Facile Fabrication of Microfluidic Chips for 3D Hydrodynamic Focusing and Wet Spinning of Polymeric Fibers.
chip fabrication
computational flow modeling
fiber wet spinning
hydrodynamic focusing
textile industry
Journal
Polymers
ISSN: 2073-4360
Titre abrégé: Polymers (Basel)
Pays: Switzerland
ID NLM: 101545357
Informations de publication
Date de publication:
10 Mar 2020
10 Mar 2020
Historique:
received:
18
02
2020
revised:
04
03
2020
accepted:
05
03
2020
entrez:
14
3
2020
pubmed:
14
3
2020
medline:
14
3
2020
Statut:
epublish
Résumé
Microfluidic wet spinning has gained increasing interest in recent years as an alternative to conventional wet spinning by offering higher control in fiber morphology and a gateway for the development of multi-material fibers. Conventionally, microfluidic chips used to create such fibers are fabricated by soft lithography, a method that requires both time and investment in necessary cleanroom facilities. Recently, additive manufacturing techniques were investigated for rapid and cost-efficient prototyping. However, these microfluidic devices are not yet matching the resolutions and tolerances offered by soft lithography. Herein, we report a facile and rapid method using selected arrays of hypodermic needles as templates within a silicone elastomer matrix. The produced microfluidic spinnerets display co-axially aligned circular channels. By simulation and flow experiments, we prove that these devices can maintain laminar flow conditions and achieve precise 3D hydrodynamic focusing. The devices were tested with a commercial polyurethane formulation to demonstrate that fibers with desired morphologies can be produced by varying the degree of hydrodynamic focusing. Thanks to the adaptability of this concept to different microfluidic spinneret designs-as well as to its transparency, ease of fabrication, and cost-efficient procedure-this device sets the ground for transferring microfluidic wet spinning towards industrial textile settings.
Identifiants
pubmed: 32164361
pii: polym12030633
doi: 10.3390/polym12030633
pmc: PMC7182802
pii:
doi:
Types de publication
Journal Article
Langues
eng
Subventions
Organisme : Swiss National Science Foundation (SNSF)
ID : 40B2-0_180983
Organisme : Swiss Competence Center for Materials Science and Technology
ID : XXXXXX
Références
Micromachines (Basel). 2018 Jul 27;9(8):
pubmed: 30424307
Nano Lett. 2016 Sep 14;16(9):5917-22
pubmed: 27513098
Biomicrofluidics. 2011 Jun;5(2):22208
pubmed: 21799714
ACS Nano. 2019 Mar 26;13(3):2749-2772
pubmed: 30768903
Biomaterials. 2010 Feb;31(5):863-9
pubmed: 19878994
ACS Appl Mater Interfaces. 2013 Jan;5(1):114-9
pubmed: 23215013
Lab Chip. 2016 Jun 21;16(12):2287-94
pubmed: 27217203
Lab Chip. 2010 Jul 21;10(14):1856-61
pubmed: 20454720
Lab Chip. 2017 Aug 22;17(17):2899-2909
pubmed: 28726927
Nat Mater. 2013 Jun;12(6):584-90
pubmed: 23542870
Adv Mater. 2018 May;30(22):e1800001
pubmed: 29656459
Lab Chip. 2018 May 1;18(9):1341-1348
pubmed: 29619449
Lab Chip. 2004 Dec;4(6):576-80
pubmed: 15570368
Lab Chip. 2016 Jul 5;16(14):2654-61
pubmed: 27296229
Anal Chem. 2018 Sep 4;90(17):10450-10456
pubmed: 30071717
Lab Chip. 2016 May 24;16(11):1993-2013
pubmed: 27146365
Nat Commun. 2018 Nov 1;9(1):4573
pubmed: 30385751
PLoS One. 2016 Apr 06;11(4):e0152023
pubmed: 27050661
Langmuir. 2007 Aug 14;23(17):9104-8
pubmed: 17637008
Sci Rep. 2017 Dec;7(1):158
pubmed: 28279011
Nat Protoc. 2018 Nov;13(11):2557-2579
pubmed: 30353174
Nat Mater. 2011 Sep 04;10(11):877-83
pubmed: 21892177
Lab Chip. 2009 Nov 21;9(22):3282-8
pubmed: 19865737
Nanoscale. 2016 Jun 16;8(24):12113-7
pubmed: 27251420
Langmuir. 2008 Jun 1;24(13):6845-51
pubmed: 18512874
Lab Chip. 2010 May 21;10(10):1328-34
pubmed: 20445889