v.). The transplanted cells are found in the infarcted hemisphere and the spleen. The goal of this project was to click here determine the nature of the interaction between the HUCB MNCs and splenic immune cells. Male Sprague Dawley rats underwent permanent middle cerebral artery occlusion (MCAO) and received i.v. injection of either vehicle (MCAO only), HUCB MNCs, or MNCs depleted of CD14+ monocytes, CD133+ stem cells, or CD19+ B cells 48 h poststroke.
At 72 h post-MCAO, the animals were euthanized, and the spleens and blood MNCs were harvested for flow cytometry and mitogen proliferation assays. All HUCB cell preparations decreased the percentage of T cells in the spleen and monocytes in the blood (p < 0.05). MNCs depleted of CD14+ and CD19+ decreased the percentage of macrophage (p < 0.001), while CD133-depleted MNCs increased the percentage of macrophage in the spleen (p < 0.001); MNC did not alter the macrophage population from the level observed after MCAO. Only HUCB MNC
significantly decreased concanavalin A-induced T cell stimulation VX-765 (p < 0.05). These results suggest that the effects of HUCB MNC in the spleen are not due to a single HUCB population, but the interaction of all the subpopulations together.”
“Volume-rendering computed tomography (CT) without contrast medium has clearly demonstrated the 3-D mapping of the saphenous vein (SV). Contrastless volume-rendering CT was used to preoperatively evaluate the SV anatomy before coronary artery bypass grafting (CABG). This technique was useful for atypical anatomical variations, such as partial duplication of SV (Case 1) or varicose veins (Case 2). Volume-rendering CT may also help with redo CABG (to determine remaining
SV) or during endoscopic SV harvesting with restricted view. Volume-rendering CT is an objective, less time-consuming modality to evaluate the SV preoperatively and may be less invasive in terms of avoiding unnecessary skin incision.”
“Cell therapies utilizing mesenchymal stem cells (MSCs) could overcome limitations of traditional treatments for reconstructing craniofacial tissues. This large-scale study explored a standardized methodology for the isolation and clinical-scale expansion of alveolar bone marrow-derived MSCs (aBMSCs). We harvested 103 alveolar bone marrow samples from 45 patients using 1 of 3 standardized methodologies. Following aBMSC isolation, buy CX-4945 cells were characterized through cell-surface marker expression and lineage-specific differentiation. Long-term cultures (> 50 population doublings [PDs]) were evaluated for transformational changes through senescence, gene expression, and karyotyping. Finally, aBMSC bone-forming potential was determined in vivo. More than 0.5 cc of bone marrow was needed to predictably isolate aBMSCs, and, regardless of methodology for harvest, cell-surface marker expression of CD73, CD90, CD105, and Stro-1 was similar for aBMSCs, being 89.8%, 98.8%, 93.8%, and 3.