Differential detection of dual traps improves the spatial resolution of optical tweezers - Test2 - elhamkhani - TriplyDB

Differential detection of dual traps improves the spatial resolution of optical tweezers

Differential detection of dual traps improves the spatial resolution of optical tweezers

http://www.wikidata.org/entity/Q24548494

about

Single-molecule force spectroscopy: optical tweezers, magnetic tweezers and atomic force microscopy MspA nanopore as a single-molecule tool: From sequencing to SPRNT Protein structure. Direct observation of structure-function relationship in a nucleic acid-processing enzyme Characterization of wet-heat inactivation of single spores of bacillus species by dual-trap Raman spectroscopy and elastic light scattering.High-resolution optical tweezers for single-molecule manipulation.Intersubunit coordination in a homomeric ring ATPase.Single molecule transcription elongation.Force unfolding kinetics of RNA using optical tweezers. II. Modeling experiments.High-resolution, single-molecule measurements of biomolecular motion.Ultrahigh-resolution optical trap with single-fluorophore sensitivity.Nanophotonic trapping for precise manipulation of biomolecular arrays.Single molecule techniques in DNA repair: a primer Interference and crosstalk in double optical tweezers using a single laser source.Precision surface-coupled optical-trapping assay with one-basepair resolution.Full distance-resolved folding energy landscape of one single protein molecule.Single-molecule fluorescence and in vivo optical traps: how multiple dyneins and kinesins interact Folding and unfolding single RNA molecules under tension.Free-energy inference from partial work measurements in small systems.Common intermediates and kinetics, but different energetics, in the assembly of SNARE proteins.The complex folding network of single calmodulin molecules.Single reconstituted neuronal SNARE complexes zipper in three distinct stages.Mechanisms of cellular proteostasis: insights from single-molecule approaches The evolution of nanopore sequencing.Practical axial optical trapping Revisiting the central dogma one molecule at a time.Forcing a connection: impacts of single-molecule force spectroscopy on in vivo tension sensing.The RSC chromatin remodelling ATPase translocates DNA with high force and small step size.Real-time monitoring of DNA polymerase function and stepwise single-nucleotide DNA strand translocation through a protein nanopore Optical tweezers study life under tension Axial Optical Traps: A New Direction for Optical Tweezers.Focal Adhesion Induction at the Tip of a Functionalized Nanoelectrode.Kinetically coupled folding of a single HIV-1 glycoprotein 41 complex in viral membrane fusion and inhibition.Step length measurement--theory and simulation for tethered bead constant-force single molecule assay Single-molecule observation of helix staggering, sliding, and coiled coil misfolding.Selective modification of nanoparticle arrays by laser-induced self assembly (MONA-LISA): putting control into bottom-up plasmonic nanostructuring.Nascent RNA structure modulates the transcriptional dynamics of RNA polymerases.Biocompatible and High Stiffness Nanophotonic Trap Array for Precise and Versatile Manipulation Single-molecule biophysics: at the interface of biology, physics and chemistry High-Resolution Optical Tweezers Combined With Single-Molecule Confocal Microscopy.Combined versatile high-resolution optical tweezers and single-molecule fluorescence microscopy

