Paroxysmal nocturnal hemoglobinuria: an historical overview

Thrombosis in Paroxysmal Nocturnal Hemoglobinuria (PNH): From Pathogenesis to Treatment

Paroxysmal Nocturnal Hemoglobinuria (PNH) constitutes a rare bone marrow failure syndrome characterized by hemolytic anemia, thrombotic events (TEs), and bone marrow aplasia of variable degrees. Thrombosis is one of the major clinical manifestations of the disease, affecting up to 40% of individuals with PNH. Venous thrombosis is more prevalent, affecting mainly unusual sites, such as intrabdominal and hepatic veins. TEs might be the first clinical manifestation of PNH. Complement activation, endothelial dysfunction, hemolysis, impaired bioavailability of nitric oxide, and activation of platelets and neutrophils are implicated in the pathogenesis of TEs in PNH patients. Moreover, a vicious cycle involving the coagulation cascade, complement system, and inflammation cytokines, such as interleukin-6, is established. Complement inhibitors, such as eculizumab and ravulizumab (C5 inhibitors), have revolutionized the care of patients with PNH. C5 inhibitors should be initiated in patients with PNH and thrombosis, while they constitute a great prophylactic measure for TEs in those individuals. Anticoagulants, such as warfarin and low-molecular-weight heparin, and, in selected cases, direct oral anticoagulants (DOACs) should be used in combination with C5 inhibitors in patients who develop TEs. Novel complement inhibitors are considered an alternative treatment option, especially for those who develop extravascular or breakthrough hemolysis when terminal inhibitors are administered.

A novel soluble complement receptor 1 fragment with enhanced therapeutic potential

Human complement receptor 1 (HuCR1) is a pivotal regulator of complement activity, acting on all three complement pathways as a membrane-bound receptor of C3b/C4b, C3/C5 convertase decay accelerator, and cofactor for factor I-mediated cleavage of C3b and C4b. In this study, we sought to identify a minimal soluble fragment of HuCR1, which retains the complement regulatory activity of the wildtype protein. To this end, we generated recombinant, soluble, and truncated versions of HuCR1 and compared their ability to inhibit complement activation in vitro using multiple assays. A soluble form of HuCR1, truncated at amino acid 1392 and designated CSL040, was found to be a more potent inhibitor than all other truncation variants tested. CSL040 retained its affinity to both C3b and C4b as well as its cleavage and decay acceleration activity and was found to be stable under a range of buffer conditions. Pharmacokinetic studies in mice demonstrated that the level of sialylation is a major determinant of CSL040 clearance in vivo. CSL040 also showed an improved pharmacokinetic profile compared with the full extracellular domain of HuCR1. The in vivo effects of CSL040 on acute complement-mediated kidney damage were tested in an attenuated passive antiglomerular basement membrane antibody-induced glomerulonephritis model. In this model, CSL040 at 20 and 60 mg/kg significantly attenuated kidney damage at 24 h, with significant reductions in cellular infiltrates and urine albumin, consistent with protection from kidney damage. CSL040 thus represents a potential therapeutic candidate for the treatment of complement-mediated disorders.

A novel marker for screening paroxysmal nocturnal hemoglobinuria using routine complete blood count and cell population data

Background

Final diagnosis of paroxysmal nocturnal hemoglobinuria (PNH) may take years demanding a quick diagnosis measure. We used the facts that PNH cells are damaged in acid, and reagents for measuring reticulocytes in Coulter DxH800 (Beckman Coulter, USA) are weakly acidic and hypotonic, to create a new PNH screening marker.

Methods

We analyzed 979 complete blood counts (CBC) data from 963 patients including 57 data from 44 PNH patients. Standard criteria for PNH assay for population selection were followed: flow cytometry for CD55 and CD59 on red blood cells (RBCs) to a detection level of 1%; and fluorescent aerolysin, CD24 and CD15 in granulocytes to 0.1%. Twenty-four PNH minor clone-positive samples (minor-PNH+) were taken, in which the clone population was <5% of RBCs and/or granulocytes. Excluding PNH and minor-PNH+ patients, the population was divided into anemia, malignancy, infection, and normal groups. Parameters exhibiting a distinct demarcation between PNH and non-PNH groups were identified, and each parameter cutoff value was sought that includes the maximum [minimum] number of PNH [non-PNH] patients.

