about
3D Printed Bionic Nanodevices3D bioprinting for engineering complex tissues.Bioprinting the Cancer Microenvironment.A decade of progress in tissue engineering.Printing soft matter in three dimensions.Cell-laden hydrogels for osteochondral and cartilage tissue engineering.Advances in engineering hydrogels.Conductive Cellulose Composites with Low Percolation Threshold for 3D Printed Electronics.Photoresponsive Passive Micromixers Based on Spiropyran Size-Tunable Hydrogels.A New 3D Printing Strategy by Harnessing Deformation, Instability, and Fracture of Viscoelastic Inks.Spatially and Temporally Controlled Hydrogels for Tissue Engineering.3D-Printed Transparent Glass.3D Printing of Materials with Tunable Failure via Bioinspired Mechanical Gradients.Bioprinting of Cartilage and Skin Tissue Analogs Utilizing a Novel Passive Mixing Unit Technique for Bioink Precellularization.Rapid Continuous Multimaterial Extrusion Bioprinting.A fluorescent microbead-based microfluidic immunoassay chip for immune cell cytokine secretion quantification.Graphene Oxide-Based Electrode Inks for 3D-Printed Lithium-Ion Batteries.Self-Organized Velocity Pulses of Dense Colloidal Suspensions in Microchannel Flow.Magnetic nanochain integrated microfluidic biochips.The role of ceramic and glass science research in meeting societal challenges: Report from an NSF-sponsored workshopInterplay between materials and microfluidicsSelf-Contained Polymer/Metal 3D Printed Electrochemical Platform for Tailored Water Splitting
P2860
Q30355336-95901081-A0BB-49AB-BA7A-C11D90126546Q36932634-80C39021-691F-4C45-A52B-CF4C4022094CQ37670051-7A01B2B7-4836-486D-9E63-A8EDCA6F9FF8Q38943524-82AF7DB3-8256-4EA6-9108-402B86176BE8Q39038668-71F00990-35F7-4690-8C94-0BFCAD352E30Q39088959-3142E64F-BE8F-4702-A2C8-05BF36897B2EQ39284721-2CF44CF9-9057-4BFA-93B8-0B2E62FA82D5Q42206863-C2E29D3E-8558-47D8-AD70-7A45C8B90D99Q47220173-F7D744E2-E468-43BC-B452-25F09A5878A7Q47251484-A6649D17-4FB3-41C7-8EDC-D50A8C2D17E4Q47287984-ADDC1082-33BC-4910-AC2A-F3C2F9632890Q48219882-207D89C2-43F2-4FC9-966F-AD34A623E4ACQ48236583-92DD9780-4695-4AE5-966E-615306C30FBFQ49827344-03D2FE59-F1A3-424F-A2CC-DC18A7414BFBQ50054350-8E424F5E-CD9C-4741-9E5B-80C189E9AE70Q50074476-151B9713-2583-4AB5-8841-088D081B3D14Q51539170-E36450AE-B1B5-4BC9-8A3A-6053CC89CA51Q52836898-008418ED-9A3A-4331-86CF-405C80A74159Q55286491-9E0E2DB3-5580-4890-9CBC-A36394A6E65AQ57426424-F2BCB405-E48B-4938-ADDF-824B41E0DAC2Q58466989-87CBFC1A-EA50-476D-9037-EE3AAC833101Q58491212-EFAA1091-5AEB-4CC3-A2D6-E86B4458D215
P2860
description
2015 nî lūn-bûn
@nan
2015年の論文
@ja
2015年論文
@yue
2015年論文
@zh-hant
2015年論文
@zh-hk
2015年論文
@zh-mo
2015年論文
@zh-tw
2015年论文
@wuu
2015年论文
@zh
2015年论文
@zh-cn
name
Active mixing of complex fluids at the microscale.
@ast
Active mixing of complex fluids at the microscale.
@en
type
label
Active mixing of complex fluids at the microscale.
@ast
Active mixing of complex fluids at the microscale.
@en
prefLabel
Active mixing of complex fluids at the microscale.
@ast
Active mixing of complex fluids at the microscale.
@en
P2093
P2860
P356
P1476
Active mixing of complex fluids at the microscale.
@en
P2093
Daniele Foresti
Jennifer A Lewis
Thomas J Ober
P2860
P304
12293-12298
P356
10.1073/PNAS.1509224112
P407
P577
2015-09-22T00:00:00Z