898. ISSN 2053-3624. PMID 30364556. doi:10.1136/openhrt-2018-000898. Consultado el 28 de abril de 2022.
DiNicolantonio, James J.; O’Keefe, James H. (1 de noviembre de 2018). «Importance of maintaining a low omega–6/omega–3 ratio for reducing inflammation». Open Heart (en inglés) 5 (2): e000946. ISSN 2053-3624. PMID 30564378. doi:10.1136/openhrt-2018-000946. Consultado el 4 de enero de 2023. «dietary LA significantly increases cyclooxygenase-2 (COX-2) expression in the aorta,2 converting arachidonic acid (AA) to proinflammatory eicosanoids».
DiNicolantonio, James J.; O’Keefe, James H. (1 de noviembre de 2018). «Importance of maintaining a low omega–6/omega–3 ratio for reducing inflammation». Open Heart (en inglés) 5 (2): e000946. ISSN 2053-3624. PMID 30564378. doi:10.1136/openhrt-2018-000946. Consultado el 4 de enero de 2023. «Additionally, there is an AA-independent pathway of inflammation promoted by the intake of omega-6 seed oils such as increased production of oxidised linoleic acid metabolites (OXLAMs) and proinflammatory LA CYP-eicosanoids».
DiNicolantonio, James J.; O’Keefe, James H. (1 de noviembre de 2018). «Importance of maintaining a low omega–6/omega–3 ratio for reducing inflammation». Open Heart (en inglés) 5 (2): e000946. ISSN 2053-3624. PMID 30564378. doi:10.1136/openhrt-2018-000946. Consultado el 4 de enero de 2023. «Omega-3 PUFAs also reduces adhesion molecules (VCAM-1 and ICAM-1), chemokines (MCP-1), matrix metalloproteinases and inflammatory cytokines».

pubmed.ncbi.nlm.nih.gov

Grootveld, Martin; Addis, Paul B.; Le Gresley, Adam (2022). «Editorial: Dietary Lipid Oxidation and Fried Food Toxicology». Frontiers in Nutrition 9: 858063. ISSN 2296-861X. PMC 8931324. PMID 35308283. doi:10.3389/fnut.2022.858063. Consultado el 4 de enero de 2023. «a recent review has summarized intelligibly, the massive amount of evidence adversely implicating omega-6 rich vegetable oils in the development, progression and pathogenesis of human CVDs (2), citing the fact that the introduction of soybean oil in the USA coincides clearly with an increased incidence of this non-communicable chronic disease (NCD).»

scielo.cl

VALENZUELA B., Alfonso y NIETO K., Susana. Ácidos grasos omega-6 y omega-3 en la nutrición perinatal: su importancia en el desarrollo del sistema nervioso y visual. Rev. chil. pediatr. [online]. mar. 2003, vol.74, no.2 [citado 27 de agosto de 2007], p.149-157. Disponible en la World Wide Web: [1]. ISSN 0370-4106.

