Ektacytometry Analysis of Post-splenectomy Red Blood Cell Properties Identifies Cell Membrane Stability Test as a Novel Biomarker of Membrane Health in Hereditary Spherocytosis.

Hereditary spherocytosis (HS) is the most common form of hereditary chronic hemolytic anemia. It is caused by mutations in red blood cell (RBC) membrane and cytoskeletal proteins, which compromise membrane integrity, leading to vesiculation. Eventually, this leads to entrapment of poorly deformable spherocytes in the spleen. Splenectomy is a procedure often performed in HS. The clinical benefit results from removing the primary site of destruction, thereby improving RBC survival. But whether changes in RBC properties contribute to the clinical benefit of splenectomy is unknown. In this study we used ektacytometry to investigate the longitudinal effects of splenectomy on RBC properties in five well-characterized HS patients at four different time points and in a case-control cohort of 26 HS patients. Osmotic gradient ektacytometry showed that splenectomy resulted in improved intracellular viscosity (hydration state) whereas total surface area and surface-to-volume ratio remained essentially unchanged. The cell membrane stability test (CMST), which assesses the in vitro response to shear stress, showed that after splenectomy, HS RBCs had partly regained the ability to shed membrane, a property of healthy RBCs, which was confirmed in the case-control cohort. In particular the CMST holds promise as a novel biomarker in HS that reflects RBC membrane health and may be used to asses treatment response in HS.

Digital microscopy as a screening tool for the diagnosis of hereditary hemolytic anemia.

INTRODUCTION: Evaluation of red blood cell (RBC) morphology is an important first step in the differential diagnosis of hereditary hemolytic anemia. It is, however, labor intensive, expensive, and prone to subjectivity. To improve and standardize the analysis of RBC morphology as a screening tool in the diagnosis of hereditary hemolytic anemia, we studied its automated analysis by digital microscopy (DM). METHODS: Blood from 90 patients with hereditary hemolytic anemia and 32 normal control subjects was analyzed by the CellaVision DM96 Digital Microscope. RESULTS: All hemolytic RBC abnormalities could be distinguished by the presence of at least one aberrant red cell type. In particular, the percentage of microcytes was highly sensitive and specific (AUCROC  = 0.97) for RBC membrane disorders, and a cut-off of 5.7% microcytes was calculated to be optimal to distinguish patients from healthy controls. Subgroup analysis of patients with RBC membrane disorders revealed additional distinct differences according to the underlying gene defect. A number of cell types were significantly elevated in sickle cell anemia patients, such as polychromatic cells, macrocytes, and poikilocytes. The increase in helmet cells (AUCROC  = 0.96) and hypochromic cells (AUCROC  = 0.91) was specific for ß-thalassemia, whereas patients with pyruvate kinase deficiency showed a significant increased polychromatic cells, macrocytes, and ovalocytes. Patients with hereditary xerocytosis showed significantly higher numbers of polychromatic cells, macrocytes, and target cells. CONCLUSION: DM holds a promise as a useful screening tool in the diagnosis of hereditary hemolytic anemia by detecting and quantifying distinct morphological changes in RBCs in patients with various forms of hereditary hemolytic anemia.