Erythrocyte deformability
In hematology, erythrocyte deformability refers to the ability of erythrocytes (red blood cells, RBCs) to change shape under a given level of applied stress without hemolysing (rupturing). This is an important property because erythrocytes must change their shape extensively under the influence of mechanical forces in fluid flow or while passing through microcirculation (see hemodynamics). The extent and geometry of this shape change can be affected by the mechanical properties of the erythrocytes, the magnitude of the applied forces, and the orientation of erythrocytes with the applied forces. Deformability is an intrinsic cellular property of erythrocytes determined by geometric and material properties of the cell membrane,[1] although as with many measurable properties the ambient conditions may also be relevant factors in any given measurement. No other cells of mammalian organisms have deformability comparable with erythrocytes; furthermore, non-mammalian erythrocytes are not deformable to an extent comparable with mammalian erythrocytes. In human RBCs there are structural supports that aid resilience, which include the cytoskeleton: actin and spectrin that are held together by ankyrin.
The phenomenon
[edit]Shape change of erythrocytes under applied forces (i.e., shear forces in blood flow) is reversible and the biconcave-discoid shape, which is normal for most mammals, is maintained after the removal of the deforming forces. In other words, erythrocytes behave like elastic bodies, while they also resist to shape change under deforming forces. This viscoelastic behavior of erythrocytes is determined by the following three properties:[2] 1) Geometry of erythrocytes; the biconcave-discoid shape provides an extra surface area for the cell, enabling shape change without increasing surface area. This type of shape change requires significantly smaller forces than those required for shape change with surface area expansion. 2) Cytoplasmic viscosity; reflecting the cytoplasmic hemoglobin concentration of erythrocytes. 3) Visco-elastic properties of erythrocyte membrane, mainly determined by the special membrane skeletal network of erythrocytes.[citation needed]
Physiological significance
[edit]Erythrocyte deformability is an important determinant of blood viscosity, hence blood flow resistance in the vascular system.[3] It affects blood flow in large blood vessels, due to the increased frictional resistance between fluid laminae under laminar flow conditions. It also affects the microcirculatory blood flow significantly, where erythrocytes are forced to pass through blood vessels with diameters smaller than their size.[citation needed]
Clinical significance
[edit]Erythrocyte deformability is altered under various pathophysiological conditions. Sickle-cell disease is characterized by extensive impairment in erythrocyte deformability, being dependent on the oxygen partial pressure. Erythrocyte deformability has also been demonstrated to be impaired in diabetes, peripheral vascular diseases, sepsis and a variety of other diseases. The property offers broad utility in disease diagnosis[4] (also see Measurement, below).
Stored packed red blood cells (sometimes denoted "pRBC" or "StRBC") also experience changes in membrane properties like deformability during storage and related processing, as part of a broader phenomenon known as "storage lesion." While the clinical implications are still being explored, deformability can be indicative of quality or preservation thereof for stored RBC product available for blood transfusion.[5][6][7] Perfusion (or perfusability) is a deformability-based metric that may offer a particularly physiologically-relevant representation of storage-induced deterioration of RBC occurring in blood banks, and the associated impacts of storage conditions/systems.[8]
Measurement
[edit]Erythocyte deformability is a measurable property, and various means for its measurement have been explored - with each having results and significance being highly particularized to the given approach employed. Accordingly, the term is somewhat loose in the sense that a given cell or sample of cells may be deemed significantly more "deformable" by one means/metric relative to another means/metric. Thus for meaningful "apples-to-apples" comparisons involving cell deformability, it is important to utilize the same qualitative approach.[citation needed]
Ektacytometry based on laser diffraction analysis is a commonly preferred (and a fairly direct) method for measuring deformability.[9] Another direct metric is optical tweezers, which targets individual cells. Deformability can in effect be measured indirectly, such as by how much pressure and/or time it takes cells pass through pores of a filter (i.e., filterability or filtration)[10] or perfuse through capillaries (perfusion),[11] in vitro or in vivo, having smaller diameters than the cells'. Some deformability tests may be more physiologically-relevant than others for given applications. For example, perfusion is more sensitive to relatively small changes in deformability (compared to filterability),[12] thus making it preferable for assessing RBC deformability in contexts where microcirculatory implications are of particular interest. Moreover, some tests may track how deformability itself changes as conditions change and/or as deformation is repeated.[citation needed]
Related erythrocyte properties
[edit]Erythrocytes/RBC may also be tested for other (related) membrane properties, including erythrocyte fragility (osmotic or mechanical) and cell morphology. Morphology can be measured by indexes which characterize shape changes of differences among cells. Fragility testing involves subjecting a sample of cells to osmotic and/or mechanical stress(es), then ascertaining how much hemolysis results thereafter, and then characterizing susceptibility to or propensity for stress-induced hemolysis with an index or profile (which can be useful to assess cells' ability to withstand sustained or repeated stresses).[citation needed]
Other related red blood cell properties can include adhesion and aggregation, which along with deformability are often classed as RBC "flow properties."
References
[edit]- ^ Chien S (1987). "Red cell deformability and its relevance to blood flow". Annual Review of Physiology. 49: 177–192. doi:10.1146/annurev.ph.49.030187.001141. PMID 3551796.
- ^ Mohandas N, Chasis JA (1993). "Red blood cell deformability, membrane material properties and shape: regulation by transmembrane, skeletal and cytosolic proteins and lipids". Seminars in Hematology. 30 (3): 171–192. PMID 8211222.
- ^ Baskurt OK, Meiselman HJ (2003). "Blood rheology and hemodynamics". Seminars in Thrombosis and Hemostasis. 29 (5): 435–450. doi:10.1055/s-2003-44551. PMID 14631543.
- ^ Tillmann W (1986). "[Reduced deformability of erythrocytes as a common denominator of hemolytic anemias]". Wien Med Wochenschr. 136 Spec No: 14–6. PMID 3548086.
- ^ Decreased Erythrocyte Deformability After Transfusion and the Effects of Erythrocyte Storage Duration, Anesth Analg, published ahead of print February 28, 2013
- ^ Journal of Blood Transfusion, Volume 2012, Article ID 102809
- ^ Ann Ist Super Sanita 2007; 43(2):176-85.
- ^ Transfusion. 2012 May;52(5):1010-23. Artificial microvascular network: a new tool for measuring rheologic properties of stored red blood cells. Burns JM, Yang X, Forouzan O, Sosa JM, Shevkoplyas SS.
- ^ Baskurt OK; Hardeman; M.R. Uyuklu M; et al. (2009). "Comparison of three commercially available ektacytometers with different shearing geometries". Biorheology. 46 (3): 251–264. doi:10.3233/BIR-2009-0536. PMID 19581731.
- ^ Advances in Hemodynamics and Hemorheology, Volume 1, edited by T.V. How
- ^ Lab Chip. 2006 Jul;6(7):914-20. Direct measurement of the impact of impaired erythrocyte deformability on microvascular network perfusion in a microfluidic device. Shevkoplyas SS, Yoshida T, Gifford SC, Bitensky MW.
- ^ Lab Chip. 2006 Jul;6(7):914-20. Direct measurement of the impact of impaired erythrocyte deformability on microvascular network perfusion in a microfluidic device. Shevkoplyas SS, Yoshida T, Gifford SC, Bitensky MW.