sciencedirect.com

Marangoni, Franca; Agostoni, Carlo; Borghi, Claudio; Catapano, Alberico L.; Cena, Hellas; Ghiselli, Andrea; La Vecchia, Carlo; Lercker, Giovanni et al. (1 de enero de 2020). «Dietary linoleic acid and human health: Focus on cardiovascular and cardiometabolic effects». Atherosclerosis (en inglés) 292: 90-98. ISSN 0021-9150. doi:10.1016/j.atherosclerosis.2019.11.018. Consultado el 4 de enero de 2023. «It has been calculated that the lowest LA intake necessary to prevent signs of deficiency in humans is about 2 g/day, which is easily reachable with a typical adult diet».
Marangoni, Franca; Agostoni, Carlo; Borghi, Claudio; Catapano, Alberico L.; Cena, Hellas; Ghiselli, Andrea; La Vecchia, Carlo; Lercker, Giovanni et al. (1 de enero de 2020). «Dietary linoleic acid and human health: Focus on cardiovascular and cardiometabolic effects». Atherosclerosis (en inglés) 292: 90-98. ISSN 0021-9150. doi:10.1016/j.atherosclerosis.2019.11.018. Consultado el 4 de enero de 2023. «LA can be metabolized by the enzymes elongases and desaturases to generate PUFA with a longer carbon chain and a greater number of double bonds; among these, AA is the most abundant and physiologically relevant one».
Marangoni, Franca; Agostoni, Carlo; Borghi, Claudio; Catapano, Alberico L.; Cena, Hellas; Ghiselli, Andrea; La Vecchia, Carlo; Lercker, Giovanni et al. (1 de enero de 2020). «Dietary linoleic acid and human health: Focus on cardiovascular and cardiometabolic effects». Atherosclerosis (en inglés) 292: 90-98. ISSN 0021-9150. doi:10.1016/j.atherosclerosis.2019.11.018. Consultado el 4 de enero de 2023. «In humans, the conversion of LA to LC-PUFA (essentially AA) is very limited (<1%) [22]. Consequently, increasing the intake of dietary LA does not lead to a significant increase of AA tissue levels, nor contributes to the biosynthesis of prostaglandins or other AA metabolites [23,24].»
Marangoni, Franca; Agostoni, Carlo; Borghi, Claudio; Catapano, Alberico L.; Cena, Hellas; Ghiselli, Andrea; La Vecchia, Carlo; Lercker, Giovanni et al. (1 de enero de 2020). «Dietary linoleic acid and human health: Focus on cardiovascular and cardiometabolic effects». Atherosclerosis (en inglés) 292: 90-98. ISSN 0021-9150. doi:10.1016/j.atherosclerosis.2019.11.018. Consultado el 4 de enero de 2023. «Another critical point is the competition of fatty acids belonging to different series (n-3, n-6, n-9) as substrates for desaturases and elongases, which preferentially use n-3 fatty acids as substrate, followed by n-6 and n-9 [25]. The activity of these enzymes is influenced by several factors, which may increase (glucose, insulin, diets lacking in essential fatty acids) or reduce it (age, adrenaline, glucagon, steroids, diets rich in cholesterol and oxysterols, marine oils).»
Marangoni, Franca; Agostoni, Carlo; Borghi, Claudio; Catapano, Alberico L.; Cena, Hellas; Ghiselli, Andrea; La Vecchia, Carlo; Lercker, Giovanni et al. (1 de enero de 2020). «Dietary linoleic acid and human health: Focus on cardiovascular and cardiometabolic effects». Atherosclerosis (en inglés) 292: 90-98. ISSN 0021-9150. doi:10.1016/j.atherosclerosis.2019.11.018. Consultado el 4 de enero de 2023. «After hydrolysis by lipase enzymes and/or emulsification by bile salts, dietary LA (as well as all dietary fats) is absorbed by enterocytes from the lumen of the small intestine. Within enterocytes, LA is re-esterified into triglycerides (TG) or, to a lesser extent, into phospholipids or cholesteryl esters, which are then incorporated into chylomicrons and reach the bloodstream. The subsequent hydrolysis by the lipoprotein lipase enzyme (LPL) releases fatty acids (including LA), which are used for energy purposes by muscle tissue or stored in adipose tissue.»
Marangoni, Franca; Agostoni, Carlo; Borghi, Claudio; Catapano, Alberico L.; Cena, Hellas; Ghiselli, Andrea; La Vecchia, Carlo; Lercker, Giovanni et al. (1 de enero de 2020). «Dietary linoleic acid and human health: Focus on cardiovascular and cardiometabolic effects». Atherosclerosis (en inglés) 292: 90-98. ISSN 0021-9150. doi:10.1016/j.atherosclerosis.2019.11.018. Consultado el 4 de enero de 2023. «Within cells, LA can be incorporated into cell membrane lipids or, alternatively, used as a substrate for metabolic reactions, according to the type of tissue and its requirements. In blood, LA is mainly present in plasma (~30%), where it is transported by LDL (35%) and HDL (30%), and - to a lesser extent - in platelets and red blood cell membranes (9.3% and 9.7%, respectively). In plasma, LA is esterified predominantly in cholesteryl esters (~50%), followed by phospholipids (40%) and TG (10%) [30]. In cell membranes, LA is incorporated in the sn-2 position in phospholipids, TG and cholesteryl esters. The time-course of dietary-induced changes in LA concentrations in erythrocytes is similar to that in plasma and platelet lipids [31].»
Marangoni, Franca; Agostoni, Carlo; Borghi, Claudio; Catapano, Alberico L.; Cena, Hellas; Ghiselli, Andrea; La Vecchia, Carlo; Lercker, Giovanni et al. (1 de enero de 2020). «Dietary linoleic acid and human health: Focus on cardiovascular and cardiometabolic effects». Atherosclerosis (en inglés) 292: 90-98. ISSN 0021-9150. doi:10.1016/j.atherosclerosis.2019.11.018. Consultado el 28 de abril de 2022.
Liao, Li-zhen; Li, Wei-dong; Liu, Ying; Li, Jia-ping; Zhuang, Xiao-dong; Liao, Xin-xue (10 de febrero de 2020). «Exploring the causal pathway from omega-6 levels to coronary heart disease: A network Mendelian randomization study». Nutrition, Metabolism and Cardiovascular Diseases (en inglés) 30 (2): 233-240. ISSN 0939-4753. doi:10.1016/j.numecd.2019.09.013. Consultado el 28 de abril de 2022.

web.archive.org

Hibbeln, Joseph R.; Nieminen, Levi R.G.; Blasbalg, Tanya L.; Riggs, Jessica A.; Lands, William E.M. (junio de 2006). «Healthy intakes of n−3 and n−6 fatty acids: estimations considering worldwide diversity». American Journal of Clinical Nutrition (American Society for Nutrition) 83 (6, supplement): 1483S-1493S. PMID 16841858. Archivado desde el original el 25 de junio de 2010.
Daley, C.A.; Abbott, A.; Doyle, P.; Nader, G.; Larson, S. (2004). A literature review of the value-added nutrients found in grass-fed beef products. California State University, Chico (College of Agriculture). Archivado desde el original el 6 de julio de 2008. Consultado el 23 de marzo de 2008.
Calder, Philip C. (junio de 2006). «n−3 polyunsaturated fatty acids, inflammation, and inflammatory diseases». American Journal of Clinical Nutrition (American Society for Nutrition) 83 (6, supplement): 1505S-1519S. PMID 16841861. Archivado desde el original el 30 de octubre de 2010.