about
Toward one-step point-of-care immunodiagnostics using capillary-driven microfluidics and PDMS substrates.Screening cell surface receptors using micromosaic immunoassays.Autonomous capillary system for one-step immunoassays.Protein tethering into multiscale geometries by covalent subtractive printing.Large-scale arrays of aligned single viruses.Microfluidics in the "open space" for performing localized chemistry on biological interfaces.Overflow microfluidic networks for open and closed cell cultures on chip.Controlled deposition of cells in sealed microfluidics using flow velocity boundaries.A vertical microfluidic probe.Diffusion of alkanethiols in PDMS and its implications on microcontact printing (muCP).Simultaneous detection of C-reactive protein and other cardiac markers in human plasma using micromosaic immunoassays and self-regulating microfluidic networks.Overflow microfluidic networks: application to the biochemical analysis of brain cell interactions in complex neuroinflammatory scenarios.Controlled particle placement through convective and capillary assembly.Cellular microarrays for use with capillary-driven microfluidics.Capillary soft valves for microfluidics.Micro-immunohistochemistry using a microfluidic probe.Capillary-driven multiparametric microfluidic chips for one-step immunoassays.Controlled release of reagents in capillary-driven microfluidics using reagent integrators.A microfluidic device for depositing and addressing two cell populations with intercellular population communication capability.Capillary pumps for autonomous capillary systems.Continuous flow in open microfluidics using controlled evaporation.High-sensitivity miniaturized immunoassays for tumor necrosis factor alpha using microfluidic systems.A bead-based immunogold-silver staining assay on capillary-driven microfluidics.Facile Preparation of Complex Protein Architectures with Sub-100-nm Resolution on SurfacesFabricating Arrays of Single Protein Molecules on Glass Using Microcontact PrintingPatterned delivery of immunoglobulins to surfaces using microfluidic networksMicromosaic immunoassaysAffinity capture of proteins from solution and their dissociation by contact printingPositive microcontact printingAutonomous microfluidic capillary systemSelf-assembled microarrays of attoliter molecular vesselsHigh-performance immunoassays based on through-stencil patterned antibodies and capillary systemsMultipurpose microfluidic probeMicrocontact printing of proteins inside microstructuresModeling and optimization of high-sensitivity, low-volume microfluidic-based surface immunoassaysMicrofluidic chips for point-of-care immunodiagnosticsHigh-grade optical polydimethylsiloxane for microfluidic applicationsFlock-based microfluidicsHigh-Content Optical Codes for Protecting Rapid Diagnostic Tests from CounterfeitingProgrammable hydraulic resistor for microfluidic chips using electrogate arrays
P50
Q30881306-87B1E31D-2E8F-4C89-9C06-DDF4B2F8286BQ33264467-1FDFDE01-7DF5-4224-A91A-F80167D16DBBQ33371238-BF6052B2-5A59-47EB-9E02-9D71FB0DA5C8Q35090323-2EE09F57-E613-46E6-B864-C35E7B8D1F91Q37018254-D8159EFD-9230-4249-B137-8EF71EF923C7Q38056670-34773322-D043-425C-8C0C-81CA71847CD3Q39714933-20E58489-2AC7-4A51-9113-A8D278D081DDQ39856249-58CFC900-19F6-4D63-8036-FCFA65DD6B6EQ42812023-0ADD0F1E-4CCD-49B7-92C8-F7774993172AQ45217979-C1A3065F-3847-4B0F-9674-A2F134EEF469Q47874721-963A67D2-925E-441A-90D2-FB2D57735A13Q48323350-668351B7-36F6-4B88-ADE7-B0F18E435D68Q50898897-A2163667-113C-4AE9-9CBC-2E8D217EFFC8Q50955379-5EEFAC3F-EF4F-41CB-9DD7-907DE92F4764Q51540381-4D020C99-14DC-42E3-98F6-D21FE107AB9FQ51542890-CB2091E2-9501-441E-BF53-12E82CEC4202Q51547403-5F87D1FE-6749-4F89-A1E6-9EE74B5B0151Q51548141-CE289D1F-FAA9-4E42-8FD3-BE27AAE85953Q51561740-FEC79896-8ECD-4217-B610-C67EC1221BC5Q51582560-138C0D3A-D21C-4270-9279-F6C3D17DF13CQ51590047-DE87E402-0982-4D45-AFA2-5959A1AD710BQ51594814-ECD9FB63-1D7F-48F8-ADEB-D76CE4359FC0Q54204820-DE4FC079-32D1-4AD3-B84A-078B7850AB39Q59664118-6547CDD3-7356-410C-B623-2A149753B8FFQ62044219-5E1610F5-2D9D-4E20-9A5F-815CD2BA4200Q73257751-9BA3307B-0D64-4EAE-A922-02CAC1FB09E9Q73481250-ADB3B05F-D053-41CF-B975-2B8C3F19D5FDQ74455243-B57F43D8-6B84-462D-9EF7-6A0F0F164D7BQ77906959-E49D3F37-5DA5-4BEC-9A8C-1B867E60DA02Q78742685-7F1EA652-4242-4E7C-AA26-54A3D8FA96BDQ79324965-E0251C31-448B-4BB4-9584-5D7E0084958CQ80600394-36013165-FAE3-435A-A830-1E322E2DC62DQ80927182-4351ECF3-4700-4016-9291-181ABAB074BFQ81475927-25ACAB29-6266-443B-A7ED-938BD9414B5CQ81820846-464F42BA-69A8-4A33-9131-D0FE7F1B1BD8Q84090923-1BC8D9D2-615D-434E-AC2A-DE2C25E51B0AQ84590249-71572E0A-6EAB-4502-9AB7-054C76EDABA5Q86145784-BDA20D8A-B750-4ACE-ABD9-78BC2E8B4A92Q89039167-ACF5F13C-5CAA-4745-B6A4-FA1D26E8CABCQ91386786-3700241C-6D9C-4EDE-B3B3-5D5BC8D205E2
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Emmanuel Delamarche
@ast
Emmanuel Delamarche
@en
Emmanuel Delamarche
@es
Emmanuel Delamarche
@nl
Emmanuel Delamarche
@sl
type
label
Emmanuel Delamarche
@ast
Emmanuel Delamarche
@en
Emmanuel Delamarche
@es
Emmanuel Delamarche
@nl
Emmanuel Delamarche
@sl
prefLabel
Emmanuel Delamarche
@ast
Emmanuel Delamarche
@en
Emmanuel Delamarche
@es
Emmanuel Delamarche
@nl
Emmanuel Delamarche
@sl
P1053
G-6342-2013
P106
P31
P3829
P496
0000-0002-8753-8895