about
Single molecular mechanics of a cholesterol-bearing pullulan nanogel at the hydrophobic interfaces.Sulfhydryl modification induces calcium entry through IP₃-sensitive store-operated pathway in activation-dependent human neutrophils.Molecular views and measurements of hemostatic processes using atomic force microscopy.Identification and characterization of a PutAMT1;1 gene from Puccinellia tenuifloraElevation of extracellular Ca2+ induces store-operated calcium entry via calcium-sensing receptors: a pathway contributes to the proliferation of osteoblasts.Saline-induced changes of epicuticular waxy layer on the Puccinellia tenuiflora and Oryza sativa leave surfaces.Rhein antagonizes P2X7 receptor in rat peritoneal macrophagesNaCl stress-induced transcriptomics analysis of Salix linearistipularis (syn. Salix mongolica)Nucleotide transmitters ATP and ADP mediate intercellular calcium wave communication via P2Y12/13 receptors among BV-2 microglia.Nitric oxide induces apoptosis associated with TRPV1 channel-mediated Ca(2+) entry via S-nitrosylation in osteoblasts.Self-assembling study of sarcolipin and its mutants in multiple molecular dynamic simulations.Multiple calcium patterns of rat osteoblasts under fluidic shear stress.AFM study of the differential inhibitory effects of the green tea polyphenol (-)-epigallocatechin-3-gallate (EGCG) against Gram-positive and Gram-negative bacteria.Biomembrane mimetic polymer poly (2-methacryloyloxyethyl phosphorylcholine-co-n-butyl methacrylate) at the interface of polyurethane surfaces.Temperature-induced labelling of Fluo-3 AM selectively yields brighter nucleus in adherent cells.Transmembrane dynamics of the Thr-5 phosphorylated sarcolipin pentameric channel.Molecular dynamics of water and monovalent-ions transportation mechanisms of pentameric sarcolipin.A multishear microfluidic device for quantitative analysis of calcium dynamics in osteoblastsVisualization of the algal polysaccharide carrageenan by scanning tunnelling microscopyForce measurements on platelet surfaces with high spatial resolution under physiological conditionsBiphasic transitions of a hairpin hexanucleotide triplex DNAReal-time observations of mechanical stimulus-induced enhancements of mechanical properties in osteoblast cellsInfluence of loop sequence on relative stability of bimolecular triplex DNAMagnetic fields at extremely low-frequency (50 Hz, 0.8 mT) can induce the uptake of intracellular calcium levels in osteoblastsChanges of cationic transport in AtCAX5 transformant yeast by electromagnetic field environments
P50
Q31048255-0C8006B2-1939-498F-8C87-53FC4F3A6D8CQ34044854-5247973D-F4E1-4A45-8538-36D36B1904FDQ34790576-890A464B-5F81-44D9-88BD-73481C9B84BDQ35067975-3C39CFCF-D6FE-44B0-8060-EEB8DD1ED84CQ35276368-C50EBEFA-80AA-471B-B18E-F694A1676F26Q35679212-055F741C-7AD6-475D-B610-AD9FA3472C27Q36044621-C22259A6-34D2-43AB-84E9-C6441B1A5458Q36634150-148161A5-8A76-412E-90AD-D1F05624B7B3Q41361968-99CEFE99-F215-4677-8C56-7BF076FA1F6EQ44323163-943A80C0-4582-405D-BA5A-1C96547A773FQ48046292-5BD11E17-5087-4446-A625-9434448BABDAQ50135945-492333FE-18C4-4D47-9AFC-53B62DD82DDEQ50509159-8461487B-08EB-4910-8934-6478B258BAB3Q51066521-25CC6EEE-7015-47A5-8BC2-DBA35233F4C7Q51127379-10A21E04-09B2-4562-882A-C6A3E62595CCQ51663759-A7FBED66-213D-452C-BF3C-AEC792D88A48Q53455831-3A43D544-AFB3-4B16-973D-C29CF9283801Q57635764-045295C3-463C-4AFE-9356-5D29DB8F3277Q67565285-4CD98BE4-FD95-4581-A5BB-38860CA299A8Q73154780-37D8922D-4E72-49B4-9687-091A3F343248Q79213683-5521B60F-6136-454E-94DA-A1751D0D201DQ81702914-188E209C-D1D6-4670-94EF-6D4E16CD550DQ81825824-D7E855B4-9204-42B9-92D6-1325ECBD1301Q84149509-FB78D205-02A4-488D-B8B7-78D0B9FB1FA0Q89037208-FC87C1CB-5291-4EDF-803F-7993F912087F
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Imshik Lee
@ast
Imshik Lee
@en
Imshik Lee
@es
Imshik Lee
@nl
Imshik Lee
@sl
type
label
Imshik Lee
@ast
Imshik Lee
@en
Imshik Lee
@es
Imshik Lee
@nl
Imshik Lee
@sl
prefLabel
Imshik Lee
@ast
Imshik Lee
@en
Imshik Lee
@es
Imshik Lee
@nl
Imshik Lee
@sl
P1053
G-6129-2010
P106
P31
P3829
P496
0000-0002-0098-392X