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Bioanalysis of eukaryotic organellesAmyloid oligomer neurotoxicity, calcium dysregulation, and lipid raftsCompliance profile of the human cornea as measured by atomic force microscopyImaging of nucleic acids with atomic force microscopy.The applications of atomic force microscopy to vision science.AFM investigations of phase separation in supported membranes of binary mixtures of POPC and an eicosanyl-based bisphosphocholine bolalipidInteractions of borneol with DPPC phospholipid membranes: a molecular dynamics simulation study.Correlating anomalous diffusion with lipid bilayer membrane structure using single molecule tracking and atomic force microscopy.kT-Scale interactions between supported lipid bilayers.Supported membranes embedded with fixed arrays of gold nanoparticlesLung cancer cellular apoptosis induced by recombinant human endostatin gold nanoshell-mediated near-infrared thermal therapy.Bright and photostable push-pull pyrene dye visualizes lipid order variation between plasma and intracellular membranes.Microscopic thin film optical anisotropy imaging at the solid-liquid interface.Colocalization of the ganglioside G(M1) and cholesterol detected by secondary ion mass spectrometry.Biodegradable, Tethered Lipid Bilayer-Microsphere Systems with Membrane-Integrated α-Helical Peptide Anchors.Atomic force microscopy: a tool to study the structure, dynamics and stability of liposomal drug delivery systems.Cryogenic transmission electron microscopy of recombinant tuberculosis vaccine antigen with anionic liposomes reveals formation of flattened liposomes.From simple to complex: investigating the effects of lipid composition and phase on the membrane interactions of biomolecules using in situ atomic force microscopy.A simple guide to biochemical approaches for analyzing protein-lipid interactions.Atomic force microscopy of model lipid membranes.Experimental aspects of colloidal interactions in mixed systems of liposome and inorganic nanoparticle and their applications.Phase transitions in supported lipid bilayers studied by AFM.Nature's lessons in design: nanomachines to scaffold, remodel and shape membrane compartments.Modulation of lipid membrane structural and mechanical properties by a peptidomimetic derived from reduced amide scaffold.Peptide-induced domain formation in supported lipid bilayers: direct evidence by combined atomic force and polarized total internal reflection fluorescence microscopy.Supported lipid bilayer microarrays created by non-contact printing.Topographic analysis by atomic force microscopy of proteoliposomes matrix vesicle mimetics harboring TNAP and AnxA5.Preparation of DOPC and DPPC Supported Planar Lipid Bilayers for Atomic Force Microscopy and Atomic Force Spectroscopy.Lipid Bilayer Membrane in a Silicon Based Micron Sized Cavity Accessed by Atomic Force Microscopy and Electrochemical Impedance Spectroscopy.Atomic Force Microscopy Imaging and Force Spectroscopy of Supported Lipid BilayersThree-Phase Coexistence in Lipid Membranes.Formation of Cell Membrane Component Domains in Artificial Lipid Bilayer.Critical point fluctuations in supported lipid membranes.The molecular mechanism of Nystatin action is dependent on the membrane biophysical properties and lipid composition.Analytical approaches to study domain formation in biomimetic membranes.Substrate Effects on the Formation Process, Structure and Physicochemical Properties of Supported Lipid Bilayers.Antimicrobial Peptides: Interaction With Model and Biological Membranes and Synergism With Chemical Antibiotics.
P2860
Q28384122-CFC07E9F-EE1A-4AE7-9E90-D4E5AC1E0092Q28742804-9BF18C26-A20F-4C81-8E48-8C2C76AB180EQ30446666-6E0C1760-E861-4ECE-9B35-DCCFE6F26FA4Q30467165-C73696C7-CDC7-4F93-9D22-6A85A417464BQ33760294-D68831AC-9876-457E-8BF4-24130C1E0702Q33875997-E98ECFA9-B12E-47B7-93D4-55FCE5400C14Q34685390-368656C5-D279-43E0-85BB-3463E10D007EQ35085489-67E904B2-AA2F-491C-BF2F-6E452758EA1CQ35126815-E8A04AE9-6FA9-4E5C-B4B7-F5AECBD66B3FQ35540461-7C1FF17A-4B99-4BD8-8CD7-3A79019F75A7Q35756373-FE66F649-04F7-48C0-BE07-C411D45CAFB6Q35889747-7D3AABC7-AF05-45A8-973F-FDA3C623AD65Q36004313-46229A4A-18BC-4E11-9818-A1788C7C6475Q36803767-2C20BFE4-33AD-429D-8B7D-BDA61DB59598Q37013586-6F2FA7DA-A87D-4037-A63A-A31A34549CA7Q37425229-C80F4E20-5337-49EA-839C-B73AFBA536A8Q37641676-B2D67CEC-ED28-41F1-ADF5-9EBC0952796BQ37871876-425ADB46-D937-456E-B405-B20349F3B528Q38030903-759813A9-3567-40B5-8E7E-BAE52A46DF59Q38042569-544DCA6B-EA09-4AA5-AF94-D290AB30ABC3Q38056495-47F0421C-3644-4AB0-866C-4B8648533B17Q38236686-A50564B4-E131-495C-B7BF-59F0D7D2D8BFQ38389680-8D992128-FCD5-4072-A736-46C3DA745897Q38993034-8E319440-8806-45D3-A858-5E410B04FB4CQ39343721-EED246F0-5726-4BE6-8547-B1E31E938B59Q39745130-7FC1B220-B9A4-46FF-B75E-73287B905D18Q40197099-1DF5C7A5-B476-4BB1-BB34-B59F2F6F71D2Q41615904-7AA85C14-EFD7-4813-8B49-3CF0C6181C5EQ41663721-961C0E6B-71F1-4E6A-969E-3A6EEB644340Q41770935-40F8F3BB-D19C-4E2B-AECA-87AE06B7BD92Q42641226-48AC1908-0523-451D-8EA2-D637FC74B55EQ47126389-49FCE33D-F2E2-467B-A811-8AAE53FF4BD5Q48719173-AF0B8E33-2E0D-4962-BB06-8488438B1911Q52446250-8B7EDE62-CF38-4929-9C7C-BEC7C782F04DQ52559039-1FBB0DA5-0A0E-43A3-A050-7AF9A2BD2C02Q54711814-2064DB79-7EAC-4F8C-B985-DC500562A7CAQ55252918-DB486AAC-A660-44E7-A010-491C51E6513D
P2860
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 11 September 2008
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
AFM for structure and dynamics of biomembranes.
@en
AFM for structure and dynamics of biomembranes.
@nl
type
label
AFM for structure and dynamics of biomembranes.
@en
AFM for structure and dynamics of biomembranes.
@nl
prefLabel
AFM for structure and dynamics of biomembranes.
@en
AFM for structure and dynamics of biomembranes.
@nl
P2093
P1476
AFM for structure and dynamics of biomembranes.
@en
P2093
Craig D Blanchette
Emel I Goksu
Juan M Vanegas
Marjorie L Longo
Wan-Chen Lin
P304
P356
10.1016/J.BBAMEM.2008.08.021
P407
P577
2008-09-11T00:00:00Z