Fingerprinting polysaccharides with single-molecule atomic force microscopy.
about
Potential role of atomic force microscopy in systems biologyChair-boat transitions in single polysaccharide molecules observed with force-ramp AFM.Direct detection of the formation of V-amylose helix by single molecule force spectroscopy.Sub-angstrom conformational changes of a single molecule captured by AFM variance analysis.Print your atomic force microscope.Equilibrium sampling for biomolecules under mechanical tensionSelf-assembly of polysaccharides gives rise to distinct mechanical signatures in marine gels.Cooperativity in forced unfolding of tandem spectrin repeatsThe force-driven conformations of heparin studied with single molecule force microscopy.Molecular dynamics simulations of forced conformational transitions in 1,6-linked polysaccharides.The effects of beta-glucan on human immune and cancer cells.New trends in food processing.Can Dissipative Properties of Single Molecules Be Extracted from a Force Spectroscopy Experiment?Nanoscale structural and mechanical properties of nontypeable Haemophilus influenzae biofilmsA transformation for the mechanical fingerprints of complex biomolecular interactions.Adsorbed gels versus brushes: viscoelastic differences.Single molecule mechanical manipulation for studying biological properties of proteins, DNA, and sugars.Decoding the mechanical fingerprints of biomolecules.Pyranose ring conformations in mono- and oligosaccharides: a combined MD and DFT approach.Demonstration of specific binding of heparin to Plasmodium falciparum-infected vs. non-infected red blood cells by single-molecule force spectroscopy.Atomic force microscopy of the morphology and mechanical behaviour of barnacle cyprid footprint proteins at the nanoscale.Optical response of magnetic fluorescent microspheres used for force spectroscopy in the evanescent field.A live bioprobe for studying diatom-surface interactions.Extended, relaxed, and condensed conformations of hyaluronan observed by atomic force microscopy.Frequency modulation atomic force microscopy reveals individual intermediates associated with each unfolded I27 titin domainDiatom adhesive mucilage contains distinct supramolecular assemblies of a single modular protein.Insights into the potential functionality of single-chain force-induced conformational transitions in polymer networks: implications for polysaccharide signaling in the plant cell wall.Inferring the diameter of a biopolymer from its stretching response.Investigation of the effects of fine structure on the nanomechanical properties of pectin.Pulling angle-dependent force microscopy.Theory of Biopolymer Stretching at High Forces.Getting the feel of food structure with atomic force microscopy.Stretching Response of Knotted and Unknotted Polymer Chains.
P2860
Q28652634-B8E6DB77-39CF-4AF8-B885-B217A68D1BB2Q31045547-A0F65292-9DF6-4B3C-BB4F-C136F6D476A1Q31049025-E9A33464-8C86-4C86-B38D-8D8135F81803Q33234746-84490244-29E3-43CD-8A50-9650761E5CA9Q33292893-9B685CB6-739D-423A-A266-B3DC67CAB7DBQ33531589-3EDEDC80-26AC-490B-8EE6-77DFD2C57393Q33922330-A5FF50DC-1125-448A-A110-F612A1887CD7Q34180220-80BEE185-A152-48D2-815F-22553A8DD0F7Q34183216-EDB42BC7-7046-40CD-97E3-E9AA4F0A5952Q34186966-98163670-2664-4A8B-8BA0-EDA3DDAD8F1FQ34608777-B345A48C-9A29-48FE-953B-E6119CB93FF8Q35599505-99D893F5-74CB-4B9A-8CF2-8DB063538392Q36139466-3F8EC88A-3D10-4516-B658-5309D10B1995Q37157000-D7C03B14-EC10-4C05-AE6B-B0E68AEC0E28Q37236421-1B0F9D3A-A241-4D70-A0B5-6235CAC6B392Q37636096-AE3D721E-CD33-433A-B3F3-0C0B73518A87Q38172064-79876DC6-FCAB-40FC-B862-963A91D4FC03Q38615789-6D2B29C4-3F3C-4444-A8B0-D8F6EC3AEA8CQ38663158-9055A3F9-FA32-4131-9FF5-61053250165CQ39212819-2173C243-33A6-4504-ABB7-1D473798C5E4Q39722275-A72AF685-37D1-4EA4-B93C-BC60B4F6D7DBQ39871586-B763E110-7313-4BBC-AEB1-A0E0261F8D06Q40309338-79AA922B-6FC9-44CE-B3C3-106412D236D5Q40312854-BA3D4BC7-5984-47F8-90C4-F1503BF1051BQ41853644-70FCCF2D-202A-4FBD-A570-FE7B1B93A110Q42067845-863D6192-8AAF-4403-97AA-D6212673486AQ42758022-761303BD-DE5C-485D-BBB2-1E1B079906BBQ42960902-88B49927-5DDA-4B4D-B778-24EF9D906DEDQ46955280-2E6EFC7A-9BEB-49CE-A5D2-70B8CE53E703Q48042870-1AF0871B-CEEA-411B-9ABB-9B08AFE6E055Q49259405-C42E344C-782D-46EC-BCB7-4E61C843381AQ53068930-B7D290CB-C547-43F1-A46C-73D1FE0FDA38Q53431858-2B54439B-53FA-4D85-9235-6EE0FF0325A2
P2860
Fingerprinting polysaccharides with single-molecule atomic force microscopy.
description
2001 nî lūn-bûn
@nan
2001 թուականի Մարտին հրատարակուած գիտական յօդուած
@hyw
2001 թվականի մարտին հրատարակված գիտական հոդված
@hy
2001年の論文
@ja
2001年論文
@yue
2001年論文
@zh-hant
2001年論文
@zh-hk
2001年論文
@zh-mo
2001年論文
@zh-tw
2001年论文
@wuu
name
Fingerprinting polysaccharides with single-molecule atomic force microscopy.
@ast
Fingerprinting polysaccharides with single-molecule atomic force microscopy.
@en
type
label
Fingerprinting polysaccharides with single-molecule atomic force microscopy.
@ast
Fingerprinting polysaccharides with single-molecule atomic force microscopy.
@en
prefLabel
Fingerprinting polysaccharides with single-molecule atomic force microscopy.
@ast
Fingerprinting polysaccharides with single-molecule atomic force microscopy.
@en
P356
P1433
P1476
Fingerprinting polysaccharides with single-molecule atomic force microscopy.
@en
P2093
J M Fernandez
P E Marszalek
P2888
P304
P356
10.1038/85712
P50
P577
2001-03-01T00:00:00Z