1,721,021 research outputs found
Function and malfunction of hematopoietic stem cells in primary bone marrow failure syndromes.
No full textHematopoietic stem cells (HSCs) are responsible for the production of mature blood cells in bone marrow; peripheral pancytopenia is a common clinical presentation resulting from several different conditions, including hematological or extra-hematological diseases (mostly cancers) affecting the marrow function, as well as primary failure of hematopoiesis. Primary bone marrow failure syndromes are a heterogeneous group of diseases with specific pathogenic mechanisms, which share a profound impairment of the hematopoietic stem cell pool resulting in global or selective marrow aplasia. Constitutional marrow failure syndromes are conditions caused by intrinsic defects of HSCs; they are due to inherited germline mutations accounting for specific phenotypes, and often involve also organs and systems other than hematopoiesis. By contrast, in acquired marrow failure syndromes hematopoietic stem cells are thought to be intrinsically normal, but subjected to an extrinsic damage affecting their hematopoietic function. Direct toxicity by chemicals or radiation, as well as association with viruses and other infectious agents, can be sometimes demonstrated. In idiopathic Aplastic Anemia (AA) immunological mechanisms play a pivotal role in damaging the hematopoietic compartment, resulting in a depletion of the hematopoietic stem cell pool. Clinical and experimental evidences support the presence of a T cell-mediated immune attack, as confirmed by clonally expanded lymphocytes, even if the target antigens are still undefined. However, this simple model has to be integrated with recent data showing that, even in presence of an extrinsic damage, preexisting mutations or polymorphisms of genes may constitute a genetic propensity to develop marrow failure. Other recent data suggest that similar antigen-driven immune mechanisms may be involved in marrow failure associated with lymphoproliferative or autoimmune disorders characterized by clonal expansion of T lymphocytes, such as Large Granular Lymphocyte leukemia. In this wide spectrum, a unique and intriguing condition is Paroxysmal Nocturnal Hemoglobinuria (PNH); even in presence of a somatic mutation of the PIG-A gene carried by one or more HSCs and their progeny, the typical marrow failure in PNH is likely due to pathogenic mechanisms similar to those involved in AA, and not to the intrinsic abnormality conferred to the clonal population by the PIG-A mutation. The study of hematopoietic stem cell function in marrow failure syndromes provides hints for specific molecular pathways disturbed in many diseases of hematopoietic and non-hematopoietic stem cells. Beyond the specific interest of investigators involved in the field of these rare diseases, marrow failure syndromes represent a model that provides intriguing insight into quantity and function of normal hematopoietic stem cells, improving our knowledge on stem cell biology
Circulating T regulatory cells (TREG) are decreased in patients with aplastic anemia (AA).
No full textInterferon-alpha may modulate the balance between FAS-receptor and FAS-ligand expression on bone marrow chronic myeloid leukemia cells.
No full textNovel immunosuppressive strategies for bone marrow failure syndromes: a focus on alemtuzumab.
No full textAcquired bone marrow failure syndromes (BMFS) are a heterogeneous group of hematological disorders characterized by impaired bone marrow function and subsequent cytopenia of one or more blood cell lineages [1,2]. The well-accepted pathogenic mechanism of the typical bone marrow failure - aplastic anemia (AA)- is a T cell mediated immune attack targeting the hematopoietic tissue [3]. This pathogenic mechanism is at least partially shared by other bone marrow failure syndromes, such as lineage-restricted aplasias and some myelodysplastic syndromes. Thus, for these disorders immunosuppression (IS) is the pivotal etiologic treatment. While the standard IS regimen include the heterologous anti-thymocyte globulin [4], here we review the recent data on the anti-CD52 monoclonal antibody alemtuzumab as a novel IS agent for marrow failures. Alemtuzumab led to objective responses in aplastic anemia patients in 3 recent prospective studies, with overall response rates ranging between 37% and 72%. Adverse events were irrelevant, ruling out even the concerns about the risk of infectious complications. Alemtuzumab was effective even for the treatment of lineage-restricted marrow failure, with very acceptable toxicity and excellent response rates (as high as 80%). More recently, even patients suffering from myelodysplastic syndromes showed a remarkable hematological response to alemtuzumab-based IS treatment. Thus, alemtuzumab is a novel IS agent representing an excellent alternative to ATG for all immune-mediated marrow failure syndromes. Even if the dose and the schedule may still require further refining, the available data support the need of large prospective trials comparing alemtuzumab to current standard IS regimens
Subeutaneous alemtuzumab is safe and effective for treatment of global or single-lineage immune-mediated marrow failure: A pilot study.
No full textSubcutaneous alemtuzumab as treatment option for patients with severe aplastic anemia or lineage-restricted aplasia.
No full textAchievements and limitations of complement inhibition by eculizumab in paroxysmal nocturnal hemoglobinuria: the role of complement component 3.
No full textParoxysmal nocturnal hemoglobinuria (PNH) is a hematological disorder characterized by complementmediated hemolytic anemia, thrombophilia and bone marrow failure. The clinical hallmark of PNH is evident chronic hemolysis due to the absence of the complement regulators CD55 and CD59 on PNH erythrocytes. Intravascular hemolysis drives the major clinical features of PNH, including anemia, hemoglobinuria, fatigue and other hemolysisrelated disabling symptoms, such as painful abdominal crises, dysphagia and erectile dysfunction. A peculiar thromboembolic risk has been associated with the hemolysis in PNH, but its pathophysiologic cause remains unclear. The treatment of PNH has remained supportive until a few years ago, when the first complement inhibitor, designated eculizumab, became available. Chronic treatment with eculizumab results in sustained control of intravascular hemolysis, leading to hemoglobin stabilization and transfusion independence in half of the patients. However, residual anemia may persist in a substantial fraction of patients. Recent observations by different groups, including our own, have demonstrated that residual hemolysis may be due to persistent activation of the early phases of the complement cascade, leading to progressive C3-deposition on PNH erythrocytes and possible subsequent extravascular hemolysis through the reticuloendothelial system. Here we critically review the available clinical results of eculizumab treatment for PNH patients, pointing out the recent insights into the pathophysiology of the disease. We discuss the role of the different components of the complement cascade leading to hemolysis, in both the absence and presence of the terminal effector pathway inhibition by eculizumab. Finally, we provide a theoretical rationale for the development of novel strategies of complement inhibition which could in the future further improve on the already substantial efficacy of eculizumab
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