The Role of Inflammation and Leukocytes in the Pathogenesis of Sickle Cell Disease; Haemoglobinopathy

Overview

Journal Hematology

Specialty Hematology

Date 2001 Jun 16

PMID 11399640

Citations 23

Authors

Ted Wun

Affiliations

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Abstract

Acute and chronic vascular occlusion underlies much of the morbidity and mortality in sickle disease. Abnormal polymerization of deoxygenated hemoglobin S (HbS) resulting in stiff, non-deformable erythrocytes is central to sickle cell pathogenesis. However, a complex interplay of many factors determines the balance between adequate blood flow and vessel obstruction. Serum markers of inflammation have provided evidence for a state of chronic inflammation in sickle cell disease (SCD). Inflammation promotes endothelial adherence to sickle erythrocytes. Studies demonstrating a beneficial effect of steroid therapy for painful episodes and acute chest syndrome provide indirect evidence for the role of inflammation in this disease. Leukocytosis, in the absence of infection, is common in SCD patients and predicts for stroke, acute chest syndrome, and overall mortality. Neutrophils and monocytes have been shown to be activated in these patients. Activated leukocytes further promote vascular inflammation and vessel damage. A reduction in leukocytes, and thus inflammation, may partially explain the beneficial effects of hydroxyurea in this disease. These data provide a strong rationale for clinical studies of therapy directed at inflammation and/or leukocytes in sickle cell disease.

Citing Articles

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Sickle Cell Disease in Children and Adolescents: A Review of the Historical, Clinical, and Public Health Perspective of Sub-Saharan Africa and Beyond.

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