Using microfluidics to observe the effect of mixing on nucleation of protein crystals.
about
Reactions in droplets in microfluidic channels.The plug-based nanovolume Microcapillary Protein Crystallization System (MPCS)User-loaded SlipChip for equipment-free multiplexed nanoliter-scale experimentsMultiparameter screening on SlipChip used for nanoliter protein crystallization combining free interface diffusion and microbatch methods.Protein crystallization in drug design: towards a rational approach.Rate of mixing controls rate and outcome of autocatalytic processes: theory and microfluidic experiments with chemical reactions and blood coagulation.Using nanoliter plugs in microfluidics to facilitate and understand protein crystallization.Capillary electrophoresis separation in the presence of an immiscible boundary for droplet analysisUsing three-phase flow of immiscible liquids to prevent coalescence of droplets in microfluidic channels: criteria to identify the third liquid and validation with protein crystallizationLocal heating of discrete droplets using magnetic porous silicon-based photonic crystals.Protein Crystallization in an Actuated Microfluidic Nanowell Device.The effect of protein-precipitant interfaces and applied shear on the nucleation and growth of lysozyme crystalsFabrication of advanced particles and particle-based materials assisted by droplet-based microfluidics.Enhancing protease activity assay in droplet-based microfluidics using a biomolecule concentrator.Simultaneous generation of multiple aqueous droplets in a microfluidic device.Droplet growth and transition to coalescence in confined geometriesOn-chip titration of an anticoagulant argatroban and determination of the clotting time within whole blood or plasma using a plug-based microfluidic systemVisualizing millisecond chaotic mixing dynamics in microdroplets: A direct comparison of experiment and simulation.Controlling one protein crystal growth by droplet-based microfluidic system.Sequential microfluidic droplet processing for rapid DNA extraction.Living anionic polymerization using a microfluidic reactor.Manipulation of gel emulsions by variable microchannel geometry.DC-dielectrophoretic separation of microparticles using an oil droplet obstacle.Fluid mixing in planar spiral microchannels.Pathways of maximum likelihood for rare events in nonequilibrium systems: application to nucleation in the presence of shear.Computer design of microfluidic mixers for protein/RNA folding studies.Self-synchronizing pairwise production of monodisperse droplets by microfluidic step emulsificationBack Pressure Regulation of Slurry-Forming Reactions in Continuous FlowLight-Driven Droplet Manipulation Technologies for Lab-on-a-Chip Applications
P2860
Q24675312-6F878C1B-6447-48E3-A5F5-742831F3E90DQ27652945-21580E76-A90D-4B46-B2C0-790D6577C78CQ27658563-2C6D3601-D6EE-4AB4-99BF-7D331C5D502BQ27658565-C5749438-686F-4879-B47A-6FFA719EE5B3Q30456527-FD503925-F8B0-4277-90BB-8C6F2075A424Q30482777-E8257A13-33F1-487D-A6E2-4C31F2CA47BDQ30542414-0258BA67-C034-4F73-B90E-C6A4BA5C54CDQ33258724-57CE5558-1FD2-4EEB-B111-57E9198E105CQ36002691-316EA7CD-5DED-4452-8489-278948C336E7Q36421378-6AF84668-8214-4CE4-9C2B-50ADD37F866AQ37283407-8A855078-8373-40E7-AEF4-A1E7D737014BQ37420599-EC90CBB4-82CC-4FD8-A27B-7D35312F71D3Q37880713-069ECE6D-764F-4BFF-8BEC-AD6863E242F3Q38280621-D8D74DB2-7E22-4752-955C-AF85B679E49EQ41517295-D8A98672-8642-4556-8E7C-82422328E28EQ41889896-558FEDB2-0979-446B-83B1-443781F69C91Q42076867-0A48267C-DB89-462D-9132-40B8CFE9B18CQ42182591-38A30DBE-83CF-478D-B436-1A4D8B4C5B07Q43855596-57B3D1F8-EB74-40B9-8C4B-2B6C28736F9BQ44180442-0D40B0A8-02AC-4FF4-8716-E7B1D5F6D26DQ46184143-45733A9E-FD72-4365-91F2-A187BAC27012Q48586604-43459C38-62D9-420E-A39E-95E4F9E99904Q51278573-75C89739-4B10-454A-854D-21A2BBF41469Q51300245-F455689C-197F-4C9B-8591-A7B6513880A6Q51877038-60D65C12-7F15-4134-B069-533F1A1774E9Q55432063-5760A8E1-EA02-425F-87F2-22D055A276B0Q56051134-9C850C81-709E-4126-BA9D-89D49096DB1AQ56951496-792BC0D1-A7E4-4320-9756-708336C58B59Q58655011-48058116-2BAA-4C28-AAEB-2C0E62940C43
P2860
Using microfluidics to observe the effect of mixing on nucleation of protein crystals.
description
2005 nî lūn-bûn
@nan
2005年の論文
@ja
2005年学术文章
@wuu
2005年学术文章
@zh-cn
2005年学术文章
@zh-hans
2005年学术文章
@zh-my
2005年学术文章
@zh-sg
2005年學術文章
@yue
2005年學術文章
@zh
2005年學術文章
@zh-hant
name
Using microfluidics to observe the effect of mixing on nucleation of protein crystals.
@en
Using microfluidics to observe the effect of mixing on nucleation of protein crystals.
@nl
type
label
Using microfluidics to observe the effect of mixing on nucleation of protein crystals.
@en
Using microfluidics to observe the effect of mixing on nucleation of protein crystals.
@nl
prefLabel
Using microfluidics to observe the effect of mixing on nucleation of protein crystals.
@en
Using microfluidics to observe the effect of mixing on nucleation of protein crystals.
@nl
P2093
P2860
P356
P1476
Using microfluidics to observe the effect of mixing on nucleation of protein crystals.
@en
P2093
Cory J Gerdts
Delai L Chen
Rustem F Ismagilov
P2860
P304
P356
10.1021/JA052279V
P407
P577
2005-07-01T00:00:00Z