An on-chip viscoelasticity sensor for biological fluids
There are so many non-Newtonian fluids in our daily life, such as milk, blood, cytoplasm, and mucus, most of which are viscoelastic heterogeneous liquid containing cells, inorganic ion, metabolites, and hormones. In microfluidic microparticle-manipulating applications, the target particles are pract...
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sg-ntu-dr.10356-1735202024-02-09T15:38:58Z An on-chip viscoelasticity sensor for biological fluids Zhao, Qianbin Yan, Sheng Zhang, Boran Fan, Kai Zhang, Jun Li, Weihua School of Electrical and Electronic Engineering Engineering Blood Viscous Flow There are so many non-Newtonian fluids in our daily life, such as milk, blood, cytoplasm, and mucus, most of which are viscoelastic heterogeneous liquid containing cells, inorganic ion, metabolites, and hormones. In microfluidic microparticle-manipulating applications, the target particles are practically distributed within the biological fluids like blood and urine. The viscoelasticity of biological fluid is constantly ignored for simplicity especially when the fluid is substantially diluted and contains rather complex components. However, even the fluid's ultraweak viscoelasticity actually affects the microparticle migration and may bring a completely different behavior compared with the Newtonian fluids. As a result, a robust and easy operated on-chip viscoelasticity sensor is potential and desired in many research and industrial fields, including assay sample preparation, clinical diagnostics, and on-chip sensor. In this work, we employed stable non-Newtonian fluid-polyethylene oxide (PEO) solutions with various concentrations to investigate and calibrate effects of the weak fluidic viscoelasticity on microparticle behaviors in a double-layered microfluidic channel. An analogy-based database of fluidic patterns for viscoelasticity sensing and relaxation time measurement was established. Then, we tested different biological fluids including blood plasma and fetal bovine serum and proved that they exhibited similar viscoelasticity effects to the PEO solutions with the corresponding concentration, which reached a good agreement with available results by references. The detection limitation of relaxation time can reach 1 ms. It promised a robust and integrated on-chip microfluidic viscoelasticity sensor for different biological fluids without complicated calculations. Published version Q.Z. acknowledges the support from Full-Time Talents Program of Hebei Province of China (2020HBQZYC012) and Academician Expert Workstation of Yunnan Province of China (202205AF150025). S.Y. thanks for the financial support from Guangdong Basic and Applied Basic Research Foundation (2021A1515110277) and the Shenzhen Natural Science Fund (20200811205344001). J.Z. acknowledges the support from the ARC DECRA fellowship (grant no. DE210100692). 2024-02-09T02:53:40Z 2024-02-09T02:53:40Z 2023 Journal Article Zhao, Q., Yan, S., Zhang, B., Fan, K., Zhang, J. & Li, W. (2023). An on-chip viscoelasticity sensor for biological fluids. Cyborg and Bionic Systems, 4(4), 0006-. https://dx.doi.org/10.34133/cbsystems.0006 2692-7632 https://hdl.handle.net/10356/173520 10.34133/cbsystems.0006 37040278 2-s2.0-85173096754 4 4 0006 en Cyborg and Bionic Systems © 2023 Qianbin Zhao et al. Exclusive Licensee Beijing Institute of Technology Press. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution License (CC BY 4.0). application/pdf |
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Engineering Blood Viscous Flow Zhao, Qianbin Yan, Sheng Zhang, Boran Fan, Kai Zhang, Jun Li, Weihua An on-chip viscoelasticity sensor for biological fluids |
| description |
There are so many non-Newtonian fluids in our daily life, such as milk, blood, cytoplasm, and mucus, most of which are viscoelastic heterogeneous liquid containing cells, inorganic ion, metabolites, and hormones. In microfluidic microparticle-manipulating applications, the target particles are practically distributed within the biological fluids like blood and urine. The viscoelasticity of biological fluid is constantly ignored for simplicity especially when the fluid is substantially diluted and contains rather complex components. However, even the fluid's ultraweak viscoelasticity actually affects the microparticle migration and may bring a completely different behavior compared with the Newtonian fluids. As a result, a robust and easy operated on-chip viscoelasticity sensor is potential and desired in many research and industrial fields, including assay sample preparation, clinical diagnostics, and on-chip sensor. In this work, we employed stable non-Newtonian fluid-polyethylene oxide (PEO) solutions with various concentrations to investigate and calibrate effects of the weak fluidic viscoelasticity on microparticle behaviors in a double-layered microfluidic channel. An analogy-based database of fluidic patterns for viscoelasticity sensing and relaxation time measurement was established. Then, we tested different biological fluids including blood plasma and fetal bovine serum and proved that they exhibited similar viscoelasticity effects to the PEO solutions with the corresponding concentration, which reached a good agreement with available results by references. The detection limitation of relaxation time can reach 1 ms. It promised a robust and integrated on-chip microfluidic viscoelasticity sensor for different biological fluids without complicated calculations. |
| author2 |
School of Electrical and Electronic Engineering |
| author_facet |
School of Electrical and Electronic Engineering Zhao, Qianbin Yan, Sheng Zhang, Boran Fan, Kai Zhang, Jun Li, Weihua |
| format |
Article |
| author |
Zhao, Qianbin Yan, Sheng Zhang, Boran Fan, Kai Zhang, Jun Li, Weihua |
| author_sort |
Zhao, Qianbin |
| title |
An on-chip viscoelasticity sensor for biological fluids |
| title_short |
An on-chip viscoelasticity sensor for biological fluids |
| title_full |
An on-chip viscoelasticity sensor for biological fluids |
| title_fullStr |
An on-chip viscoelasticity sensor for biological fluids |
| title_full_unstemmed |
An on-chip viscoelasticity sensor for biological fluids |
| title_sort |
on-chip viscoelasticity sensor for biological fluids |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/173520 |
| _version_ |
1794549396077019136 |