A Rare Case of Chronic Myelogenous Leukemia Presenting as T-Cell Lymphoblastic Crisis.

Chronic Myelogenous Leukemia in blast crisis can manifest as either myeloid (more common) or lymphoid blast crisis. Most lymphoblastic crises are of B-cell lineage. T-cell blast crisis is extremely rare, with only a few reported cases. We present a case of a middle-aged man who was diagnosed with CML on peripheral blood and bone marrow biopsy. Because of a generalized lymphadenopathy noted at the time of diagnosis, a lymph node biopsy was also performed, which revealed a T-cell lymphoblastic leukemia/lymphoma, BCR/ABL1 positive, with clonal evolution. This is a very rare manifestation of CML in blast crisis with no standard treatment and with poor outcomes despite chemotherapy or allogeneic stem cell transplant. Given its rarity, it would be difficult to develop standard chemotherapy protocols. We believe the treatment for this condition should be similar to any lymphoid blast crisis. The patient was treated with induction chemotherapy (hyper-CVAD regimen) plus dasatinib for 3 cycles followed by sibling-donor allogeneic stem cell transplant and is currently on maintenance dasatinib and has minimal residual disease at this time.

Discrepant Cytogenetic and Interphase Fluorescence In Situ Hybridization (I-FISH) Results from Bone Marrow Specimens of Patients with Hematologic Neoplasms.

Conventional cytogenetic and routine I-FISH (interphase fluorescence in-situ hybridization) studies periodically present discrepant results on the same sample calling into question their validity. Generally it is expected that these tests confirm each other, otherwise there is concern that they may represent laboratory error. We present data showing that these discrepant results are rarely due to laboratory error, and that M-FISH (metaphase fluorescence in-situ hybridization) can usually reconcile them by identifying the nature of these differences. This report includes 32 bone marrow (BM) samples from patients with hematologic neoplasms that showed incongruent cytogenetic/I-FISH results. M-FISH was selectively applied for further clarification of these discrepancies when deemed necessary. This study evaluated BM samples in our laboratory (Integrated Oncology, Phoenix, AZ) that represented 5 major categories of hematologic disorders (MDS/AML, MPN, NHL, CLL, & PCN). Five general categories of these cases were identified: 1) laboratory error (clerical), 2) limited resolution of testing methods, 3) cellular response to culture/preparative conditions, 4) cytogenetic bi-clonality and 5) failed hybridizations due to cover-slipping. Our results suggest that the majority of discrepant results are related to the intrinsic nature of the malignant cells (and how they respond to their growth environment) evaluated by these two testing methods.

Male-to-female sex ratios of abnormalities detected by fluorescence in situ hybridization in a population of chronic lymphocytic leukemia patients.

Distorted sex ratios occur in hematologic disorders. For example, chronic lymphocytic leukemia (CLL) displays disproportionate sex ratios with a large male excess. However, the underlying genetics for these disparities are poorly understood, and gender differences for specific cytogenetic abnormalities have not been carefully investigated. We sought to provide an initial characterization of gender representation in genetic abnormalities in CLL by using fluorescence in situ hybridization (FISH). We confirm the well known skewed male-tofemale (M/F sex ratio) of ~1.5 in our CLL study population, but also determine the genotypic M/F sex ratio values corresponding to specific FISH DNA probes. Genetic changes in CLL detectable by four FISH probes were statistically compared with respect to gender. Initial FISH evaluations of 4698 CLL patients were retrospectively examined and new findings of the genotypic M/F sex ratios for these probes are reported. This study represents the largest CLL survey conducted in the United States using FISH probes. The CLL database demonstrated that FISH abnormalities (trisomy 12, 13q14.3 deletion and 17p13.1 deletion) probes had skewed M/F ratios of ~1.5. Also, by statistical analysis it was shown that ATM gene loss (11q22.3q23.1 deletion) solely or with other abnormalities was considerably higher in males with an M/F ratio of 2.5 and significantly different from M/F ratios of 1.0 or 1.5. We hypothesize that interactions involving these autosomal abnormalities (trisomy 12, and deletions of 11q22.3, 13q14.3, and 17p13.1), and the sex chromosomes may provide the genetic basis for the altered phenotypic M/F ratio in CLL.