about
A genetic variant in the LDLR promoter is responsible for part of the LDL-cholesterol variability in primary hypercholesterolemiaPhytosterol plasma concentrations and coronary heart disease in the prospective Spanish EPIC cohort.FABP4 plasma levels are increased in familial combined hyperlipidemia.Effects of ezetimibe on cholesterol metabolism in HIV-infected patients with protease inhibitor-associated dyslipidemia: a single-arm intervention trialDietary Marine ω-3 Fatty Acids and Incident Sight-Threatening Retinopathy in Middle-Aged and Older Individuals With Type 2 Diabetes: Prospective Investigation From the PREDIMED Trial.The Walnuts and Healthy Aging Study (WAHA): Protocol for a Nutritional Intervention Trial with Walnuts on Brain Aging.Clinical Application of Plant Sterol and Stanol Products.The proportion of total C18:1 trans-fatty acids in red blood cell membranes relates to carotid plaque prevalence.Long-chain n-3 PUFA supplied by the usual diet decrease plasma stearoyl-CoA desaturase index in non-hypertriglyceridemic older adults at high vascular risk.Increases in Plasma Tryptophan Are Inversely Associated with Incident Cardiovascular Disease in the Prevención con Dieta Mediterránea (PREDIMED) Study.Nuclear magnetic resonance lipoprotein abnormalities in newly-diagnosed type 2 diabetes and their association with preclinical carotid atherosclerosis.Adenine nucleotide changes in the remnant liver: An early signal for regeneration after partial hepatectomy.Red Blood Cell Eicosapentaenoic Acid Inversely Relates to MRI-Assessed Carotid Plaque Lipid Core Burden in Elders at High Cardiovascular Risk.A moderate intake of phytosterols from habitual diet affects cholesterol metabolism.Phytosterols inhibit the tumor growth and lipoprotein oxidizability induced by a high-fat diet in mice with inherited breast cancer.Serum sterol responses to increasing plant sterol intake from natural foods in the Mediterranean diet.Mediterranean diet supplemented with nuts reduces waist circumference and shifts lipoprotein subfractions to a less atherogenic pattern in subjects at high cardiovascular risk.Inverse association between serum phospholipid oleic acid and insulin resistance in subjects with primary dyslipidaemia.Femoral atherosclerosis in heterozygous familial hypercholesterolemia: influence of the genetic defect.Serum lipid responses to weight loss differ between overweight adults with familial hypercholesterolemia and those with familial combined hyperlipidemia.Relationship Between Total Serum Bilirubin Levels and Carotid and Femoral Atherosclerosis in Familial Dyslipidemia.ABCG5/G8 gene is associated with hypercholesterolemias without mutation in candidate genes and noncholesterol sterols.Effects of the Ser326Cys Polymorphism in the DNA Repair OGG1 Gene on Cancer, Cardiovascular, and All-Cause Mortality in the PREDIMED Study: Modulation by Diet.Relationship between noninvasive scores of nonalcoholic fatty liver disease and nuclear magnetic resonance lipoprotein abnormalities: A focus on atherogenic dyslipidemia.Functional analysis of new 3' untranslated regions genetic variants in genes associated with genetic hypercholesterolemias.APOA5 variants predispose hyperlipidemic patients to atherogenic dyslipidemia and subclinical atherosclerosis.Lipid phenotype and heritage pattern in families with genetic hypercholesterolemia not related to LDLR, APOB, PCSK9, or APOE.Carotid atherosclerosis in familial combined hyperlipidemia associated with the APOB/APOA-I ratio.Acute effects of high-fat meals enriched with walnuts or olive oil on postprandial endothelial function.Rare genetic variants with large effect on triglycerides in