Key Points Dehydrated hereditary stomatocytosis is characterized by abnormal RBC morphology but may involve pseudohyperkalemia and perinatal edema. This syndrome is associated with germline mutations in PIEZO1, encoding a transmembrane protein that induces mechanosensitive currents.
The antiviral drug ribavirin (RBV) is widely used in combination with interferon (IFN) in the treatment of chronic hepatitis C virus (HCV) infection. A major side effect of RBV is a reversible hemolytic anemia. We have evaluated the in vitro effects of RBV on erythrocyte adenosine triphosphate (ATP) content and on hexosemonophosphate shunt (HMS). The ATP levels were significantly decreased in the presence of RBV and the HMS was increased, suggesting the presence of red cell susceptibility to oxidation. In vivo, we have studied the hematologic effects of treatment with RBV alone or in combination with IFN in 11 patients with chronic hepatitis C: 6 were treated with RBV (1,000-1,200 mg/d) and 5 were treated with a combination of RBV and IFN (5 million U thrice weekly). Patients were studied at semi-monthly intervals from 0 to day 60 of therapy. Both treatments were associated with a significant reduction in hemoglobin levels (steady state level at day 45) and a marked increase in absolute reticulocyte counts. Erythrocyte Na-K pump activity was significantly diminished, whereas K-Cl cotransport and its dithiotreitol-sensitive fraction, malondialdehyde and methemoglobin levels were significantly increased. RBV-treated patients showed an increase in aggregated band 3, which was associated with a significantly increased binding of autologous antibodies and complement C3 fragments indicating an erithrophagocytic removal by reticuloendothelial system. (HEPATOLOGY 2000;31:997-1004.)Hepatitis C virus (HCV) infection is a major cause of chronic liver disease, leading to cirrhosis, end-stage liver disease, and hepatocellular carcinoma worldwide. 1,2 A major therapeutic goal in HCV-infected patients is to achieve early eradication of the virus, and to prevent severe long-term clinical complications. Interferon alfa (IFN-␣) is currently the only therapy that has been shown to have beneficial effects in chronic hepatitis type C. However, with a standard regimen of 3 million U administered 3 times per week for 6 to 12 months, only a small fraction of approximately 15% to 20% of the patients showed a sustained response with normalization of serum alanine transferase levels and serum HCV-RNA clearance. 3 Ribavirin (1--D-ribofuranosyl-1H-1, 2,4-triazole-3-carboxamide) (RBV) is a water soluble synthetic guanosine analog that exerts antiviral activity against DNA and RNA viruses after intracellular phosphorylation. 4 Current studies indicate that combination therapy with RBV and IFN is associated with higher rates of sustained virological, biochemical, and histological response compared to IFN monotherapy. [5][6][7][8][9][10] The major side effect of RBV treatment is the occurrence of a reversible hemolytic anemia in a substantial proportion of treated patients. 11 The underlying mechanism is unknown. Studies on steady-state pharmacokinetics of RBV have shown that erythrocyte concentration of RBV greatly exceeds plasma concentrations 12 and that RBV is a transported permeant for the (es) nucleoside transporter in human erythrocytes...
We have investigated the interaction of clotrimazole (CLT) and related compounds with the erythroid Ca2"-activated K+ channel, a mediator of sickle cell dehydration. We measured K+ transport, membrane potential, and cell volume upon activation of this pathway in sickle erythrocytes. CLT blocked almost completely Ca2"-activated K+ transport in homozygous hemoglobin S cells, with IC5o values of 29±15 nM in isotonic 20 mM salt solution and 51±15 nM in normal saline (n = 3). The inhibition of K+ transport by CLT was caused by a specific interaction with the Ca2"-activated K+ channel of human red cells, since it displaced bound 125I-Charybdotoxin, a specific ligand of the Gardos channel, with an IC50 (12±4 nM in isotonic 20 mM) similar to the IC50 values for flux inhibition. When homozygous hemoglobin S cells were dehydrated by incubation in the presence of 100 ,gM CaCI2 and the ionophore A23187, or by exposure to cycles of oxygenation and deoxygenation, CLT effectively inhibited cell dehydration and K+ loss. The IC50 of CLT for inhibition of Ca2+-activated K+ transport in sickle cells is significantly lower than plasma concentrations of CLT achievable after nontoxic oral doses. We therefore propose that oral administration of CLT may prevent red cell dehydration in patients with sickle cell anemia. (J. Clin. Invest. 1993. 92:520-526.)
