Structure and deformation properties of red blood cells: concepts and quantitative methods - PubMed (original) (raw)
Review
Structure and deformation properties of red blood cells: concepts and quantitative methods
E A Evans. Methods Enzymol. 1989.
Abstract
The lamellar configuration of the red cell membrane includes a (liquid) superficial bilayer of amphiphilic molecules supported by a (rigid) subsurface protein meshwork. Because of this composite structure, the red cell membrane exhibits very large resistance to changes in surface density or area with very low resistance to in-plane extension and bending deformations. The primary extrinsic factor in cell deformability is the surface area-to-volume ratio which establishes the minimum-caliber vessel into which a cell can deform (without rupture). Within the restriction provided by surface area and volume, the intrinsic properties of the membrane and cytoplasm determine the deformability characteristics of the red cell. Since the cytoplasm is liquid, the static rigidity of the cell is determined by membrane elastic constants. These include an elastic modulus for area compressibility in the range of 300-600 dyn/cm, an elastic modulus for in-plane extension or shear (at constant area) of 5-7 X 10(-3) dyn/cm, and a curvature or bending elastic modulus on the order of 10(-12) dyn.cm. Even though small, the surface rigidity of the cell membrane is sufficient to return the membrane capsule to a discoid shape after deformation by external forces. Viscous dissipation in the peripheral protein structure (cytoskeleton) dominates the dynamic response of the cell to extensional forces. Based on a time constant for recovery after extensional deformation on the order of 0.1 sec, the coefficient of surface viscosity is on the order of 10(-3) dyn.sec/cm. On the other hand, the dynamic resistance to folding of the cell appears to be limited by viscous dissipation in the cytoplasmic and external fluid phases. Dynamic rigidities for both extensional and folding deformations are important factors in the distribution of flow in the small microvessels. Although the red cell membrane normally behaves as a resilient viscoelastic shell, which recovers its conformation after deformation, structural relaxation and failure lead to break-up and fragmentation of the red cell. The levels of membrane extensional force which is two orders of magnitude less than the level of tension necessary to lyse vesicles by rapid area dilation. Each of the material properties ascribed to the red cell membrane plays an important role in the deformability and survivability of the red cell in the circulation over its several-month life span.
Similar articles
- Deformability and intrinsic material properties of neonatal red blood cells.
Linderkamp O, Nash GB, Wu PY, Meiselman HJ. Linderkamp O, et al. Blood. 1986 May;67(5):1244-50. Blood. 1986. PMID: 3697506 - The influence of membrane skeleton on red cell deformability, membrane material properties, and shape.
Mohandas N, Chasis JA, Shohet SB. Mohandas N, et al. Semin Hematol. 1983 Jul;20(3):225-42. Semin Hematol. 1983. PMID: 6353591 Review. - Mechanical fragility of erythrocyte membrane in neonates and adults.
Böhler T, Leo A, Stadler A, Linderkamp O. Böhler T, et al. Pediatr Res. 1992 Jul;32(1):92-6. doi: 10.1203/00006450-199207000-00018. Pediatr Res. 1992. PMID: 1635851 - Measuring the mechanical properties of individual human blood cells.
Hochmuth RM. Hochmuth RM. J Biomech Eng. 1993 Nov;115(4B):515-9. doi: 10.1115/1.2895533. J Biomech Eng. 1993. PMID: 8302034 Review.
Cited by
- Cellular normoxic biophysical markers of hydroxyurea treatment in sickle cell disease.
Hosseini P, Abidi SZ, Du E, Papageorgiou DP, Choi Y, Park Y, Higgins JM, Kato GJ, Suresh S, Dao M, Yaqoob Z, So PT. Hosseini P, et al. Proc Natl Acad Sci U S A. 2016 Aug 23;113(34):9527-32. doi: 10.1073/pnas.1610435113. Epub 2016 Aug 10. Proc Natl Acad Sci U S A. 2016. PMID: 27512047 Free PMC article. - Temperature transition of human hemoglobin at body temperature: effects of calcium.
Kelemen C, Chien S, Artmann GM. Kelemen C, et al. Biophys J. 2001 Jun;80(6):2622-30. doi: 10.1016/S0006-3495(01)76232-7. Biophys J. 2001. PMID: 11371439 Free PMC article. - Effect of Cell Age and Membrane Rigidity on Red Blood Cell Shape in Capillary Flow.
Nouaman M, Darras A, John T, Simionato G, Rab MAE, van Wijk R, Laschke MW, Kaestner L, Wagner C, Recktenwald SM. Nouaman M, et al. Cells. 2023 Jun 1;12(11):1529. doi: 10.3390/cells12111529. Cells. 2023. PMID: 37296651 Free PMC article. - The role of cellular traction forces in deciphering nuclear mechanics.
Joshi R, Han SB, Cho WK, Kim DH. Joshi R, et al. Biomater Res. 2022 Sep 8;26(1):43. doi: 10.1186/s40824-022-00289-z. Biomater Res. 2022. PMID: 36076274 Free PMC article. Review. - A New Computational Method for Membrane Compressibility: Bilayer Mechanical Thickness Revisited.
Doktorova M, LeVine MV, Khelashvili G, Weinstein H. Doktorova M, et al. Biophys J. 2019 Feb 5;116(3):487-502. doi: 10.1016/j.bpj.2018.12.016. Epub 2019 Jan 3. Biophys J. 2019. PMID: 30665693 Free PMC article.