Red blood cells radial dispersion in blood flowing through microchannels: the role of temperature

The behavior of suspensions of individual blood cells, such as red blood cells (RBCs), flowing through microvessels and microfluidic systems depend strongly on the hematocrit (Hct), microvessel topology and cell properties. Although it is well known that blood rheological properties are temperature...

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Published inJournal of biomechanics Vol. 49; no. 11; pp. 2293-2298 - 2298
Main Authors Pinho, Diana, Rodrigues, Raquel O., Faustino, Vera, Yaginuma, T., Exposto, José, Lima, Rui Alberto Madeira Macedo
Format Journal Article
LanguageEnglish
Published Elsevier 1 2016
Subjects
Biomicrofluidics
Blood flow
Diffusion
Erythrocytes
Hematocrit
Hemodynamics
Hemorheology
Humans
Microcirculation
Microfluidics
Microscopy
Microvessels
Radial dispersion
Red blood cells
Science & Technology
Temperature
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Summary:The behavior of suspensions of individual blood cells, such as red blood cells (RBCs), flowing through microvessels and microfluidic systems depend strongly on the hematocrit (Hct), microvessel topology and cell properties. Although it is well known that blood rheological properties are temperature dependent, to the best of our knowledge no work has studied the role of the temperature on the RBCs dispersion. A powerful way to investigate this latter effect is through a high-speed video microscopy system, which provides detailed flow measurements of each individual RBC. Hence, the effect of temperature on the RBCs dispersion flowing through a 100μm glass capillary was examined by means of a confocal micro-PTV system. Hundreds of labeled RBCs were tracked at moderate Hct (12%) and at four different temperatures, i.e., 25°C, 32°C, 37°C and 42°C. The results yielded an enhancement of the RBCs diffusion as the temperature increases. Hence, our findings show that RBCs radial dispersion is temperature dependent and as a result the temperature should not be ignored in future blood flow studies. We believe that this finding is important for a better understanding of blood mass transport mechanisms under both physiological and pathological conditions. The authors acknowledge the financial support provided by PTDC/SAU-ENB/116929/2010 and EXPL/EMS-SIS/2215/2013 from FCT (Science and Technology Foundation), COMPETE, QREN and European Union (FEDER). R. O. Rodrigues, D. Pinho and V. Faustino acknowledge respectively, the PhD scholarships SFRH/BD/97658/ 2013, SFRH/BD/89077/2012 and SFRH/BD/99696/2014 Granted by FCT. The authors are also very grateful to Professor Takuji Ishikawa and Professor Takami Yamaguchi (Tohoku University) for supporting this research work.
ISSN:1873-2380
DOI:10.1016/j.jbiomech.2015.11.037