A Flexible Method for Nanofiber-based 3D Microfluidic Device Fabrication for Water Quality Monitoring
Water pollution seriously affects human health. Accurate and rapid detection and timely treatment of toxic substances in water are urgently needed. A stacked multilayer electrostatic printing technique was developed for making nanofiber-based microfluidic chips for water-quality testing. Nanofiber m...
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MDPI AG
2020-03-01
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| Series: | Micromachines |
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| Online Access: | https://www.mdpi.com/2072-666X/11/3/276 |
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doaj-7f0eac6da2f145c4ac50c4f354d390542020-11-25T02:24:31ZengMDPI AGMicromachines2072-666X2020-03-0111327610.3390/mi11030276mi11030276A Flexible Method for Nanofiber-based 3D Microfluidic Device Fabrication for Water Quality MonitoringXiaojun Chen0Deyun Mo1Manfeng Gong2School of Mechanical and Electronic Engineering, Lingnan Normal University, Zhanjiang 524048, ChinaSchool of Mechanical and Electronic Engineering, Lingnan Normal University, Zhanjiang 524048, ChinaSchool of Mechanical and Electronic Engineering, Lingnan Normal University, Zhanjiang 524048, ChinaWater pollution seriously affects human health. Accurate and rapid detection and timely treatment of toxic substances in water are urgently needed. A stacked multilayer electrostatic printing technique was developed for making nanofiber-based microfluidic chips for water-quality testing. Nanofiber membrane matrix structures for microfluidic devices were fabricated by electrospinning. A hydrophobic barrier was then printed through electrostatic wax printing. This process was repeatedly performed to create three-dimensional nanofiber-based microfluidic analysis devices (3D-µNMADs). Flexible printing enabled one-step fabrication without the need for additional alignment or adhesive bonding. Practical applications of 3D-µNMADs include a colorimetric platform to quantitatively detect iron ion concentrations in water. There is also great potential for personalized point-of-care testing. Overall, the devices offer simple fabrication processes, flexible prototyping, potential for mass production, and multi-material integration.https://www.mdpi.com/2072-666X/11/3/276nanofiber-based3d microfluidic chipwater-quality monitoringelectrostatic printing |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
Xiaojun Chen Deyun Mo Manfeng Gong |
| spellingShingle |
Xiaojun Chen Deyun Mo Manfeng Gong A Flexible Method for Nanofiber-based 3D Microfluidic Device Fabrication for Water Quality Monitoring Micromachines nanofiber-based 3d microfluidic chip water-quality monitoring electrostatic printing |
| author_facet |
Xiaojun Chen Deyun Mo Manfeng Gong |
| author_sort |
Xiaojun Chen |
| title |
A Flexible Method for Nanofiber-based 3D Microfluidic Device Fabrication for Water Quality Monitoring |
| title_short |
A Flexible Method for Nanofiber-based 3D Microfluidic Device Fabrication for Water Quality Monitoring |
| title_full |
A Flexible Method for Nanofiber-based 3D Microfluidic Device Fabrication for Water Quality Monitoring |
| title_fullStr |
A Flexible Method for Nanofiber-based 3D Microfluidic Device Fabrication for Water Quality Monitoring |
| title_full_unstemmed |
A Flexible Method for Nanofiber-based 3D Microfluidic Device Fabrication for Water Quality Monitoring |
| title_sort |
flexible method for nanofiber-based 3d microfluidic device fabrication for water quality monitoring |
| publisher |
MDPI AG |
| series |
Micromachines |
| issn |
2072-666X |
| publishDate |
2020-03-01 |
| description |
Water pollution seriously affects human health. Accurate and rapid detection and timely treatment of toxic substances in water are urgently needed. A stacked multilayer electrostatic printing technique was developed for making nanofiber-based microfluidic chips for water-quality testing. Nanofiber membrane matrix structures for microfluidic devices were fabricated by electrospinning. A hydrophobic barrier was then printed through electrostatic wax printing. This process was repeatedly performed to create three-dimensional nanofiber-based microfluidic analysis devices (3D-µNMADs). Flexible printing enabled one-step fabrication without the need for additional alignment or adhesive bonding. Practical applications of 3D-µNMADs include a colorimetric platform to quantitatively detect iron ion concentrations in water. There is also great potential for personalized point-of-care testing. Overall, the devices offer simple fabrication processes, flexible prototyping, potential for mass production, and multi-material integration. |
| topic |
nanofiber-based 3d microfluidic chip water-quality monitoring electrostatic printing |
| url |
https://www.mdpi.com/2072-666X/11/3/276 |
| work_keys_str_mv |
AT xiaojunchen aflexiblemethodfornanofiberbased3dmicrofluidicdevicefabricationforwaterqualitymonitoring AT deyunmo aflexiblemethodfornanofiberbased3dmicrofluidicdevicefabricationforwaterqualitymonitoring AT manfenggong aflexiblemethodfornanofiberbased3dmicrofluidicdevicefabricationforwaterqualitymonitoring AT xiaojunchen flexiblemethodfornanofiberbased3dmicrofluidicdevicefabricationforwaterqualitymonitoring AT deyunmo flexiblemethodfornanofiberbased3dmicrofluidicdevicefabricationforwaterqualitymonitoring AT manfenggong flexiblemethodfornanofiberbased3dmicrofluidicdevicefabricationforwaterqualitymonitoring |
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1724855244406390784 |