Fast, flexible and low-cost multiphase blood analogue for biomedical and energy applications

During the last two decades, several kinds of particulate blood analogue fluids have been proposed, but none of those were able to mimic the multiphase effects of real blood. Hence, it is clear that it is crucial to develop a simple multiphase blood analogue to be used for in vitro experiments at bo...

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Bibliographic Details
Published in:Experiments in fluids 2020, Vol.61 (11), Article 231
Main Authors: Lima, Rui Alberto Madeira Macedo, Vega, E. J., Moita, A. S., Miranda, J. M., Pinho, Diana, Moreira, A. L. N.
Format: Article
Language:English
Subjects:
Applications of Laser and Imaging Technique to Fluid Mechanics. 20th International Symposium in Lisbon 2020
Blood flow
Engineering
Engineering Fluid Dynamics
Engineering Thermodynamics
Fluid- and Aerodynamics
Fluids
Heat and Mass Transfer
Low cost
Micelles
Microchannels
Multiphase
Research Article
Rheological properties
Science & Technology
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Summary:During the last two decades, several kinds of particulate blood analogue fluids have been proposed, but none of those were able to mimic the multiphase effects of real blood. Hence, it is clear that it is crucial to develop a simple multiphase blood analogue to be used for in vitro experiments at both macro- and microscale level. To the best of our knowledge, the present work shows for the first time a straightforward and extremely stable blood analogue fluid able to mimic multiphase blood flow phenomena. The present work proposes a simple, low-cost and stable multiphase blood analogue with the ability to mimic microscale blood flow phenomena. The proposed analogue fluid is composed of Brij L4 surfactant micelles suspended in pure water and is extremely easy to be produced. To investigate the ability of this analogue to mimic microscale blood flow phenomena, flow visualizations were performed in a microchannel constriction. In vitro blood phenomena were compared with the measurements performed with the proposed analogue fluid. Additionally, rheological measurements of the multiphase blood analogue were acquired by means of a stress-controlled rheometer and compared with in vitro blood sample viscosity curves. Overall, the results indicate that it is possible to produce a stable particulate fluid with geometrical, mechanical and flow properties similar to in vitro blood. Hence, the proposed analogue has a great potential to be used in flow experiments from macro- to nanoscale levels Fundação para a Ciência e a Tecnologia (FCT) under the strategic grants UIDB/04077/2020, UIDB/04436/2020 and UIDB/00532/2020. The authors are also grateful for the funding of FCT through the projects NORTE-01-0145-FEDER-029394, NORTE-01-0145-FEDER-030171 and POCI-01-0145-FEDER-016861 (PTDC/QEQ-FTT/4287/2014) funded by COMPETE2020, NORTE2020, PORTUGAL2020, and FEDER. The authors also acknowledge FCT for partially financing the research under the framework of the project UTAP-EXPL/CTE/0064/2017, financiado no âmbito do Projeto 5665—Parcerias Internacionais de Ciência e Tecnologia, UT Austin Programme. Partial support from the Spanish Ministry of Science and Education (grant no. DPI2016-78887) and Junta de Extremadura (grants no. GR15014 and IB18005, partially financed by FEDER funds) is gratefully acknowledged too.
ISSN:0723-4864
1432-1114
DOI:10.1007/s00348-020-03066-7