Results

Cutoff values for 5 selected CBC parameters (MRV, RDWR, MSCV, MN-AL2-NRET, and IRF) were determined. Positive rates were: PNH (86.0%), minor-PNH+ (33.3%), others (5.0%), anemia (13.4%), malignancy (5.3%), infection (3.7%), normal (0.0%); within anemia group, aplastic anemia (40.0%), immune hemolytic anemia (11.1%), iron deficiency anemia (1.6%). Sensitivity (86.0%), specificity (95.0%), PPV (52.1%), and NPV (99.1%) were achieved in PNH screening.

Conclusion

A new PNH screening marker is proposed with 95% specificity and 86% sensitivity. The flag identifies PNH patients, reducing time to final diagnosis by flow cytometry.

Laboratory tests for paroxysmal nocturnal hemoglobinuria

Paroxysmal nocturnal hemoglobinuria (PNH) is a rare hematological disorder that is often suspected in a patient presenting with non-immune hemolytic anemia associated with pancytopenia or venous thrombosis. This disorder is a consequence of acquired somatic mutations in the phosphatidylinositol glycan class A (PIG-A) gene in the hematopoietic stem cells (HSC) of patients. The presence of these mutations leads to production of blood cells with decreased glycosyl phosphatidylinositol-anchored cell surface proteins, making red blood cells derived from the clone more sensitive to complement mediated hemolysis. The diagnosis of PNH may be difficult in some cases due a low proportion of PNH cells in the blood and occasionally due to difficulties in selecting the most appropriate diagnostic studies. The latest generation of tests allow for detection of very small populations of PNH cells, for following the natural course and response to therapy of the disease, and for helping to decide when to initiate therapy with monoclonal antibody targeting the terminal complement protein C5 (Eculizumab), anticoagulation, and in some cases allogeneic HSC transplant. In this article, we review the different diagnostic tests available to clinicians for PNH diagnosis.

Anemias beyond B12 and iron deficiency: the buzz about other B's, elementary, and nonelementary problems

The term “unexplained anemia” appears frequently in a request for a hematology consultation. Although most anemia consultations are fairly routine, they occasionally represent challenging problems that require an amalgam of experience, insight, and a modicum of “out-of-the-box” thinking. Problem anemia cases and pitfalls in their recognition can arise for one of several reasons that are discussed in the cases presented herein. “Anemias beyond B12 and iron deficiency” covers a vast domain of everything that lies beyond the commonly encountered anemias caused by simple deficiencies of 2 currently major hematologically relevant micronutrients. However, even these deficiencies may be obscured when they coexist or are not considered because of misleading distractions. They may also be mistakenly identified when other less common nutrient deficiencies occur. I present herein case examples of such situations: a young patient with pancytopenia and schistocytes who was responsive to plasmapheresis, but in whom pernicious anemia was not suspected because of ethnicity and age; a bicytopenic patient with anemia and myelodysplastic features caused by copper deficiency after gastric reduction surgery; and a patient with BM hypoplasia and a dimorphic blood smear who was found to have paroxysmal nocturnal hemoglobinuria. These “pearls” represent but 3 examples of the many varieties of problems in anemia diagnosis and are used to illustrate potential pitfalls and how to avoid them.

Management of Paroxysmal Nocturnal Hemoglobinuria in the Era of Complement Inhibitory Therapy

