4.7 Article

In vitro assay for single-cell characterization of impaired deformability in red blood cells under recurrent episodes of hypoxia

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LAB ON A CHIP
卷 21, 期 18, 页码 3458-3470

出版社

ROYAL SOC CHEMISTRY
DOI: 10.1039/d1lc00598g

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资金

  1. National Science Foundation [1635312, 1941655]
  2. National Insitutes of Health [R01HL158102, R01HL154150]
  3. Directorate For Engineering
  4. Div Of Civil, Mechanical, & Manufact Inn [1635312] Funding Source: National Science Foundation
  5. Div Of Civil, Mechanical, & Manufact Inn
  6. Directorate For Engineering [1941655] Funding Source: National Science Foundation

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Red blood cells are exposed to varying shear stress and oxygen tension during circulation, which can affect their biomechanics. Cyclic hypoxia alone significantly reduces cell deformability, particularly in sickle cells which show less resistance to fatigue damage. Treatment with an anti-sickling drug can improve the fatigue resistance of sickle cells exposed to cyclic hypoxia.
Red blood cells (RBCs) are subjected to recurrent changes in shear stress and oxygen tension during blood circulation. The cyclic shear stress has been identified as an important factor that alone can weaken cell mechanical deformability. The effects of cyclic hypoxia on cellular biomechanics have yet to be fully investigated. As the oxygen affinity of hemoglobin plays a key role in the biological function and mechanical performance of RBCs, the repeated transitions of hemoglobin between its R (high oxygen tension) and T (low oxygen tension) states may impact their mechanical behavior. The present study focuses on developing a novel microfluidic-based assay for characterization of the effects of cyclic hypoxia on cell biomechanics. The capability of this assay is demonstrated by a longitudinal study of individual RBCs in health and sickle cell disease subjected to cyclic hypoxia conditions of various durations and levels of low oxygen tension. The viscoelastic properties of cell membranes are extracted from tensile stretching and relaxation processes of RBCs induced by the electrodeformation technique. Results demonstrate that cyclic hypoxia alone can significantly reduce cell deformability, similar to the fatigue damage accumulated through cyclic mechanical loading. RBCs affected by sickle cell disease are less deformable (significantly higher membrane shear modulus and viscosity) than normal RBCs. The fatigue resistance of sickle RBCs to the cyclic hypoxia challenge is significantly inferior to that of normal RBCs, and this trend is more significant in mature erythrocytes of sickle cells. When the oxygen affinity of sickle hemoglobin is enhanced by anti-sickling drug treatment of 5-hydroxymethyl-2-furfural (5-HMF), sickle RBCs show ameliorated resistance to fatigue damage induced by cyclic hypoxia. These results indicate an important biophysical mechanism underlying RBC senescence in which the cyclic hypoxia challenge alone can lead to mechanical degradation of the RBC membrane. We envision that the application of this assay can be further extended to RBCs in other blood diseases and other cell types.

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