Coronary Plaque Boundary Enhancement in IVUS Image by Using a Modified Perona-Malik Diffusion Filter.

We propose a modified Perona-Malik diffusion (PMD) filter to enhance a coronary plaque boundary by considering the conditions peculiar to an intravascular ultrasound (IVUS) image. The IVUS image is commonly used for a diagnosis of acute coronary syndrome (ACS). The IVUS image is however very grainy due to heavy speckle noise. When the normal PMD filter is applied for speckle noise reduction in the IVUS image, the coronary plaque boundary becomes vague. For this problem, we propose a modified PMD filter which is designed in special reference to the coronary plaque boundary detection. It can then not only reduce the speckle noise but also enhance clearly the coronary plaque boundary. After applying the modified PMD filter to the IVUS image, the coronary plaque boundaries are successfully detected further by applying the Takagi-Sugeno fuzzy model. The accuracy of the proposed method has been confirmed numerically by the experiments.

A case of congenital leukemia with monosomy 7.

A case of congenital leukemia with monosomy 7 is reported. Immunological study of the blast cells using monoclonal antibodies was suggestive of both myelomegakaryocytic and T-lymphoblastic leukemia. Chromosomal analysis of the bone marrow cells showed monosomy 7. Chemotherapy was initiated with a combination of adriamycin, cytosine arabinoside, 6-mercaptopurine, and prednisolone. The patient obtained complete remission, which has been maintained for 4 years and 1 month. He receives no chemotherapy now. Our case shows that monosomy 7 in congenital leukemia is rare, but the presence of monosomy 7 in congenital leukemia does not necessarily indicate a poor prognosis.

Frequent lack of antibodies against human T-cell leukemia virus type I gag proteins p24 or p19 in sera of patients with adult T-cell leukemia.

Specificities of antibodies against human T-cell leukemia virus type I (HTLV-I) in sera of 27 patients with adult T-cell leukemia (ATL) were studied. All sera were positive for HTLV-I antigens by immunofluorescence assay using cells expressing HTLV-I antigens; sera from five ATL patients, however, did not react or hardly reacted with p19 or p24 gag proteins of HTLV-I upon immunoprecipitation assay. Therefore, the relationships among antibody specificities against HTLV-I, the proviral structures of HTLV-I genomes in leukemic cells, and the expression of viral antigens by leukemic cells after cultivation in vitro for a few days were examined. Analyses of the genomic structures of the proviruses revealed deletions in at least seven cases. However, we could not detect deletions in the proviral genomes of four out of the five ATL patients who lacked antibodies against gag proteins. Furthermore, expression of p19 and p24 was detected in these patients' peripheral blood lymphocytes (PBL) cultured in vitro for a few days. Thus, some ATL patients could not or could hardly raise antibodies against gag proteins, although they harbored complete HTLV-I genomes and their PBL expressed gag proteins in vitro. All patients harboring deleted proviruses, so far tested, raised antibodies not only against viral proteins that should be encoded by the integrated proviruses, but also against viral proteins that should be encoded by the deleted regions. Antibodies against viral proteins were detected also in sera of ATL patients whose PBL did not express viral proteins after in vitro cultivation. Specificities of antibodies against viral proteins in ATL patients could not be predicted by the structures of proviruses in leukemic cells or by expression of viral proteins in vitro. Immune responses to HTLV-I antigens were weak or lost in some ATL patients.

Immunoglobulin heavy chain gene rearrangements and mixed lineage characteristics in acute leukemias with the 11;19 translocation.

Although the origin of acute leukemia with the 4;11 translocation has been shown to be an early myeloid progenitor cell or a stem cell with the potential for differentiation into both lymphoid and myeloid lineage, few precise studies on acute leukemia with the 11;19 translocation have thus far been reported. This study focused on the clinical, morphologic, ultrastructural, and immunologic characteristics as well as the DNA in three cases of acute leukemia with the 11;19 translocation. All three patients were infants and showed hyperleukocytosis. The morphologic feature was French-American-British (FAB)-L2 in two patients, in one of which a few monocytoid blasts were also seen by electron microscopy. Cells from the third patient underwent morphologic changes from FAB-L2 at the time of diagnosis to M5b at relapse. Immunologic marker studies revealed that the blast cells from all three patients expressed Ia and B4, but none expressed B1, CALLA(J5), T antigens, or SIg. Cells from one patient simultaneously expressed myeloid antigen (MCS-II) both at diagnosis and relapse. Cells from two patients expressed myeloid antigen after being cultured for a short time in vitro. An analysis of immunoglobulin genes and T-cell receptor genes revealed rearrangements of the heavy chain genes and germ line configurations of the kappa and lambda light chain genes, and of the T-cell receptor beta chain genes. These findings suggest that acute leukemia with the 11;19 translocation has mixed lineage characteristics as a result of leukemogenesis in a stem cell with the potential for both lymphoid and myeloid, especially monocytic, differentiation.