Red blood cell deformability influences platelets--vessel wall interaction in flowing blood

Hematocrit and red cell size are important factors for the transport of blood platelets toward subendothelium in flowing blood. We report that red cell deformability also influences platelet transport. Red cell deformability was estimated with Couette-flow viscosimetry at a shear rate of 130 s-1 and expressed as a 'T' factor--a dimensionless parameter relating the relative viscosity and the hematocrit derived from the relationship: T = (1 - mu -0.4 rel)/H, where mu rel is the relative viscosity and H is the hematocrit. The normal value of T was within a narrow range (0.91 +/- 0.02). Treatment of normal red cells with isoxsuprine and chlorpromazine caused decreased rigidity and decreased T. Cholesterol loading and treatment with diamide increased rigidity and increased T. In vitro perfusion experiments in an annular perfusion system with everted human umbilical arteries were performed with perfusates to which such treated red blood cells were added to investigate their influence on platelet adherence to artery subendothelium. Platelet adherence was well correlated with red cell rigidity, with increased adherence at increased rigidity and vice versa. A change in T of 0.10 corresponded to a change in platelet adherence of approximately 50%. These effects were more pronounced at a wall shear rate of 1,800 s-1 than at 300 s-1.     

HLA-DRB1*16-restricted recognition of myeloid cells,including CD34+ CML progenitor cells

The therapeutic effect of a human leucocyte antigen (HLA)-identical allogeneic stem cell transplantation (allo-SCT) for the treatment of haematological malignancies is mediated partly by the allogeneic T cells that are administered together with the stem cell graft. Chronic myeloid leukaemia (CML) is particularly sensitive to this graft-versus-leukaemia (GVL) effect. Several studies have shown that in allogeneic responses both CD4 and CD8 cells are capable of strong antigen-specific growth inhibition of leukaemic progenitor cells, but that CD4 cells mainly exert the GVL effect against CML. Efficient activation of allogeneic CD4 cells, as well as CD8 cells, may explain the sensitivity of CML cells to elimination by allogeneic T cells. Identification of the antigens recognized by CD4 cells is crucial in understanding the mechanism through which CML cells are so successful in activating allogeneic T cells. In the present report, we describe the characterization of an allogeneic CD4 T-cell clone, DDII.4.4. This clone was found to react against an antigen that is specifically expressed in myeloid cells, including CD34+ CML cells. The antigen recognition is restricted by HLA-DRB1*16. To our knowledge, this is only the second report on an allogeneic CD4 T-cell clone that reacts with early CD34+ myeloid progenitor cells.     

胆碱能M受体拮抗剂：2α－（2＇，2＇－二取代基－2＇－羟基乙氧基）托品烷光学异构体合成

胆碱能Ｍ受体拮抗剂：２α－（２＇，２＇－二取代基－２＇－羟基乙氧基）托品烷光学异构体合成王林，恽榴红，张其楷（军事医学科学院毒物药物研究所，北京１００８５０）目前临床所用托品类抗胆碱药一般为３位取代托品酯类衍生物，这类药物作用较广泛，但选择性不高。Ａ...     

A perfusion chamber developed to investigate platelet interaction in flowing blood with human vessel wall cells, their extracellular matrix, and purified components

A flat perfusion chamber was developed to study the interaction of blood platelets in flowing blood with cultured human vessel wall cells, their connective tissue matrix, and isolated connective tissue components at defined shear rate conditions. A cover slip covered with endothelial cells or extracellular matrix components was introduced into the chamber. Laser-Doppler velocimetry showed a symmetrical flow profile at flow rates between 50 and 150 ml/min (wall shear rate 300 to 1100 sec-1). Platelet deposition was estimated by using blood platelets labeled with indium-111 or by a morphometric method. Blood platelets did not adhere to endothelial cells at wall shear rates of 765 sec-1 and the endothelial cells remained attached for at least 10 min of perfusion. In preconfluent cultures of endothelial cells, blood platelets adhered to extracellular material in areas between the cells. Removal of endothelial cells by treatment with 0.5% Triton X-100 induced increased platelet adherence with a preference for certain, as yet unidentified, fibrillar structures of the extracellular matrix. Platelet adherence to equine collagen was also studied after coating the cover slips by spraying of small collagen droplets followed by air drying. Platelet adherence and the subsequent platelet aggregate formation occurred predominantly along visible collagen fibers. These studies showed that this perfusion chamber has a laminar and symmetrical flow allowing qualitative and quantitative investigation of platelet interaction with endothelial cells, their extracellular matrix, and pure connective tissue components. A variety of wall shear rates and exposure times can be applied at controlled conditions without removing cells or extracellular material.