Background-Hemolytic diseases are characterized by enhanced intravascular hemolysis resulting in heme-catalyzed reactive oxygen species generation, which leads to endothelial dysfunction and oxidative damage. Hemopexin (Hx) is a plasma heme scavenger able to prevent endothelial damage and tissue congestion in a model of heme overload. Here, we tested whether Hx could be used as a therapeutic tool to counteract heme toxic effects on the cardiovascular system in hemolytic diseases. Methods and Results-By using a model of heme overload in Hx-null mice, we demonstrated that heme excess in plasma, if not bound to Hx, promoted the production of reactive oxygen species and the induction of adhesion molecules and caused the reduction of nitric oxide availability. Then, we used β-thalassemia and sickle cell disease mice as models of hemolytic diseases to evaluate the efficacy of an Hx-based therapy in the treatment of vascular dysfunction related to heme overload. Our data demonstrated that Hx prevented heme-iron loading in the cardiovascular system, thus limiting the production of reactive oxygen species, the induction of adhesion molecules, and the oxidative inactivation of nitric oxide synthase/nitric oxide, and promoted heme recovery and detoxification by the liver mainly through the induction of heme oxygenase activity. Moreover, we showed that in sickle cell disease mice, endothelial activation and oxidation were associated with increased blood pressure and altered cardiac function, and the administration of exogenous Hx was found to almost completely normalize these parameters. 12,13,16 In hemolytic diseases, the high rate of hemolysis results in the saturation and depletion of the plasma Hb/heme scavenging systems 17 and leads to a buildup of Hb and heme in the circulation that mediates pro-oxidant and proinflammatory effects on vessel endothelial cells. Conclusions-Hemopexin 18Although many mechanisms contribute to the complex pathophysiology of hemolytic diseases as SCD and β-thalassemia, a unifying theme is represented by the dysfunction of the vascular endothelium and the highly pro-oxidant plasma environment. 1,[19][20][21][22] SCD is characterized by recurring episodes of painful vasoocclusion, leading to ischemia/reperfusion injury and organ damage.6,23 Endothelial dysfunction, inflammation, and activated monocytes, neutrophils, platelets, and dense red cells all contribute to sickle cell crisis.4,23 β -Thalassemia is frequently complicated by thromboembolic events resulting from coagulation abnormalities and damaged red cells exposing phosphatidylserine, to which endothelial activation and oxidative stress strongly contribute. 3,23,24 Moreover, severe forms of SCD and β-thalassemia require a blood transfusion regimen that further increases the amount of circulating Hb/heme, thus exacerbating oxidative stress. 25,26 Although an iron chelation therapy is routinely associated with a transfusion regimen, 27,28 no heme chelation therapy has been developed to date that specifically prevents heme-induced endot...
Key Points• The study establishes a reliable method to quantify differentiating mouse erythroblasts and to monitor terminal mouse erythropoiesis in vivo.• Quantitative analysis of erythropoiesis of thalassemia mice revealed stage-specific changes in terminal erythroid differentiation.Terminal erythroid differentiation is the process during which proerythroblasts differentiate to produce enucleated reticulocytes. Although it is well established that during murine erythropoiesis in vivo, 1 proerythroblast undergoes 3 mitosis to generate sequentially 2 basophilic, 4 polychromatic, and 8 orthochromatic erythroblasts, currently there is no method to quantitatively monitor this highly regulated process. Here we outline a method that distinguishes each distinct stage of erythroid differentiation in cells from mouse bone marrow and spleen based on expression levels of TER119, CD44, and cell size. Quantitative analysis revealed that the ratio of proerythroblasts:basophilic: polychromatic:orthromatic erythroblasts follows the expected 1:2:4:8 ratio, reflecting the physiologic progression of terminal erythroid differentiation in normal mice. Moreover, in 2 stress erythropoiesis mouse models, phlebotomy-induced acute anemia and chronic hemolytic anemia because of 4.1R deficiency, the ratio of these erythroblast populations remains the same as that of wild-type bone marrow. In contrast, in anemic -thalassemia intermedia mice, there is altered progression which is restored to normal by transferrin treatment which was previously shown to ameliorate the anemic phenotype. The means to quantitate in vivo murine erythropoiesis using our approach will probably have broad application in the study of altered erythropoiesis in various red cell disorders. (Blood. 2013;121(8):e43-e49)
Sickle cell disease (SCD) is characterized by the presence of sickle hemoglobin, which has the unique property of polymerizing when deoxygenated. The pathophysiology of acute and chronic clinical manifestations of SCD have shown the central role of dense, dehydrated red cells in acute and chronic clinical manifestations of this pathology. Recent studies have indicated that SCD is characterized by a hypercoagulable state that contributes to the vaso-occlusive events in microcirculation, leading to acute and chronic sickle cell-related organ damage. This review discusses, in the context of SCD, (1) abnormalities in the coagulation system, (2) perturbation of platelet activation and aggregation, (3) vascular endothelial dysfunction, (4) the contribution of cell inflammatory responses, and (5) the connection with nitric oxide metabolism. We also review the available studies on the therapeutic approaches in clinical management of hypercoagulability in SCD.
Hereditary hemolytic anemias are a group of disorders with a variety of causes, including red cell membrane defects, red blood cell enzyme disorders, congenital dyserythropoietic anemias, thalassemia syndromes and hemoglobinopathies. As damaged red blood cells passing through the red pulp of the spleen are removed by splenic macrophages, splenectomy is one possible therapeutic approach to the management of severely affected patients. However, except for hereditary spherocytosis for which the effectiveness of splenectomy has been well documented, the efficacy of splenectomy in other anemias within this group has yet to be determined and there are concerns regarding short- and long-term infectious and thrombotic complications. In light of the priorities identified by the European Hematology Association Roadmap we generated specific recommendations for each disorder, except thalassemia syndromes for which there are other, recent guidelines. Our recommendations are intended to enable clinicians to achieve better informed decisions on disease management by splenectomy, on the type of splenectomy and the possible consequences. As no randomized clinical trials, case control or cohort studies regarding splenectomy in these disorders were found in the literature, recommendations for each disease were based on expert opinion and were subsequently critically revised and modified by the Splenectomy in Rare Anemias Study Group, which includes hematologists caring for both adults and children.
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