Myelodysplastic Syndrome - Diagnosis

Diagnosis

MDS must be differentiated from anemia, thrombocytopenia, and/or leukopenia. Usually, the elimination of other causes of these cytopenias, along with a dysplastic bone marrow, is required to diagnose a myelodysplastic syndrome.

A typical investigation includes:

• Full blood count and examination of blood film. The blood film morphology can provide clues about hemolytic anemia, clumping of the platelets leading to spurious thrombocytopenia, or leukemia.
• Blood tests to eliminate other common causes of cytopenias, such as lupus, hepatitis, B₁₂, folate, or other vitamin deficiencies, renal failure or heart failure, HIV, hemolytic anemia, monoclonal gammopathy. Age-appropriate cancer screening should be considered for all anemic patients.
• Bone marrow examination by a hematopathologist. This is required to establish the diagnosis, since all hematopathologists consider dysplastic marrow the key feature of myelodysplasia.
• Cytogenetics or chromosomal studies. This is ideally performed on the bone marrow aspirate. Conventional cytogenetics requires a fresh specimen, since live cells are induced to enter metaphase to enhance chromosomal staining. Alternatively, virtual karyotyping can be done for MDS, which uses computational tools to construct the karyogram from disrupted DNA. Virtual karyotyping does not require cell culture and has dramatically higher resolution than conventional cytogenetics, but cannot detect balanced translocations.
• Flow cytometry is helpful to establish the presence of any lymphoproliferative disorder in the marrow.

Anemia dominates the early course. Most symptomatic patients complain of the gradual onset of fatigue and weakness, dyspnea, and pallor, but at least half the patients are asymptomatic and their MDS is discovered only incidentally on routine blood counts. Previous chemotherapy or radiation exposure is an important historic fact. Fever and weight loss should point to a myeloproliferative rather than myelodysplastic process. Children with Down syndrome are susceptible to MDS, and a family history may indicate a hereditary form of sideroblastic anemia or Fanconi anemia.

The average age at diagnosis for MDS is about 65 years, but pediatric cases have been reported. Some patients have a history of exposure to chemotherapy (especially alkylating agents such as melphalan, cyclophosphamide, busulfan, and chlorambucil) or radiation (therapeutic or accidental), or both (e.g., at the time of stem cell transplantation for another disease). Workers in some industries with heavy exposure to hydrocarbons such as the petroleum industry have a slightly higher risk of contracting the disease than the general population. Males are slightly more frequently affected than females. Xylene and benzene exposure has been associated with myelodysplasia. Vietnam veterans exposed to Agent Orange are at risk of developing MDS.

The features generally used to define a MDS are: blood cytopenias; ineffective hematopoiesis; dyserythropoiesis; dysgranulopoiesis; dysmegakaropoiesis and increased myeloblast.

Dysplasia can affect all three lineages seen in the bone marrow. The best way to diagnose dysplasia is by morphology and special stains (PAS) used on the bone marrow aspirate and peripheral blood smear. Dysplasia in the myeloid series is defined by:

• Granulocytic series
  1. Hypersegmented neutrophils (also seen in Vit B₁₂/Folate deficiency)
  2. Hyposegmented neutrophils (Pseudo-Pelger Huet)
  3. Hypogranular neutrophils or pseudo Chediak Higashi large granules
  4. Auer rods - automatically RAEB II (if blast count <5% in the peripheral blood and <10% in the bone marrow aspirate) also note Auer rods may be seen in mature neutrophils in AML with translocation t(8;21)
  5. Dimorphic granules (basophilic and eosinophilic granules) within eosinophils
• Erythroid series
  1. Binucleated erythroid percursors and karyorrhexis
  2. Erythroid nuclear budding
  3. Erythroid nuclear strings or internuclear bridging (also seen in congenital dyserythropoietic anemias)
  4. Loss of E-cadherin in normoblasts is a sign of aberrancy
  5. PAS (globular in vacuoles or diffuse cytoplasmic staining) within erythroid precursors in the bone marrow aspirate (has no bearing on paraffin fixed bone marrow biopsy). Note: One can see PAS vacuolar positivity in L1 and L2 blasts (AFB classification; the L1 and L2 nomenclature is not used in the WHO classification)
  6. Ringed sideroblasts seen on Prussian blue iron stain (10 or more iron granules encircling 1/3 or more of the nucleus and >15% ringed sideroblasts when counted amongst red cell precursors)
• Megakaryocytic series (can be the most subjective)
  1. Hyposegmented nuclear features in platelet producing megakaryocytes (lack of lobation)
  2. Hypersegmented (osteoclastic appearing) megakaryocytes
  3. Ballooning of the platelets (seen with interference contrast microscopy)

Other stains can help in special cases (PAS and napthol ASD chloroacetate esterase positivity) in eosinophils is a marker of abnormality seen in chronic eosinophilic leukemia and is a sign of aberrancy.

On the bone marrow biopsy high grade dysplasia (RAEB-I and RAEB-II) may show atypical localization of immature precursors (ALIPs) which are islands of immature precursors cells (myeloblasts and promyelcytes) localized to the center of intertrabecular space rather than adjacent to the trabeculae or surrounding arterioles. This morphology can be difficult to recognize from treated leukemia and recovering immature normal marrow elements. Also topographic alteration of the nucleated erythroid cells can be seen in early myelodysplasia (RA and RARS), where normoblasts are seen next to bony trabeculae instead of forming normal interstitially placed erythroid islands.

Myelodysplasia is a diagnosis of exclusion and must be made after proper determination of iron stores, vitamin deficiencies, and nutrient deficiencies are ruled out. Also congenital diseases such as congenital dyserythropoietic anemia (CDA I through IV) has been recognized, Pearson's syndrome (sideroblastic anemia), Jordans anomaly - vacuolization in all cell lines may be seen in Chanarin-Dorfman syndrome, ALA (aminolevulinic acid) enzyme deficiency, and other more esoteric enzyme deficiencies are known to give a pseudomyelodysplastic picture in one of the cell lines, however, all three cell lines are never morphologically dysplastic in these entities with the exception of chloramphenicol, arsenic toxicity and other poisons.

All of these conditions are characterized by abnormalities in the production of one or more of the cellular components of blood (red cells, white cells other than lymphocytes and platelets or their progenitor cells, megakaryocytes).