subjects with a clinical diagnosis of familial vs nonfamilial hypertriglyceridemia.The red blood cell proportion of arachidonic acid relates to shorter leukocyte telomeres in Mediterranean elders: A secondary analysis of a randomized controlled trial.Crossover study of diets enriched with virgin olive oil, walnuts or almonds. Effects on lipids and other cardiovascular risk markersAssociation of plasma markers of cholesterol homeostasis with metabolic syndrome components. A cross-sectional studyDeterminants of the omega-3 index in a Mediterranean population at increased risk for CHDCorrigendum to “APOA5 variants predispose hyperlipidemic patients to atherogenic dyslipidemia and subclinical atherosclerosis” [Atherosclerosis 240/1 (2015) 98–104]Apolipoprotein E gene mutations in subjects with mixed hyperlipidemia and a clinical diagnosis of familial combined hyperlipidemiaEffects of plant sterol esters in skimmed milk and vegetable-fat-enriched milk on serum lipids and non-cholesterol sterols in hypercholesterolaemic subjects: a randomised, placebo-controlled, crossover studyNaturally-occurring phytosterols in the usual diet influence cholesterol metabolism in healthy subjectsWhite blood cell count is associated with carotid and femoral atherosclerosisCarotid and femoral plaque burden is inversely associated with the α-linolenic acid proportion of serum phospholipids in Spanish subjects with primary dyslipidemia
P50
Q33614636-B814DAD2-92DB-4358-AF50-8FD3A4547F31Q33634183-B2942069-5218-42AD-81A4-2316C6415966Q33784529-CCE9526E-5186-43F7-AD65-ECD60C7F2C58Q34217293-39FA7590-5361-45BB-A136-F2BC26AA4EC1Q36107870-7E25BCE8-FE5D-44D0-B6C0-195D9CE276F5Q37574817-C4752778-B292-4544-9C4B-A6765F15E5E2Q38459419-D8B0F847-C299-4A3D-9640-A73DF6CB4C93Q38812328-7944F91B-458D-438B-A3E1-551055AEA048Q39141854-D0E11EF8-A224-4C40-98A2-D8D1333138FCQ40343646-AADC210A-737A-48C4-B701-F1466F230587Q40883955-F4502E29-966B-4D22-A9FD-D0582856EE62Q42100601-C49266A9-C421-423C-A294-81862A5B7722Q42368269-68D36ECC-2FCE-4539-A4AE-6C653F5176DFQ43112487-C0D25301-ACAF-46C1-9AE8-139AA1FDBE3AQ45771241-69D07B56-9DFF-40E8-8492-F194C5C7FCC1Q46027041-9FD88904-4544-4348-B83A-79233FEAF8F0Q46461377-9E01F83C-9A60-4CEC-A7F8-B9DAE553C266Q46483722-663706E2-FBF6-48AE-B1F6-51522A1314C0Q46838366-AC3818EA-31EB-47E3-8D88-405A8B3EEF0DQ47583784-20173D39-2F0F-4149-81BE-2B7B00F6CA89Q47598298-7221E2E2-7AAF-454F-862B-8346AB9C2E9CQ50077771-EA2E091C-2DCC-4F60-9B58-06D7CB1A8EE0Q50161124-B4E2EF77-541F-46A3-8361-9FE1299C27B7Q50207315-3B82755A-5D86-4D7F-B4EF-0031368BA2A9Q51002881-087E3741-4E3E-4B5C-A5A1-4758850B278EQ51044914-8F0482AF-86B2-42FF-81A8-8CF92A776741Q51284738-1BA89B6D-01AD-4E43-8D92-4AD5E8126A4EQ51465735-8B151DD8-B034-46FD-8C1B-0B2BB0A6BEBCQ51487688-C5824700-56D0-4EEB-854E-33BA717EB973Q51541596-335C9C4C-4046-476B-BB34-C592F185CEE1Q51767372-50C25A13-91F3-4C27-A9D8-1CF7C1279814Q58419612-B2565DED-1F74-4625-B31F-C2F64F30DF00Q58931258-A707052E-CBAA-402B-AA07-1CAEB0CD51CFQ59158015-753C2C43-B7A3-4961-B965-9479148A93D2Q59237310-B9D3D96B-4A9E-4DCA-909E-C6DCC654F5D8Q59237335-652D694F-73EC-4054-9462-FA508F397CA2Q59237339-10904C61-4E14-452B-B313-36646575014DQ59237342-0C45A87A-AF87-4D51-BB3B-A65F7C87A818Q59237346-A58B5795-4206-4D44-9EE1-358CED8ED41AQ59237350-EDFA5A4C-8E3C-4BCE-9AF9-A42F81A259BA
P50
description
researcher ORCID ID = 0000-0002-1895-5644
@en
wetenschapper
@nl
name
Montserrat Cofan
@ast
Montserrat Cofan
@en
Montserrat Cofan
@es
Montserrat Cofan
@nl
type
label
Montserrat Cofan
@ast
Montserrat Cofan
@en
Montserrat Cofan
@es
Montserrat Cofan
@nl
prefLabel
Montserrat Cofan
@ast
Montserrat Cofan
@en
Montserrat Cofan
@es
Montserrat Cofan
@nl
P106
P1153
6602419864
P21
P31
P496
0000-0002-1895-5644