P2860

Q24631831-8A1309EC-BF9B-4D13-95B8-C1B7D1F15ABB Q26752452-8E943567-0A28-43A2-AE61-94206EF10EC1 Q30373812-298DD77E-AB3A-4106-861A-625691F1A197 Q30384787-DFDBEFFF-11EE-4CEE-87AC-27B8B7EEA386 Q30449157-F7BBA06D-A9FC-49DB-A0BF-AA55A33F8FCC Q30489077-AD8352F7-53F6-4A54-8A83-14222B454223 Q30491199-6C5F7747-4C40-4441-9603-6644C85CF12C Q30494669-CA3E5737-6413-4509-93BE-829FCF1C3417 Q30501806-ED09B236-C2C5-463F-AE6F-BE5133BF5DBB Q30542090-6CA62E1E-79DB-43FD-8B23-663226E0C48E Q30580045-715EA0CD-6D3A-48C5-BFEC-5630BE1043E0 Q30829969-3C7A51A7-31C2-4AE0-B7BE-9374AC859ADB Q33388303-D833CBF5-C98B-4D20-A0C9-E2F17301C128 Q33427243-D7D7B76C-AAD7-4DDC-8079-139A51A8F270 Q33719574-32905CF4-1CE5-4716-A7E8-495032919CF0 Q33727357-98E7D6E8-4648-4391-AAFD-03675E073518 Q33791724-4D7E08C0-4DA7-4254-B34F-805234129580 Q34083017-C3D6037A-5B33-4DBE-942A-43DC43DFD789 Q34196813-8863D0C5-7AE5-42CA-969F-2366218AB168 Q34228218-EC2B7E5D-A33A-4274-B520-E2ECB87A8E72 Q34294781-E985108D-D92D-498E-A2FC-08B492423D7F Q34422820-9FB7E657-7FD0-41A2-BD50-1487A01183BF Q34459110-8328C1CF-130B-4F07-9C30-A1F3876D858A Q34466961-CB1A4C5E-7638-4A47-B3ED-1A13A231201D Q34711713-A2BCE854-5E25-4CB2-9D13-7746EBF1BB32 Q34990311-5510A12B-5FD9-437F-AB51-DE966BC4C0E6 Q35048885-7A6C1CC1-E00D-45D9-8F26-BF2EAFC06803 Q35093077-2C538541-C08D-4109-94E7-BE6B79802F5C Q35588297-98F92541-D399-4AA5-9F1B-9233E0119B04 Q35666392-7FAEBB71-CAD5-4AF2-8B3E-76A33063857E Q35667914-F6F4B94D-3D69-47D5-8D87-574238708047 Q35699218-7C40BB3C-F246-4E71-BD6E-9B515138D525 Q35878666-31145187-AADB-4ED3-9FC8-284E8A5BEF81 Q35889460-4ECD7188-4D6C-4ED7-9C13-AB3F25F9664A Q35975248-A349137F-14E4-4A18-BE44-3823C0184594 Q36061367-49F660AB-429A-4E01-9935-A6FEDD3AD87A Q36149614-60F59B49-88F4-4214-A0D0-1A72B6D4C1E4 Q36170041-DF096784-DFAB-460D-8091-448C105FE097 Q36243432-D82049C3-A47C-4AEE-B5F2-ECF9A2FB046E Q36300611-78A1E9CB-D67E-467A-8360-8041DF6CCF1C

P2860

Differential detection of dual traps improves the spatial resolution of optical tweezers

http://www.wikidata.org/entity/Q24548494

description

2006 nî lūn-bûn

@nan

2006 թուականի Յունիսին հրատարակուած գիտական յօդուած

@hyw

2006 թվականի հունիսին հրատարակված գիտական հոդված

@hy

2006年の論文

@ja

2006年論文

@yue

2006年論文

@zh-hant

2006年論文

@zh-hk

2006年論文

@zh-mo

2006年論文

@zh-tw

2006年论文

@wuu

name

Differential detection of dual traps improves the spatial resolution of optical tweezers

@ast

Differential detection of dual traps improves the spatial resolution of optical tweezers

@en

Differential detection of dual traps improves the spatial resolution of optical tweezers

@nl

type

label

Differential detection of dual traps improves the spatial resolution of optical tweezers

@ast

Differential detection of dual traps improves the spatial resolution of optical tweezers

@en

Differential detection of dual traps improves the spatial resolution of optical tweezers

@nl

prefLabel

Differential detection of dual traps improves the spatial resolution of optical tweezers

@ast

Differential detection of dual traps improves the spatial resolution of optical tweezers

@en

Differential detection of dual traps improves the spatial resolution of optical tweezers

