Probing single-cell oxygen reserve in sickled erythrocytes via in vivo photoacoustic microscopy

Abstract

Individuals with sickle cell disease (SCD) face ongoing risk of multi-organ ischemia resulting in chronic disability, frequent hospitalizations, and early mortality. The relationship between hemoglobin (Hb) S polymerization, erythrocyte sickling, and tissue ischemia has been of great interest. Oxygen off-loading and increasing deoxy-Hb concentration promote HbS polymerization, the latter, which has been linked to early erythrocyte deformation or "reversible" sickling. Eventually, severe polymerization weakens the cell membrane, leading to "irreversibly" sickled cells. Whether the degree of polymerization and the cell's morphologic state, in turn, influence oxygen binding and thus, tissue oxygen availability has been of interest, but technically challenging to study in patients. Over two decades, Wang and colleagues developed an imaging platform, photoacoustic microscopy (PAM), which offers two unique aspects compared to other intravital microscopy systems: (1) high resolution in vivo human imaging using the cuticle as the window to a highly organized vascular bed capable of imaging single capillary loops, and (2) measurements of oxy- and deoxy-Hb levels within single capillaries and single erythrocytes. In this study, we aimed to: (1) characterize capillary morphology and hemodynamic/oxygen metabolic properties in the cuticle nailbed of individuals with SCD compared to healthy controls and (2) track single erythrocytes along the capillary loop to obtain measurements of erythrocyte elongation (ellipticity index, EI) and oxygen saturation before and after tissue oxygen exchange. We hypothesized that erythrocyte EI, as an index of HbS polymerization, would be associated with decreased arteriolar oxygen saturation and/or increased oxygen extraction fraction (OEF) across capillaries—representing compromised "oxygen reserve."

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