Expression and capping of a proliferation-associated surface membrane p34 kDa antigen on different human hematopoietic cell lines

A novel surface membrane nonglycosylated acidic polypeptide (34 kDa), encoded by a structural gene on chromosome 11, has been identified using murine monoclonal antibody (MoAb) 53.6 (IgG2a). MoAb 53.6, raised against uninduced cells of a human erythroleukemia line (HEL), recognizes a surface membrane antigen that is displayed on proliferating (cell cycle phase G1, S, and M + G2 phase) human leukocytes. The expression and redistribution (i.e., patching and capping) of the p34 kDa antigen on 27 different long-term human hematopoietic cell (HHC) lines was defined by fluorescence microscopy. These lines had been established from patients with leukemia or healthy donors and included phenotypically defined populations of T cells, B cells, and myelomonocytic cells. Almost all (greater than 95%) of the leukocytes of the 27 lines reacted strongly with MoAb 53.6. The majority of the leukocytes displayed p34 kDa antigen patching (26/27 lines; patched cells, 96-100%); moreover, 20 of 27 lines exhibited p34 kDa antigen capping (capped cells, 8-96%). Presentation of the p34 kDa antigen on surface membrane ultrastructures, imaged with immunogold using an indirect antibody labeling procedure, was illustrated by scanning electron microscopy, and endocytosis of the gold-tagged antigen-antibody complex was studied by transmission electron microscopy. The HHC lines are thought to represent immortalized populations of different human leukocyte subsets that are in different stages of maturation and/or differentiation; thus these lines should prove useful as models for further characterizing this unique p34 kDa proliferation-associated antigen and for defining the mechanisms and significance of surface membrane antigen redistribution and modulation that has been associated with leukocyte activation and propagation.     

Proximal femoral focal deficiency: radiologic analysis of 49 cases

Proximal femoral focal deficiency, an uncommon congenital anomaly, necessitates early radiologic classification for surgical planning and treatment. Objective radiographic criteria, including femoral length index, acetabular depth index, acetabular angle index, and shape of the proximal femur were determined in 49 patients before cartilaginous ossification of the femoral capital epiphysis; final classification was based on follow-up radiographs or findings at arthrography or surgery. These parameters were analyzed to determine the accuracy and contributions of each in classification. Correct classification into one of three groups was possible in 86% of cases with use of three of the parameters: femoral length index, acetabular depth index, and shape of the proximal femur. The acetabular angle was found to contribute insignificantly to classification. Magnetic resonance imaging, used in only one case, depicted the nonossified cartilaginous femoral capital epiphysis, thus obviating the need for invasive diagnostic procedures and facilitating early classification.     

Using adiabatic inversion pulses for long-T2 suppression in ultrashort echo time (UTE) imaging.

Ultrashort echo time (UTE) imaging is a technique that can visualize tissues with sub-millisecond T(2) values that have little or no signal in conventional MRI techniques. The short-T(2) tissues, which include tendons, menisci, calcifications, and cortical bone, are often obscured by long-T(2) tissues. This paper introduces a new method of long-T(2) component suppression based on adiabatic inversion pulses that significantly improves the contrast of short-T(2) tissues. Narrow bandwidth inversion pulses are used to selectively invert only long-T(2) components. These components are then suppressed by combining images prepared with and without inversion pulses. Fat suppression can be incorporated by combining images with the pulses applied on the fat and water resonances. Scaling factors must be used in the combination to compensate for relaxation during the preparation pulses. The suppression is insensitive to RF inhomogeneities because it uses adiabatic inversion pulses. Simulations and phantom experiments demonstrate the adiabatic pulse contrast and how the scaling factors are chosen. In vivo 2D UTE images in the ankle and lower leg show excellent, robust long-T(2) suppression for visualization of cortical bone and tendons.