about
MADAMM: a multistaged docking with an automated molecular modeling protocolGlycosidase inhibitors: a patent review (2008-2013).Experimental and Theoretical Data on the Mechanism by Which Red Wine Anthocyanins Are Transported through a Human MKN-28 Gastric Cell Model.Chemical behavior of methylpyranomalvidin-3-O-glucoside in aqueous solution studied by NMR and UV-visible spectroscopy.Receptor-based virtual screening protocol for drug discovery.The Catalytic Mechanism of the Marine-Derived Macrocyclase PatGmacMolecular determinants of ligand specificity in family 11 carbohydrate binding modules: an NMR, X-ray crystallography and computational chemistry approach.HMG-CoA Reductase inhibitors: an updated review of patents of novel compounds and formulations (2011-2015).Molecular dynamics studies on both bound and unbound renin protease.QM/MM Studies on the β-Galactosidase Catalytic Mechanism: Hydrolysis and Transglycosylation Reactions.The glycation site specificity of human serum transferrin is a determinant for transferrin's functional impairment under elevated glycaemic conditions.Evidence for copigmentation interactions between deoxyanthocyanidin derivatives (oaklins) and common copigments in wine model solutions.Structural characterization of a A-type linked trimeric anthocyanin derived pigment occurring in a young Port wine.Mechanistic studies on the formation of glycosidase-substrate and glycosidase-inhibitor covalent intermediates.Antioxidant features of red wine pyranoanthocyanins: experimental and theoretical approaches.Study of human salivary proline-rich proteins interaction with food tannins.Mechanistic Insights on Human Phosphoglucomutase Revealed by Transition Path Sampling and Molecular Dynamics Calculations.Interaction between Wine Phenolic Acids and Salivary Proteins by Saturation-Transfer Difference Nuclear Magnetic Resonance Spectroscopy (STD-NMR) and Molecular Dynamics Simulations.Molecular Approach to the Synergistic Effect on Astringency Elicited by Mixtures of Flavanols.Reactivity of Cork Extracts with (+)-Catechin and Malvidin-3-O-glucoside in Wine Model Solutions: Identification of a New Family of Ellagitannin-Derived Compounds (Corklins).Discovery of new sites for drug binding to the hypertension-related renin-angiotensinogen complex.Mechanistic Pathway on Human α-Glucosidase Maltase-Glucoamylase Unveiled by QM/MM Calculations.Effect of flavonols on wine astringency and their interaction with human saliva.Human Bitter Taste Receptors Are Activated by Different Classes of PolyphenolsUnderstanding the Rate-Limiting Step of Glycogenolysis by Using QM/MM Calculations on Human Glycogen PhosphorylaseParametrization of Molybdenum Cofactors for the AMBER Force FieldEstablishing the Catalytic Mechanism of Human Pancreatic α-Amylase with QM/MM MethodsInsights into the structural determinants of substrate specificity and activity in mouse aldehyde oxidasesAnalyses of cobalt–ligand and potassium–ligand bond lengths in metalloproteins: trends and patternsThe catalytic mechanism of mouse renin studied with QM/MM calculationsVirtual screening and QSAR study of some pyrrolidine derivatives as α-mannosidase inhibitors for binding feature analysisAccuracy of Density Functionals in the Prediction of Electronic Proton Affinities of Amino Acid Side ChainsSynthesis of N-aryl-5-amino-4-cyanopyrazole derivatives as potent xanthine oxidase inhibitorsCharacterization of Sensory Properties of Flavanols--A Molecular Dynamic ApproachCorrection to "understanding the molecular mechanism of anthocyanin binding to pectin"Understanding the molecular mechanism of anthocyanin binding to pectinImpact of a pectic polysaccharide on oenin copigmentation mechanismCell Wall Mannoproteins from Yeast Affect Salivary Protein-Flavanol Interactions through Different Molecular MechanismsA 1000-year-old mystery solved: Unlocking the molecular structure for the medieval blue from Chrozophora tinctoria, also known as folium
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Q28286817-E82E1148-9F4A-4768-9F98-954265D30D1BQ30363930-0EC82AE0-4E90-4C94-9840-82E4B08131B6Q30928575-5E2F4ED7-569D-4E3E-B3F9-80F275F9B9DAQ33798355-94F88249-7919-40D9-BF19-9B30FD0C7DBAQ35653355-1DFB5BE1-3F7C-4B7D-87D5-FF51067AC1D5Q37412725-81257067-3D35-4C2F-ADB1-BFA7F4F29CDDQ38291663-6E46E258-B78F-476E-8B73-3CCB7D57CAB3Q38809604-0A8240C9-0216-43CB-8951-CF3045345C31Q39445512-2B52BA0A-DC00-4640-9C1E-005468D01034Q40263459-8C36EEA0-F3C7-42CC-B167-A897A130054CQ42653614-EE120BED-6182-4E34-8B1B-71DB4CC02DA0Q44471616-EC36BB63-02F8-4A88-9B0A-1BA95E8D18C6Q45014125-5C86BE55-FFC1-4413-B33D-68667B554275Q46602208-5CC1FF43-518A-4F6A-9C44-C7D2CAD35B9EQ46950702-DFB918FD-2C9B-435A-811A-F7DB51FFE20BQ47394574-54DE7EA9-1F82-44AE-9EAD-6A2FC3C85D01Q47409487-661D212A-B013-4A7C-8A67-1CEBBA33DFBBQ48173680-8270A835-6F5E-4155-8E58-B040A984388EQ48260218-EFF98DF1-C424-4BBE-BEC7-F013B2625471Q50243357-0DABC3F8-5D66-471C-B35D-5B00045F9670Q51739235-1411C162-9016-4F0A-999D-DB0D007E978FQ52651839-BAE12CAF-F382-4205-8688-DB4E1FCB14DDQ53097387-551042C5-0F14-4883-9CFC-F8C4D2C41D6DQ57641718-F72E7CE6-87AB-4C64-9225-50EA78A84B99Q57990864-511F03F2-CB0D-4299-AC01-5D3CADA0CD25Q57990868-697BD60E-E408-4B6B-8042-513454862C63Q57990918-1257AC95-2AE2-463E-9BFE-F7E98EC500D5Q57990921-B90BE5FC-29D8-4AB0-9E21-9C6519FCD5D8Q57990931-6DA3BFEF-9B3A-40D5-A829-3F60A96A9E13Q57991038-A337D349-6D6C-4E33-9DC6-8FB056962A04Q57991041-90D84A51-2C07-47E9-AD3C-3C9B2019B879Q57991043-3234BCFA-9946-40D7-832B-912775B09A77Q60626533-BC21B02C-4724-4BCB-A1A9-1E8E0EC8AE3BQ62721682-825CA863-D4F8-4CB9-8019-1600C9FA22A2Q86624032-6B0894C1-7FC1-4853-9074-E00397E545D5Q88211287-8C15DECE-178C-45CF-8869-516F1B2344AAQ89424566-5294DC09-4564-4F5A-AAC0-0D3841CA399DQ90175088-0DB058C9-C9AD-4872-892C-62BBD8A4F29AQ95278437-AF761724-BDA7-48A6-A904-0F5B6BC7BFD3
P50
description
investigador
@es
researcher
@en
wetenschapper
@nl
name
Natércia Brás
@en
Natércia Brás
@nl
type
label
Natércia Brás
@en
Natércia Brás
@nl
prefLabel
Natércia Brás
@en
Natércia Brás
@nl
P31
P496
0000-0002-3130-9807