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Kinesin Kip2 enhances microtubule growth in vitro through length-dependent feedback on polymerization and catastrophe.Optical trapping of coated microspheres.The distribution of active force generators controls mitotic spindle position.Optical tweezers with millikelvin precision of temperature-controlled objectives and base-pair resolution.Measuring the complete force field of an optical trap.Under-filling trapping objectives optimizes the use of the available laser power in optical tweezers.Contact line dynamics near the pinning threshold: a capillary rise and fall experimentCapillary instabilities by fluctuation induced forces.A Single-Strand Annealing Protein Clamps DNA to Detect and Secure HomologyThe growth speed of microtubules with XMAP215-coated beads coupled to their ends is increased by tensile force.Microtubule dynamics reconstituted in vitro and imaged by single-molecule fluorescence microscopy.Enzyme-Powered Hollow Mesoporous Janus Nanomotors.The Kinesin-8 Kip3 switches protofilaments in a sideward random walk asymmetrically biased by force.Kinesin-8 is a low-force motor protein with a weakly bound slip state.Developmentally Regulated GTP binding protein 1 (DRG1) controls microtubule dynamics.Protein friction limits diffusive and directed movements of kinesin motors on microtubules.Measuring Microtubule Supertwist and Defects by Three-Dimensional-Force-Clamp Tracking of Single Kinesin-1 Motors.Kinesin rotates unidirectionally and generates torque while walking on microtubules.Molecular forces caused by the confinement of thermal noise.LED illumination for video-enhanced DIC imaging of single microtubules.Functional surface attachment in a sandwich geometry of GFP-labeled motor proteins.Implementation and Tuning of an Optical Tweezers Force-Clamp Feedback System.Inertial effects of a small Brownian particle cause a colored power spectral density of thermal noise.Surface forces and drag coefficients of microspheres near a plane surface measured with optical tweezers.Custom-Made Microspheres for Optical Tweezers.Calibration of optical tweezers with positional detection in the back focal planeDynamic domain formation in membranes: Thickness-modulation-induced phase separationInfluence of Enzyme Quantity and Distribution on the Self-Propulsion of Non-Janus Urease-Powered MicromotorsLED-based interference-reflection microscopy combined with optical tweezers for quantitative three-dimensional microtubule imagingLED-based interference-reflection microscopy combined with optical tweezers for quantitative three-dimensional single microtubule imagingDetermination of pitch rotation in a spherical birefringent microparticlePhragmoplast Orienting Kinesin 2 Is a Weak Motor Switching between Processive and Diffusive ModesImproved antireflection coated microspheres for biological applications of optical tweezersNanonewton optical force trap employing anti-reflection coated, high-refractive-index titania microspheresSeeded Growth of Titania Colloids with Refractive Index Tunability and Fluorophore-Free LuminescenceBreaking of bonds between a kinesin motor and microtubules causes protein frictionCoated microspheres as enhanced probes for optical trappingSelf-organized organic nanostructures: structure formation in thin polymer blend filmsAspects of electrohydrodynamic instabilities at polymer interfacesHierarchical structure formation and pattern replication induced by an electric field
P50
Q27931170-FC9A72CB-E988-4C7E-8768-C9ADDC60F361Q30847610-602DC28D-D2F4-48C1-B687-A8213602645BQ31150806-3C0594E0-56D2-4B09-A452-B9BB4A5D79ADQ33505545-77382C9C-CE77-4C02-AED5-855286559E73Q33867162-C743A266-00CA-4DD0-9DCB-838858C80A9BQ33946420-901F2083-42DC-4C3F-B0A8-B151A1F36D33Q34059888-458354D5-B2FA-4F64-A2EB-D8F6A1B5ECC0Q35685258-7DB83484-19F8-448F-A67F-59EF194A44E3Q35745189-112EC5A5-833E-46DC-9341-58D2A19BC632Q37157351-458649AA-3A4F-4084-AC14-BA18DB6E569AQ37751194-3F254ED7-3AC9-41FC-A276-6333766566C2Q38956646-0A1A37FA-DEE6-496C-8C66-2239CC76E9D2Q39893360-86C23639-379A-491B-BFD2-2ACA7F21A2ADQ41542011-B212F516-8B96-48A2-999B-A8BCD7760045Q41565226-1B0BBB6F-0A02-479B-9896-1D5449CAAD3EQ43292289-9A0EB055-8294-46B6-9FA0-3E1CBBDA56D1Q48043206-3E73A1D1-1DA1-49CE-8B29-584F1C212A67Q48052558-C803BE37-3098-4D9B-8F7B-FD6A3C9058DAQ49253363-78D0D979-F070-43F2-8FA5-1F1332EF5A94Q50470609-B603EBDB-BCC2-4EF3-A415-215CB3810077Q50515084-D32ED6A7-9E84-42BB-925A-2F8DAEA3D7BAQ50548386-EC6F8F47-868C-47F6-8850-B6608811973FQ50667578-17192BEF-7D8D-4D49-8E97-5DE2479DDEA6Q51059706-DA26CE26-E9C0-41BE-8E18-304A17640CC0Q51065424-0BBBD464-F807-4A4D-B792-2B0DFB50C194Q57252571-9899C661-00F9-4300-925F-68BC49438889Q57374597-A05FE0F4-0F6A-45D4-AD3B-461EC349B079Q58811684-B425D653-CFDF-4405-8A79-CA9F8E5CD0BFQ58811686-5C03DBBD-9BB0-4C65-98C4-7C3B240AF146Q58811687-5BA4D489-73EC-4FA5-A08B-2F6837C7E419Q58811689-35B2B4F4-A44E-4107-BBF9-98F6ECD46CD2Q58811691-D2AA7E25-BEEC-492F-ABAA-A55A0E87E59DQ58811697-D5F9471D-E5E6-4948-8A67-7994983ED3E5Q58811698-C126B15B-9749-45A5-94C7-000D37DA8E76Q58811699-18E78424-02B9-46EE-91CA-DCA8E5C77114Q58811701-23E5E03E-203B-4487-A36D-4F8848B7B89FQ58811703-E0EB537C-3148-409C-B8A5-83A00AEBF7DEQ58811707-D41AB762-1DED-4395-9D44-E88B83098EBFQ58811709-F4F4D2E9-C877-48DF-A280-7780129252ABQ58811710-063F680A-80A6-4330-A804-A6AA5AE8D799
P50
description
hulumtues
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Erik Schäffer
@ast
Erik Schäffer
@en
Erik Schäffer
@es
Erik Schäffer
@nl
Erik Schäffer
@sl
type
label
Erik Schäffer
@ast
Erik Schäffer
@en
Erik Schäffer
@es
Erik Schäffer
@nl
Erik Schäffer
@sl
prefLabel
Erik Schäffer
@ast
Erik Schäffer
@en
Erik Schäffer
@es
Erik Schäffer
@nl
Erik Schäffer
@sl
P1053
A-4664-2010
P106
P21
P31
P3829
P496
0000-0001-7876-085X