Despite the availability of safe, effective targeted therapy that controls intravascular hemolysis, the management of paroxysmal nocturnal hemoglobinuria (PNH) remains complicated because of disease heterogeneity and close association with BM failure syndromes. The purpose of this review is to provide a framework for individualizing treatment based on disease classification. According to the recommendations of the International PNH Interest Group, patients can be placed into one of the following 3 categories: (1) classic PNH, (2) PNH in the setting of another BM failure syndrome, or (3) subclinical PNH. The PNH clone in patients with subclinical disease is insufficiently large to produce even biochemical evidence of hemolysis, and consequently, patients who fit into this category require no PNH-specific therapy. Patients with PNH in the setting of another BM failure syndrome (usually aplastic anemia or low-risk myelodysplastic syndrome) have at least biochemical evidence of hemolysis, but typically the PNH clone is small (< 10%) so that hemolysis does not contribute significantly to the underlying anemia. In these cases, the focus of treatment is on the BM failure component of the disease. Intravascular hemolysis is the dominant feature of classic PNH, and this process is blocked by the complement inhibitor eculizumab. The thrombophilia of PNH also appears to be ameliorated by eculizumab, but the drug has no effect on the BM failure component of the disease. Low-grade extravascular hemolysis due to complement C3 opsonization develops in most patients treated with eculizumab, and in some cases is a cause for suboptimal response to treatment. Allogeneic BM transplantation can cure classic PNH, but treatment-related toxicity suggests caution for this approach to management.

New frontiers in transfusion biology: identification and significance of mediators of morbidity and mortality in stored red blood cells

Red blood cell (RBC) transfusions are associated with inflammation and thrombosis, both arterial and venous, the mechanisms of which are not understood. Although a necessary life-saving procedure in modern medicine, transfusions have rarely been subjected to modern assessments of efficacy and safety, including randomized trials. Storage of RBCs induces changes, including the release of free hemoglobin and the accumulation of biologically active soluble mediators and microparticles. These mediators likely play a direct role in the inflammatory and prothrombotic properties of RBC transfusions. Methods such as leukoreduction, washing of RBCs, and rejuvenation may improve the quality of RBC transfusions.

Rethinking the prosaicism of mosaicism; is it in us?

Exponential advances in the quantitation of DNA variation and epigenetic states seem poised to convert much of biological research into a statistical exercise. But these developments also invite us to reimagine well-worn biological concepts on a grander scale. Somatic mosaicism refers to postzygotic mutations persisting in the individual, occasionally conspicuous to dermatologists as Blaschkoid, checkerboard, phylloid and patchy morphologies. A thoughtful examination of cutaneous mosaicism suggests, however, that virtually all of us may be somatic mosaics. Such genetic variability within individuals might explain localized presentations of disease and implies that some tissues literally evolve throughout life. We discuss here (i) the likely ubiquity of somatic mosaicism, (ii) the broad range of possible biological consequences and (iii) how experimentalists and clinicians may begin establishing genotype-to-phenotype correlates.

A case report of concomitant paroxysmal nocturnal hemoglobinuria and heterozygous β-thalassemia

Paroxysmal nocturnal hemoglobinuria (PNH) is a rare clonal blood disorder that presents chronic intravascular hemolysis. PNH concomitant with inherited hemolytic anemia has been rarely reported. Here, we report an interesting PNH patient who was misdiagnosed with iron deficiency anemia due to concomitant heterozygous β-thalassemia. The patient experienced dizziness, fatigue, and restricted physical activity for the previous 3 years. Thalassemia gene analysis revealed heterozygous β-thalassemia. Iron staining of the bone marrow demonstrated the absence of stainable iron and sideroblasts. The patient was diagnosed with iron deficiency anemia. Iron supplementation treatment was performed, but the anemia remained unresolved. The patient became transfusion dependent 1 year later and was admitted to our hospital in March 2010. Flow cytometry of the patient's peripheral blood demonstrated that 7.9% and 11.9% of the erythrocytes were CD59 and CD55 deficient, respectively. The patient was finally diagnosed with concomitant PNH and heterozygous β-thalassemia.

The case for complement and inflammation in AMD: open questions

The complement cascade has been identified as a key factor in the pathogenesis of age-related macular degeneration (AMD). As a result, pharmacological modulation of the complement cascade is being investigated as a therapeutic strategy for AMD. The genetic data point to a triggering of the complement cascade, which subsequently cannot be damped down. Despite promising genetic, preclinical and immunolabeling data, important questions remain to be answered regarding the role of complement in the pathogenesis of AMD. The involvement of the complement cascade in the vision threatening stages of AMD, e.g. geographic atrophy and choroidal neovascularization, remain unknown. Additionally, the optimal component(s) of the complement cascade to be targeted for modulation still need to be identified. Answering these and other questions will provide investigators with a clear framework with which to evaluate progress in the field and help guide the development of future clinical therapeutics.