The Comprehensive Genetic Test for Fanconi Anemia utilizes next-generation sequencing (NGS) to examine 24 genes associated with DNA repair defects and bone marrow failure. It is a targeted gene panel specifically designed to support accurate diagnosis, risk assessment, and prevention.
More Information
The Comprehensive Genetic Test for Fanconi Anemia is a targeted genetic test designed to evaluate hereditary causes of bone marrow failure syndromes, particularly Fanconi anemia and related chromosomal instability disorders. The comprehensive genetic test for Fanconi anemia includes the analysis of a set of genes, along with selected non-coding variants, enabling a comprehensive assessment of genetic defects associated with impaired DNA repair mechanisms. It is particularly suitable for individuals with a clinical suspicion of Fanconi anemia or Nijmegen breakage syndrome. These conditions are characterized by genomic instability, leading to hematological abnormalities, congenital malformations, and an increased predisposition to malignancies, often presenting early in life.
The comprehensive genetic test for Fanconi anemia includes key genes such as FANCA, FANCC, FANCG, BRCA2 (FANCD1), and NBN, which are involved in DNA damage recognition and repair pathways. FANCA, FANCC, and FANCG are part of the Fanconi anemia core complex responsible for maintaining genomic integrity, while BRCA2 plays a critical role in homologous recombination repair. NBN is essential for DNA double-strand break repair and cellular response to genomic damage. Disruptions in these pathways result in chromosomal instability and defective cell cycle control. The comprehensive genetic test for Fanconi anemia is indicated in individuals presenting with clinical features suggestive of Fanconi anemia or related DNA repair disorders.
The clinical spectrum of Fanconi anemia is broad and includes progressive bone marrow failure, typically presenting in childhood with pancytopenia. Affected individuals often exhibit congenital anomalies such as short stature, skin pigmentation abnormalities, cardiac and renal defects, and limb malformations, particularly involving the radial ray. Additional features may include mild microcephaly and endocrine abnormalities. There is a significantly increased risk of developing hematologic malignancies, especially acute myeloid leukemia, as well as solid tumors in adulthood. Clinical variability is considerable, with some individuals presenting with severe early manifestations and others with milder or later-onset disease, complicating diagnosis.
The purpose of the comprehensive genetic test for Fanconi anemia is to identify pathogenic variants associated with Fanconi anemia and related syndromes, supporting accurate diagnosis and differentiation from other chromosomal instability disorders. Genetic findings contribute to a better understanding of disease mechanisms and facilitate early recognition of cancer risk and associated complications. The identification of specific genetic alterations supports risk stratification and informs long-term monitoring strategies, including the assessment of potential involvement of multiple organ systems.
A higher genetic risk is confirmed when pathogenic mutations are found in genes associated with Fanconi anemia and related DNA repair disorders, including FANCA, FANCC, and BRCA2. A lower risk may be inferred when no mutations are detected, though comprehensive clinical follow-up is still essential. The integration of genetic data with clinical findings and laboratory evaluation is critical for precise diagnosis, prognosis, and long-term patient care.
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.
