about
Close encounters with DNAIon Channels Made from a Single Membrane-Spanning DNA Duplex.Ionic conductivity, structural deformation, and programmable anisotropy of DNA origami in electric fieldLarge-Conductance Transmembrane Porin Made from DNA OrigamiPlasmonic Nanopores for Trapping, Controlling Displacement, and Sequencing of DNA.In meso crystal structure and docking simulations suggest an alternative proteoglycan binding site in the OpcA outer membrane adhesinWater-silica force field for simulating nanodevicesThe effect of calcium on the conformation of cobalamin transporter BtuB.Modeling thermophoretic effects in solid-state nanoporesNanopore Sequencing: Electrical Measurements of the Code of Life.Modeling and simulation of ion channels.Structure refinement of the OpcA adhesin using molecular dynamicsDetection of DNA sequences using an alternating electric field in a nanopore capacitor.Ionic Current Rectification Through Silica NanoporesSynthetic ion channels via self-assembly: a route for embedding porous polyoxometalate nanocapsules in lipid bilayer membranesEnd-to-end attraction of duplex DNA.Molecular dynamics study of MspA arginine mutants predicts slow DNA translocations and ion current blockades indicative of DNA sequence.Toward detection of DNA-bound proteins using solid-state nanopores: insights from computer simulations.In situ structure and dynamics of DNA origami determined through molecular dynamics simulations.Conformational transitions and stop-and-go nanopore transport of single-stranded DNA on charged grapheneSlowing DNA Transport Using Graphene-DNA Interactions.Computer modeling in biotechnology: a partner in development.Interference-Free Detection of Genetic Biomarkers Using Synthetic Dipole-Facilitated Nanopore Dielectrophoresis.Electric and Electrophoretic Inversion of the DNA Charge in Multivalent Electrolytes.Electro-osmotic screening of the DNA charge in a nanoporeExploring transmembrane transport through alpha-hemolysin with grid-steered molecular dynamics.Orientation discrimination of single-stranded DNA inside the alpha-hemolysin membrane channel.Mechanical properties of a complete microtubule revealed through molecular dynamics simulationDeciphering ionic current signatures of DNA transport through a nanopore.A Coarse-Grained Model of Unstructured Single-Stranded DNA Derived from Atomistic Simulation and Single-Molecule Experiment.The electromechanics of DNA in a synthetic nanopore.Surface functionalization of thin-film diamond for highly stable and selective biological interfaces.Smooth DNA transport through a narrowed pore geometry.Rectification of Ion Current in Nanopores Depends on the Type of Monovalent Cations: Experiments and Modeling.Rectification of the current in alpha-hemolysin pore depends on the cation type: the alkali series probed by MD simulations and experimentsControl and reversal of the electrophoretic force on DNA in a charged nanoporeModeling Transport Through Synthetic NanoporesSlowing the translocation of double-stranded DNA using a nanopore smaller than the double helix.Lipid bilayer coated Al(2)O(3) nanopore sensors: towards a hybrid biological solid-state nanopore.Control of Nanoscale Environment to Improve Stability of Immobilized Proteins on Diamond Surfaces.
P50
Q26999396-0019DF49-3E77-47D1-AB7A-513707194486Q27300843-B2584C9E-B5FC-4789-A72A-4CE9E2FF1498Q27334951-45AB8A34-D3C8-41EE-9BEC-8BB25A535FE2Q27340210-7B5AB446-772B-4C1F-A84E-84A6416AA724Q27342143-B4F33CCE-F020-4F36-A371-1F9174E0295CQ27649290-595AEA00-0542-4FF2-BE6E-97BB9D7643EDQ28385301-596D21E1-D729-43D9-B169-9EA51789D913Q30157049-E836B2E8-3356-4911-B293-779899AEE24CQ30397405-39BFB84A-FFF5-4C1A-95A8-2DEFE4FF3171Q30402688-9B2F69BB-B5CC-4D46-951F-321DB490C0D3Q30443341-3FE25152-6D40-4A35-84ED-ECDAECE33595Q30480228-818C6D15-DAA1-4439-828D-1A9EBFEFF6F3Q30484768-C9314F7C-94CE-4AD2-9986-33AAF6C48213Q30486588-9E0EE10B-DDDF-4F6A-8227-DBF0A79D670EQ30494889-E4A763DF-D7BD-4991-8BEE-11E0896CB7CFQ30514058-58EA6EC2-DEAD-42B1-8B11-196216CC1307Q30525176-F8860F0E-81F0-453B-B223-D67099C30378Q30547853-34862644-7C07-435A-BC73-0B08CDF19313Q30559549-EFA25F1C-87F7-46F7-A5E4-D9970F0DF33CQ30599175-4CDCB3F3-1C3D-4585-9C5A-1B48313A7FC0Q30657318-0D96DB0A-4B8B-4F94-98E5-EC692907BAB6Q33386931-5EECE350-B3D3-44AC-AE06-D928A4D761ADQ33709360-DF76838D-8553-402D-98AB-7164F6F3C833Q33913516-71456908-A80A-4E99-B7FA-481E41D7D1BCQ33920271-515AFE98-C88C-4B88-956C-82E9053E4589Q33924818-B6F7101E-2E72-4553-9166-D5EFC49DBB97Q33933830-85F64878-460E-4B96-8AA7-EBFD0F4C3003Q33999440-1EEB216A-962C-41A5-B812-DEF9CD0980E5Q34018554-EFCB04E9-D21E-4035-A167-97E4CD39D419Q34044968-B12DC5E4-04B1-415B-8C14-708FED9FA543Q34353128-A22A8C17-EC50-467E-9152-2B5500FDC625Q34509029-89253EAB-A469-4171-9616-EBC5009C1C61Q34561296-A6A99AAF-F72B-4972-A059-EA82CD3AE82DQ35049011-17B977D2-277B-4667-A3EA-52DF4C0C072FQ35171840-BCBA1393-7B30-48B3-8BEE-AFACDB951B1DQ35176328-B70282FE-8763-464A-B7B7-1495923830BEQ35200908-C9EEB6D6-3EB3-4693-B6B5-9AF39A0303CBQ35206610-869E3E11-5F49-4985-9793-D94583A19CB4Q35219590-887D32FF-321D-4980-907C-EE5C95481DC8Q35225373-45F767C8-B70E-4359-88F3-5E1807B91B5C
P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Aleksei Aksimentiev
@ast
Aleksei Aksimentiev
@en
Aleksei Aksimentiev
@es
Aleksei Aksimentiev
@nl
Aleksei Aksimentiev
@sl
type
label
Aleksei Aksimentiev
@ast
Aleksei Aksimentiev
@en
Aleksei Aksimentiev
@es
Aleksei Aksimentiev
@nl
Aleksei Aksimentiev
@sl
prefLabel
Aleksei Aksimentiev
@ast
Aleksei Aksimentiev
@en
Aleksei Aksimentiev
@es
Aleksei Aksimentiev
@nl
Aleksei Aksimentiev
@sl
P106
P1153
8845324300
P21
P31
P496
0000-0002-6042-8442