Structural colour enhanced microfluidics

Detao Qin; Andrew H. Gibbons; Masateru M. Ito; Sangamithirai Subramanian Parimalam; Handong Jiang; H. Enis Karahan; Behnam Ghalei; Daisuke Yamaguchi; Ganesh N. Pandian; Easan Sivaniah

doi:10.1038/s41467-022-29956-4

Structural colour enhanced microfluidics

Detao Qin, Andrew H. Gibbons, Masateru M. Ito^*, Sangamithirai Subramanian Parimalam, Handong Jiang, H. Enis Karahan, Behnam Ghalei, Daisuke Yamaguchi, Ganesh N. Pandian, Easan Sivaniah^*

^*Corresponding author for this work

Kyoto University

Research output: Contribution to journal › Article › peer-review

15 Citations (Scopus)

Abstract

Advances in microfluidic technology towards flexibility, transparency, functionality, wearability, scale reduction or complexity enhancement are currently limited by choices in materials and assembly methods. Organized microfibrillation is a method for optically printing well-defined porosity into thin polymer films with ultrahigh resolution. Here we demonstrate this method to create self-enclosed microfluidic devices with a few simple steps, in a number of flexible and transparent formats. Structural colour, a property of organized microfibrillation, becomes an intrinsic feature of these microfluidic devices, enabling in-situ sensing capability. Since the system fluid dynamics are dependent on the internal pore size, capillary flow is shown to become characterized by structural colour, while independent of channel dimension, irrespective of whether devices are printed at the centimetre or micrometre scale. Moreover, the capability of generating and combining different internal porosities enables the OM microfluidics to be used for pore-size based applications, as demonstrated by separation of biomolecular mixtures.

Original language	English
Article number	2281
Journal	Nature Communications
Volume	13
Issue number	1
DOIs	https://doi.org/10.1038/s41467-022-29956-4
Publication status	Published - Dec 2022
Externally published	Yes

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Publisher Copyright:
© 2022, The Author(s).

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title = "Structural colour enhanced microfluidics",

abstract = "Advances in microfluidic technology towards flexibility, transparency, functionality, wearability, scale reduction or complexity enhancement are currently limited by choices in materials and assembly methods. Organized microfibrillation is a method for optically printing well-defined porosity into thin polymer films with ultrahigh resolution. Here we demonstrate this method to create self-enclosed microfluidic devices with a few simple steps, in a number of flexible and transparent formats. Structural colour, a property of organized microfibrillation, becomes an intrinsic feature of these microfluidic devices, enabling in-situ sensing capability. Since the system fluid dynamics are dependent on the internal pore size, capillary flow is shown to become characterized by structural colour, while independent of channel dimension, irrespective of whether devices are printed at the centimetre or micrometre scale. Moreover, the capability of generating and combining different internal porosities enables the OM microfluidics to be used for pore-size based applications, as demonstrated by separation of biomolecular mixtures.",

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doi = "10.1038/s41467-022-29956-4",

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AU - Qin, Detao

AU - Gibbons, Andrew H.

AU - Ito, Masateru M.

AU - Parimalam, Sangamithirai Subramanian

AU - Jiang, Handong

AU - Enis Karahan, H.

AU - Ghalei, Behnam

AU - Yamaguchi, Daisuke

AU - Pandian, Ganesh N.

AU - Sivaniah, Easan

PY - 2022/12

Y1 - 2022/12

N2 - Advances in microfluidic technology towards flexibility, transparency, functionality, wearability, scale reduction or complexity enhancement are currently limited by choices in materials and assembly methods. Organized microfibrillation is a method for optically printing well-defined porosity into thin polymer films with ultrahigh resolution. Here we demonstrate this method to create self-enclosed microfluidic devices with a few simple steps, in a number of flexible and transparent formats. Structural colour, a property of organized microfibrillation, becomes an intrinsic feature of these microfluidic devices, enabling in-situ sensing capability. Since the system fluid dynamics are dependent on the internal pore size, capillary flow is shown to become characterized by structural colour, while independent of channel dimension, irrespective of whether devices are printed at the centimetre or micrometre scale. Moreover, the capability of generating and combining different internal porosities enables the OM microfluidics to be used for pore-size based applications, as demonstrated by separation of biomolecular mixtures.

AB - Advances in microfluidic technology towards flexibility, transparency, functionality, wearability, scale reduction or complexity enhancement are currently limited by choices in materials and assembly methods. Organized microfibrillation is a method for optically printing well-defined porosity into thin polymer films with ultrahigh resolution. Here we demonstrate this method to create self-enclosed microfluidic devices with a few simple steps, in a number of flexible and transparent formats. Structural colour, a property of organized microfibrillation, becomes an intrinsic feature of these microfluidic devices, enabling in-situ sensing capability. Since the system fluid dynamics are dependent on the internal pore size, capillary flow is shown to become characterized by structural colour, while independent of channel dimension, irrespective of whether devices are printed at the centimetre or micrometre scale. Moreover, the capability of generating and combining different internal porosities enables the OM microfluidics to be used for pore-size based applications, as demonstrated by separation of biomolecular mixtures.

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Structural colour enhanced microfluidics

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