Selective serotonin reuptake inhibitors (SSRIs) are a widely used group of antidepressants (ADs) with reported potential detrimental effects on bone mineral density (BMD) and increased fracture risk. Here, a comprehensive review of the in vitro, in vivo and clinical studies to date was carried out using the medical search engines MEDLINE (1950 to September 2010) and EMBASE (1980 to September 2010). Serotonin (5-HT) receptors have been identified on osteoclast, osteoblast and osteocyte cell lines. The effect of SSRIs on bone formation and resorption appears to be governed by the activation of a number of 5-HT receptors on osteoblasts and osteoclasts via endocrine, autocrine/paracrine and neuronal pathways. In vitro, in vivo and clinical collective data appears to indicate that SSRIs have a negative effect on bone at the therapeutic dose levels widely used for the treatment of depression in current clinical practice. Caution may therefore have to be employed with the use of SSRIs in patients at an increased risk of falls and osteoporosis. Further studies are needed in order to fully elicit the role of SSRIs in bone formation and their effects in the low oestrogen state.
During maturation of the red blood cell (RBC) from the nucleated normoblast stage to the mature biconcave discocyte, both the structure and mechanical properties of the cell undergo radical changes. The development of the mechanical stability of the membrane reflects underlying changes in the organization of membraneassociated cytoskeletal proteins, and so provides an assessment of the time course of the development of membrane structural organization. Membrane stability in maturing erythrocytes was assessed by measuring forces required to form thin, tubular, lipid strands (tethers) from the surfaces of mononuclear cells obtained from fresh human marrow samples, marrow reticulocytes, circulating reticulocytes, and mature erythrocytes. Cells were biotinylated and manipulated with a micropipette to form an adhesive contact with a glass microcantilever, which gave a measure of the tethering force. The cell was withdrawn at controlled velocity and aspiration pressure to form a tether from the cell surface. The mean force required to form tethers from marrow reticulocytes and normoblasts was 27 ؎ 9 pN, compared to 54 ؎ 14 pN for mature cells. The energy of dissociation of the bilayer from the underlying skeleton increases 4-fold between the marrow reticulocyte stage and the mature cell, demonstrating that the mechanical stability of the membrane is not completely established until the very last stages of RBC maturation. IntroductionDuring the last stages of maturation of red blood cells (RBCs), dramatic changes occur in the structure and organization within the cell. The cell loses its nucleus, surface molecules are shed in small vesicles, and the final surface-to-volume ratio of the cell is established. [1][2][3] During this time, proteins that will eventually form the membrane-associated cytoskeleton (membrane skeleton) are synthesized and assembled at the intracellular surface of the plasma membrane. 4 The time course over which these protein assemblies become functionally viable is of interest, particularly with regard to hemolytic anemia and the early release of cells during hemorrhagic crisis, and could be important in designing methods for production of erythrocytes in vitro.The function of the assembled membrane skeleton is fundamentally mechanical, and therefore, studies of membrane mechanical properties in maturing cells provide the most direct assessment of the development of the functional viability of the skeleton during maturation. Early studies of membrane properties of both murine and human reticulocytes indicated increased membrane stiffness (shear rigidity) in those membranes. 5 This increased rigidity has been confirmed subsequently both by micropipette 6 and cell deformation in shear (ektacytometry). 7 In the latter study, evidence was also obtained that, despite increased mechanical stiffness, membranes of immature cells were less mechanically stable than their mature counterparts, as indicated by fragmentation of cells in fluid shear and in micropipette aspiration studies. The structural events...
Porous 3D polymer scaffolds prepared by TIPS from PLGA (53:47) and PS are intrinsically hydrophobic which prohibits the wetting of such porous media by water. This limits the application of these materials for the fabrication of scaffolds as supports for cell adhesion/spreading. Here we demonstrate that the interior surfaces of polymer scaffolds can be effectively modified using atmospheric air plasma (AP). Polymer films (2D) were also modified as control. The surface properties of wet 2D and 3D scaffolds were characterised using zeta-potential and wettability measurements. These techniques were used as the primary screening methods to assess surface chemistry and the wettability of wet polymer constructs prior and after the surface treatment. The surfaces of the original polymers are rather hydrophobic as highlighted but contain acidic functional groups. Increased exposure to AP improved the water wetting of the treated surfaces because of the formation of a variety of oxygen and nitrogen containing functions. The morphology and pore structure was assessed using SEM and a liquid displacement test. The PLGA and PS foam samples have central regions which are open porous interconnected networks with maximum pore diameters of 49 microm for PLGA and 73 microm for PS foams.
Bone marrow, with its intricate, three-dimensional tissue structure facilitating cell-cell interactions, provides a microenvironment supporting the production of hundreds of billions of multilineal blood cells everyday. We have developed a three-dimensional bone marrow culture system in which marrow cells are cultured in a reactor packed with porous microspheres. The culture supports a three-dimensional growth configuration and multilineal hemopoiesis mimicking the bone marrow in vivo. We studied ex vivo human erythropoiesis using the three-dimensional culture system. The system sustained extensive erythropoiesis at low erythropoietin concentrations (0.2 U/mL), plus stem cell factor, interleukin-3, granulocyte-macrophage colony-stimulating factor, and insulin-like growth factor-I. Erythroid cell production lasted for more than 5 weeks, and the percentage of erythroid cells in the nonadherent cell population was approximately 60%. Flow cytometric analysis using cell surface markers specific for erythroid cells (CD71 and glycophorin-A) indicated that the culture produced early, intermediate, and late erythroid cells. As the culture progressed, the erythroid cell population shifted gradually toward mature cell types. When compared to the three-dimensional culture, the traditional flask cultures failed to support extensive erythropoiesis under the same conditions. This indicates that the three-dimensional bone marrow culture system provides a microenvironment conducive to erythropoiesis under more physiological conditions and is a better bone marrow model.
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