@nl

P1433

Q24548494-044CEBB0-20CE-42CD-BCE1-8FA608EE015F

P1476

Q24548494-12EBE0B5-A1CC-48C0-AD40-789EBE7D9BC0

P2093

Q24548494-BE429289-D2F2-43A9-AA5F-6AF0663533C9

Q24548494-C1265CB2-05A8-4DB6-B497-2F173D693F3B

P2860

Q24548494-12D7CD26-AED3-4987-8B06-19C772171F83

Q24548494-18BFD0A4-0EC5-4425-8BDE-FDB951DF2E63

Q24548494-22413E4C-CAE8-4916-B58C-5F301C51DF7E

Q24548494-389919B2-A410-4D28-AA58-CDF83C1C0CD9

Q24548494-39D98DF8-835D-4EF8-AF11-300F60308964

Q24548494-3FF6800A-CE46-4E5E-B857-9E2ABE1E8CBE

Q24548494-421718BD-B624-4C3F-8A33-DD11DF5AE3AF

Q24548494-48361285-22AB-456A-9A43-6B5F1EB1EA3A

Q24548494-5EAC8476-769E-4D16-898A-93531645CF08

Q24548494-6076DA0F-98AB-485D-A66C-1D15C897BB5C

P304

Q24548494-D6A16B40-41A9-4C0A-8BAF-4E9D09C34FEC

P31

Q24548494-AE3AEE77-6085-4CF4-B8AB-B4CB3757BCD6

P3181

Q24548494-A0B505C0-D749-4828-9BC0-936B5AC911C8

P356

Q24548494-EADC7EEE-8D27-48E0-BEE2-70CF5763E555

P407

Q24548494-38FC4BC7-7310-4DAD-8064-18BA550B610E

P433

Q24548494-8A9F90ED-72AB-460B-A8E3-A3738331E0CF

P478

Q24548494-70C13405-0E20-40B0-954B-5E77170D15E1

P50

Q24548494-0C8A00DA-1FE3-473E-A101-51C65B569C16

Q24548494-8757FCBE-ACE0-46E4-B2CA-D8C5E583B71C

P577

Q24548494-71585A48-13A1-4818-80B0-5DC833E0B8CC

P5875

Q24548494-7C101A05-7A5D-411D-8DB7-3C3D1028FA12

P698

Q24548494-1B8D263A-F4E8-487C-9373-CE8741FEB5A4

P921

Q24548494-E568F2EB-997B-4ACC-BB40-115614655242

P932

Q24548494-5A7D1A0E-ED3A-46B1-8E8A-4338AEF1F830

P3181

P356

PNAS.0603342103

P1433

Proceedings of the National Academy of Sciences of the United States of America

P1476

Differential detection of dual traps improves the spatial resolution of optical tweezers

@en

P2093

David Izhaky

http://www.w3.org/2001/XMLSchema#string

Jeffrey R Moffitt

http://www.w3.org/2001/XMLSchema#string

P2860

Direct observation of base-pair stepping by RNA polymerase

Verification of the Crooks fluctuation theorem and recovery of RNA folding free energies

Experimental Demonstration of Violations of the Second Law of Thermodynamics for Small Systems and Short Time Scales

Stretching DNA with optical tweezers.

Entropic elasticity of lambda-phage DNA

Mechanical processes in biochemistry

Single-molecule biomechanics with optical methods.

Correlated motions of two hydrodynamically coupled particles confined in separate quadratic potential wells.

Versatile optical traps with feedback control.

Interference model for back-focal-plane displacement detection in optical tweezers.

P304

9006-11

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P3181

3392042

http://www.w3.org/2001/XMLSchema#string

P356

10.1073/PNAS.0603342103

http://www.w3.org/2001/XMLSchema#string

P407

P433

24

http://www.w3.org/2001/XMLSchema#string

P478

103

http://www.w3.org/2001/XMLSchema#string

P50

Carlos Bustamante

P577

2006-06-13T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P5875

7032226

http://www.w3.org/2001/XMLSchema#string

P698

16751267

http://www.w3.org/2001/XMLSchema#string

P921

optical tweezers

P932

1482556

http://www.w3.org/2001/XMLSchema#string