Saranya Veluswamy scite author profile

Alpha thalassemia is a hemoglobinopathy due to decreased production of the α‐globin protein from loss of up to four α‐globin genes, with one or two missing in the trait phenotype. Individuals with sickle cell disease who co‐inherit the loss of one or two α‐globin genes have been known to have reduced risk of morbid outcomes, but the underlying mechanism is unknown. While α‐globin gene deletions affect sickle red cell deformability, the α‐globin genes and protein are also present in the endothelial wall of human arterioles and participate in nitric oxide scavenging during vasoconstriction. Decreased production of α‐globin due to α‐thalassemia trait may thereby limit nitric oxide scavenging and promote vasodilation. To evaluate this potential mechanism, we performed flow‐mediated dilation and microvascular post‐occlusive reactive hyperemia in 27 human subjects (15 missing one or two α‐globin genes and 12 healthy controls). Flow‐mediated dilation was significantly higher in subjects with α‐trait after controlling for age (P = .0357), but microvascular perfusion was not different between groups. As none of the subjects had anemia or hemolysis, the improvement in vascular function could be attributed to the difference in α‐globin gene status. This may explain the beneficial effect of α‐globin gene loss in sickle cell disease and suggests that α‐globin gene status may play a role in other vascular diseases.

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Vaso-Occlusion in Sickle Cell Disease: Is Autonomic Dysregulation of the Microvasculature the Trigger?

Veluswamy

Shah

Denton

et al. 2019

JCM

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Sickle cell disease (SCD) is an inherited hemoglobinopathy characterized by polymerization of hemoglobin S upon deoxygenation that results in the formation of rigid sickled-shaped red blood cells that can occlude the microvasculature, which leads to sudden onsets of pain. The severity of vaso-occlusive crises (VOC) is quite variable among patients, which is not fully explained by their genetic and biological profiles. The mechanism that initiates the transition from steady state to VOC remains unknown, as is the role of clinically reported triggers such as stress, cold and pain. The rate of hemoglobin S polymerization after deoxygenation is an important determinant of vaso-occlusion. Similarly, the microvascular blood flow rate plays a critical role as fast-moving red blood cells are better able to escape the microvasculature before polymerization of deoxy-hemoglobin S causes the red cells to become rigid and lodge in small vessels. The role of the autonomic nervous system (ANS) activity in VOC initiation and propagation has been underestimated considering that the ANS is the major regulator of microvascular blood flow and that most triggers of VOC can alter the autonomic balance. Here, we will briefly review the evidence supporting the presence of ANS dysfunction in SCD, its implications in the onset of VOC, and how differences in autonomic vasoreactivity might potentially contribute to variability in VOC severity.

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Saranya Veluswamy

Mental stress causes vasoconstriction in subjects with sickle cell disease and in normal controls

Loss of alpha‐globin genes in human subjects is associated with improved nitric oxide‐mediated vascular perfusion

Vaso-Occlusion in Sickle Cell Disease: Is Autonomic Dysregulation of the Microvasculature the Trigger?

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