Characterization of shear stress preventing red blood cells aggregation at the individual cell level: The temperature dependence

K. Lee, A. Priezzhev, Sehyun Shin, F. Yaya, I. Meglinski

Research output: Contribution to journalArticle

8 Citations (Scopus)

Abstract

BACKGROUND: The novel measure of the red blood cells (RBC) aggregation (RBC-A) - the critical (minimum) shear stress (CSS) to prevent the cells from aggregation was found to be a promising clinically significant parameter. However, the absolute values of this parameter were found to change significantly depending on the shearing geometry (cup-and-bob, cone-plate or microchannel-flow) and have different temperature dependences along with it. The direct confirmation of these dependences aimed to find out the correct values is still pending. OBJECTIVE: In this work, we aim to assess the absolute values of CSS at different temperatures. METHODS: The single cell level measurements of CSS were performed using optical tweezers. The measurements were carried out in heavily diluted suspensions of RBCs in plasma. RESULTS: The temperature dependent changes in CSS were measured at the points (22 and 38°C), in which the cup-and-bob and cone-plate systems yielded about 1.5-fold different values, while the microchannel-flow system yielded a constant value. The single cell CSS were found to be 362±157mPa (22°C) and 312±57mPa (38°C). CONCLUSIONS: Our results prove that the microfluidic-flow approach is reflecting the RBC-A correctly. While the CSS values measured with other systems show the temperature dependent effect of the shearing geometry.

Original languageEnglish
Pages (from-to)853-857
Number of pages5
JournalClinical Hemorheology and Microcirculation
Volume64
Issue number4
DOIs
Publication statusPublished - 2016

Keywords

  • aggregation
  • critical shear stress
  • microfluidic flow
  • optical tweezers
  • Red blood cell
  • shearing-geometry
  • single-cell level measurements
  • temperature

ASJC Scopus subject areas

  • Physiology
  • Hematology
  • Cardiology and Cardiovascular Medicine
  • Physiology (medical)

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