about
3D printed auto-mixing chip enables rapid smartphone diagnosis of anemiaCell Microarray Technologies for High-Throughput Cell-Based Biosensors.Rapid mask prototyping for microfluidics.Microphysiological Human Brain and Neural Systems-on-a-Chip: Potential Alternatives to Small Animal Models and Emerging Platforms for Drug Discovery and Personalized Medicine.Materials for Microfluidic Immunoassays: A Review.3D-printed Microfluidic Devices: Fabrication, Advantages and Limitations-a Mini Review.3D printed microfluidic devices: enablers and barriers.3D-printed fluidic networks as vasculature for engineered tissue.A review of digital microfluidics as portable platforms for lab-on a-chip applications.Open-source, community-driven microfluidics with Metafluidics.Fibre-based electrofluidics on low cost versatile 3D printed platforms for solute delivery, separations and diagnostics; from small molecules to intact cells.Fused Deposition Modeling 3D Printing for (Bio)analytical Device Fabrication: Procedures, Materials, and Applications.Autonomous microfluidic capillaric circuits replicated from 3D-printed molds.BaroFuse, a novel pressure-driven, adjustable-throughput perfusion system for tissue maintenance and assessment.Additive Manufacturing: Unlocking the Evolution of Energy Materials.The recent development and applications of fluidic channels by 3D printing.3D printed conformal microfluidics for isolation and profiling of biomarkers from whole organs.Upgrading well plates using open microfluidic patterning.3D-Printed Paper Spray Ionization Cartridge with Integrated Desolvation Feature and Ion Optics.Additive Manufacturing of Biomaterials, Tissues, and Organs.Why microfluidics? Merits and trends in chemical synthesis.Liquid Letters.An easily fabricated three-dimensional threaded lemniscate-shaped micromixer for a wide range of flow rates.Moving from millifluidic to truly microfluidic sub-100-μm cross-section 3D printed devices.A 2.5-D glass micromodel for investigation of multi-phase flow in porous media.A one-step strategy for ultra-fast and low-cost mass production of plastic membrane microfluidic chips.Stereoselective Catalytic Synthesis of Active Pharmaceutical Ingredients in Homemade 3D-Printed Mesoreactors.3D printed water-soluble scaffolds for rapid production of PDMS micro-fluidic flow chambers.3D-glass molds for facile production of complex droplet microfluidic chips.A Modular Microfluidic Device via Multimaterial 3D Printing for Emulsion Generation.Accessing microfluidics through feature-based design software for 3D printing.Insert-based microfluidics for 3D cell culture with analysis.Handheld skin printer: in situ formation of planar biomaterials and tissues.Determination of red blood cell deformability using centrifugal force in a three-dimensional-printed mini-disk (3D-PMD).3D printed microchannels for sub-nL NMR spectroscopy.Reprocessable thermosets for sustainable three-dimensional printing.Design and 3D printing of a stainless steel reactor for continuous difluoromethylations using fluoroformMechanically Defined Microgels by Droplet MicrofluidicsInterplay between materials and microfluidicsMicrofluidics: A New Layer of Control for Extrusion-Based 3D Printing
P2860
Q33451091-6148A63C-52AF-4F5E-BD1D-D80E95CA1EA4Q33858214-A2DEBC41-6250-4EB0-86CA-8E76F8E8C7F3Q36678240-0D04BB5C-64C3-4524-9F34-A935EEB021F2Q38685795-B0624730-44A7-4FB1-9E90-23DF5CA68A27Q38742435-4062F953-4BE8-4885-8041-E8CE36731F1EQ38822362-96351D99-8F3A-4838-828B-F0D5E5835864Q38825864-2781F809-23E8-4E64-8EFC-DE24AAE6F92DQ38833108-B8D63EDB-0203-4934-9251-7EB72BBEFA03Q38858114-56C1EF03-CE42-46C6-905C-4221CD1902E9Q40476862-759A635A-4FFF-48EE-A793-804AEF34A53BQ40482346-A832E750-A19B-48A4-945C-A54FF5382463Q41012428-2600D581-EAF7-46A8-8519-C5918C823A5DQ42320864-9F455975-D7BD-4F30-9A1F-93D6F5EE35D6Q42353233-61B2E076-E8C9-448C-BBBC-8F534BFED91CQ42379323-75FA39B3-CE19-4D2E-97B7-506601C668CDQ42657902-03A86DD9-C828-42C6-B049-C7149676D236Q45061711-773D7F14-A89F-4F61-AC01-3E288CD91F31Q47325080-CC6521EA-466A-4121-9826-1984AAD38CE9Q47437356-EABD3CB8-9A37-44AE-A145-FFC315FCF016Q47658833-82E3B6CB-CEAA-40F0-8264-CCF0BB662B9FQ47673030-EF31FF06-09FA-4E2F-BC6C-E1AC924EB5A2Q47716376-F2FDAA4D-82D5-4312-A708-A8008AAEF720Q47807140-48787713-1E63-4652-8FFB-C56BD47DDCDFQ48020937-F21CDE91-ED05-4E3B-ABF9-188A4FCDB1BBQ48279560-61477384-0C04-42FD-84AC-29326068AA7CQ48312413-F90957A8-55F9-4397-9A64-929F602D09F0Q48360525-FAD28DAE-1D54-479A-BF89-A5F81538E80EQ49789708-DA263BD7-55DD-4C51-8692-FE2F897123EBQ52320897-32B5E104-C461-4F42-9EB3-71F2B1FAD5BBQ52349724-AE8DF384-7CC0-46EF-BFA4-B57B0648A297Q52622103-1A40C16C-AE5B-46F7-A76B-73E8BDA6352AQ52656909-80DF8222-A47B-4289-9193-DD2EC66E3888Q52718892-0F7C1DB3-F582-4997-B36F-486DD7564D0AQ55187841-E6ACEC64-D99A-4EA2-A7C6-687131874D78Q55246509-F1ECBD62-D06A-4B37-ACC5-BE760740A209Q55288492-F87C58E3-6736-48AD-A66E-3922E06A3A3EQ56679369-C66FDF97-F3A8-473E-9A8C-74FAB8E440AAQ57343113-D2D38005-7ACB-4093-B45C-3F9E9EDC5132Q58466989-D4728076-9D1F-481C-AA1A-EB2B202E4C0FQ58576338-70A9CBDE-4031-493C-B683-C589404F3C0B
P2860
description
2016 nî lūn-bûn
@nan
2016年の論文
@ja
2016年論文
@yue
2016年論文
@zh-hant
2016年論文
@zh-hk
2016年論文
@zh-mo
2016年論文
@zh-tw
2016年论文
@wuu
2016年论文
@zh
2016年论文
@zh-cn
name
3D-Printed Microfluidics.
@en
type
label
3D-Printed Microfluidics.
@en
prefLabel
3D-Printed Microfluidics.
@en
P2093
P2860
P356
P1476
3D-Printed Microfluidics.
@en
P2093
Albert Folch
Anthony K Au
Lisa F Horowitz
Wilson Huynh
P2860
P304
P356
10.1002/ANIE.201504382
P407
P577
2016-02-08T00:00:00Z