The Comprehensive Genetic Test for Anemia utilizes next-generation sequencing (NGS) to examine 88 genes associated with disorders of erythropoiesis and red blood cell function. It is a targeted gene panel specifically designed to support accurate diagnosis, risk assessment, and prevention.
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The Comprehensive Genetic Test for Anemia is a specialized genetic test that supports molecular diagnosis in patients with suspected hereditary hematological disorders, particularly when no clear etiology can be identified through conventional laboratory testing. This test plays an important role in identifying the genetic causes underlying heterogeneous forms of hereditary anemia. It represents a valuable tool for precise diagnostic investigation, providing deeper insight into the biological mechanisms underlying the clinical manifestations.
Hereditary anemias constitute a heterogeneous group of genetic hematological disorders characterized by reduced red blood cell production or increased red blood cell destruction. These conditions may result from mutations in genes affecting hemoglobin synthesis, erythropoiesis, or the structural integrity of red blood cells. The clinical presentation varies widely, ranging from mild forms of anemia to severe conditions that require specialized diagnostic evaluation to determine the underlying genetic cause.
Most hereditary anemias are inherited in an autosomal recessive or autosomal dominant manner, depending on the gene involved and the underlying pathophysiological mechanism. Disease onset may occur during the neonatal period or early childhood, although in some cases diagnosis is established later in adulthood, particularly when symptoms are milder. The significant genetic heterogeneity of these disorders often makes etiological diagnosis difficult using conventional laboratory methods, highlighting the importance of specialized genetic testing.
The molecular basis of hereditary anemias involves mutations in numerous genes involved in red blood cell biology and hematopoiesis. The comprehensive genetic test for anemia analyzes 88 genes and enables the evaluation of both coding and non-coding genetic variants that may affect gene regulation and expression. The genes HBA1 and HBA2, which are associated with alpha-thalassemia, exhibit high sequence homology, which may reduce sensitivity for detecting certain genetic alterations, such as specific deletions or gene fusions. In addition, in severe hemophilia A, a significant proportion of patients carry inversions in intron 22 or intron 1 of the F8 gene, which are not reliably detected by this approach.
The comprehensive genetic test for anemia is designed to evaluate patients with suspected hereditary anemia, particularly when variants in HBA1 and HBA2 have already been excluded or when there is no indication that the anemia is caused by alpha-thalassemia. The test utilizes next-generation sequencing (NGS) technology to detect inherited (germline) variants. It is not intended for the detection of somatic variants in tumor tissue or for the specific detection of common F8 gene inversions.
Hereditary hematological disorders exhibit considerable genetic heterogeneity, as variants in different genes may lead to similar hematological phenotypes. For this reason, the use of multigene panels contributes to the systematic investigation of the genetic causes underlying anemia.
The test is performed in a clinical laboratory accredited to ISO 15189 and certified by CLIA and CAP, ensuring the validity, accuracy and international recognition of the results.
