S A Wong1, B I Dalal2, H A Leitch3. 1. Faculty of Medicine, The Royal College of Surgeons, Dublin, Ireland. 2. Department of Hematopathology, Vancouver General Hospital, Vancouver, BC. 3. Division of Hematology, St. Paul's Hospital and the University of British Columbia, Vancouver, BC.
Abstract
Background: Myelodysplastic syndrome (mds) is characterized by peripheral blood cytopenias, with most patients developing significant anemia and dependence on red blood cell (rbc) transfusion. In paroxysmal nocturnal hemoglobinuria (pnh), mutations in the PIGA gene lead to lack of cell-surface glycosylphosphatidylinositol, allowing complement-mediated lysis to occur. Paroxysmal nocturnal hemoglobinuria results in direct antiglobulin test-negative hemolysis and cytopenias, and up to 50% of patients with mds test positive for pnh cells. We wanted to determine whether pnh is considered to be a contributor to anemia in mds. Methods: Patients with a diagnosis of mds confirmed by bone-marrow biopsy since 2009 were reviewed. High-resolution pnh testing by flow cytometry examined flaer (fluorescein-labeled proaerolysin) binding and expression of CD14, CD15, CD24, CD45, CD59, CD64, and CD235 on neutrophils, monocytes, and rbcs. Results: In 152 patients with mds diagnosed in 2009 or later, the mds diagnosis included subtypes associated with pnh positivity (refractory anemia, n = 7, and hypoplastic mds, n = 4). Of 11 patients who underwent pnh testing, 1 was positive (9.0%). Reasons for pnh testing were anemia (n = 3), new mds diagnosis (n = 2), hypoplastic mds (n = 2), decreased haptoglobin (n= 1), increased rbc transfusion requirement (n= 1), and unexplained iron deficiency (n= 1). Conclusions: Testing for pnh was infrequent in mds patients, and the criteria for testing were heterogeneous. Clinical indicators prompted pnh testing in 6 of 11 patients. Given that effective treatment is now available for pnh and that patients with pnh-positive mds can respond to immunosuppressive therapy, pnh testing in mds should be considered. Prospective analyses to clarify the clinical significance of pnh positivity in mds are warranted.
Background: Myelodysplastic syndrome (mds) is characterized by peripheral blood cytopenias, with most patients developing significant anemia and dependence on red blood cell (rbc) transfusion. In paroxysmal nocturnal hemoglobinuria (pnh), mutations in the PIGA gene lead to lack of cell-surface glycosylphosphatidylinositol, allowing complement-mediated lysis to occur. Paroxysmal nocturnal hemoglobinuria results in direct antiglobulin test-negative hemolysis and cytopenias, and up to 50% of patients with mds test positive for pnh cells. We wanted to determine whether pnh is considered to be a contributor to anemia in mds. Methods:Patients with a diagnosis of mds confirmed by bone-marrow biopsy since 2009 were reviewed. High-resolution pnh testing by flow cytometry examined flaer (fluorescein-labeled proaerolysin) binding and expression of CD14, CD15, CD24, CD45, CD59, CD64, and CD235 on neutrophils, monocytes, and rbcs. Results: In 152 patients with mds diagnosed in 2009 or later, the mds diagnosis included subtypes associated with pnh positivity (refractory anemia, n = 7, and hypoplastic mds, n = 4). Of 11 patients who underwent pnh testing, 1 was positive (9.0%). Reasons for pnh testing were anemia (n = 3), new mds diagnosis (n = 2), hypoplastic mds (n = 2), decreased haptoglobin (n= 1), increased rbc transfusion requirement (n= 1), and unexplained iron deficiency (n= 1). Conclusions: Testing for pnh was infrequent in mds patients, and the criteria for testing were heterogeneous. Clinical indicators prompted pnh testing in 6 of 11 patients. Given that effective treatment is now available for pnh and that patients with pnh-positive mds can respond to immunosuppressive therapy, pnh testing in mds should be considered. Prospective analyses to clarify the clinical significance of pnh positivity in mds are warranted.
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