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Human bone marrow stromal cells

Pereira, A. and Dean, B. (2006) Clozapine bioactivation induces dose-dependent, drug-specific toxicity of human bone marrow stromal cells a potential in vitro system for the study of agranulocytosis. Biochemical Pharmacology, 71, 783—793. [Pg.434]

Monticone, M., Liu, Y.,Tonachini, L., et al. (2004), Gene expression profile of human bone marrow stromal cells determined by restriction fragment differential display analysis, /. Cell. Biochem, 92(4), 733-744. [Pg.115]

Di Nicola, M., Carlo-Stella, C., Magni, M., et al. (2002), Human bone marrow stromal cells suppress T-lymphocyte proliferation induced by cellular or nonspecific mitogenic stimuli, Blood, 99(10), 3838-3843. [Pg.115]

Chen, J., Li, Y., Zhang, R., Katakowski, M., Gautam, S.C., Xu, Y., Lu, M., Zhang, Z., Chopp, M. (2004). Combination therapy of stroke in rats with a nitric oxide donor and human bone marrow stromal cells enhances angiogenesis and neurogenesis. Brain Res, 1005,21-8. [Pg.29]

Chuah, M. K., Van Damme, A., Zwinnen, H., Goovaerts, I., Vanslembrouck, V., Collen, D. and Vandendriessche, T. (2000). Long-term persistence of human bone marrow stromal cells transduced with factor VUI-retroviral vectors and transient production of therapeutic levels of human factor VIII in nonmyeloablated immunodeficient mice. Hum. Gene Ther. 11, 729-738. [Pg.75]

Chen, J.S., Altman, G.H., Karageorgiou, V., Horan, R., Collette, A., Volloch, V., Colabro, T., and Kaplan, D.L. "Human bone marrow stromal cell and ligament fibroblast responses on RGD-modified silk fibers".. Biomed. Mater. Res. Part A 67A(2), 559-570 (2003). [Pg.150]

Marolt, D., Augst, A., Freed, L.E., Vepari, C., Fajardo, R., Patel, N., Gray, M., Farley, M., Kaplan, D., and Vunjak-Novakovic, G. "Bone and cartilage tissue constructs grown using human bone marrow stromal cells, silk scaffolds and rotating bioreactors". Biomaterials 27(36), 6138-6149 (2006). [Pg.154]

Aman MJ, Bug G, Aulitzky WE, et al. Inhibition of interleukin-11 by interferon-a in human bone marrow stromal cells. Exp Hematol 1996 24 863-7. [Pg.723]

Jin HJ et al (2004) Human bone marrow stromal cell responses on electrospun silk fibroin mats. Biomaterials 25(6) 1039-1047... [Pg.127]

Woodbury D, Schwarz E J, Prockop D J, et al. (2000). Adult rat and human bone marrow stromal cells differentiate into neurons. J. Neurosci. Res. 61 364-370. [Pg.1353]

Silk, silk/PEO Nonwoven scaffold TE SEM, XPS, Differential Scanning Calorimetry (DSQ, mechanical evaluation, in vitro human bone marrow stromal cell culture (Jin et al. 2004)... [Pg.86]

V. Karageorgiou, L. Meinel, S. Hofmann, A. Malhotra, V. Volloch, D. Kaplan, Bone morphogenetic protein-2 decorated silk fibroin films induce osteogenic differentiation of human bone marrow stromal cells, J. Biomed. Mater. Res. A 71 (3) (2004) 528-537. [Pg.367]

Ho STB, Cool SM, Hui JH, Hutmacher DW (2010) The influence of fibrin based hydrogels on the chondrogenic differentiation of human bone marrow stromal cells. Biomaterials 31 38-47... [Pg.207]

Pei, M., He, F., Kish, V.L., 2011. Expansion on extracellular matrix deposited by human bone marrow stromal cells facilitates stem cell proliferation and tissue-specific lineage potential. Tissue Eng. Part A 17, 3067-3076. [Pg.80]

Hankemeier S, Keus M, Zeichen J (2005) Modulation of proliferation and differentiation of human bone marrow stromal cells by fibroblast growth factor 2 Potential implicatimis for tissue engineering of tendons and ligaments. Tissue Eng 11 41-49... [Pg.560]

Multiple conducted cell culture tests show that osteosarcomic cells (Saos-2) and human bone marrow stromal cells adhere directly on the fibers and proliferate regardless of the overall porosity (Fig. 12.5). [Pg.248]

Figure 12.5 SEM of adhered human bone marrow stromal cells on chitosan fibers (a), proliferation of cells for various porosities given by fiber diameters of 20, 25, and 30 pm and... Figure 12.5 SEM of adhered human bone marrow stromal cells on chitosan fibers (a), proliferation of cells for various porosities given by fiber diameters of 20, 25, and 30 pm and...
Figure 21.13. A) High power microscope image showing that polysaccharide nanoparticles selectively associate with primary human bone marrow stromal cells in a 3D cell suspensions (n=12). The alginate nanocapsule core is stained with a fluorescent dye (Cell Tracker Red) which in white transmitted light is blue. B) TEM image showing presence of nanocapsules (i) at the surface of a primary hBMSC cell membrane and (ii) internalized within vacuoles. The yellow arrows denote position of nanocapsules. Figure 21.13. A) High power microscope image showing that polysaccharide nanoparticles selectively associate with primary human bone marrow stromal cells in a 3D cell suspensions (n=12). The alginate nanocapsule core is stained with a fluorescent dye (Cell Tracker Red) which in white transmitted light is blue. B) TEM image showing presence of nanocapsules (i) at the surface of a primary hBMSC cell membrane and (ii) internalized within vacuoles. The yellow arrows denote position of nanocapsules.
Green, D., Walsh, D., Yang, X., Mann, S., Oreffo, R.O.C., 2004. Stimulation of human bone marrow stromal cells using growth factor-encapsulated calcium carbonate porous microspheres. J. Mater. Chem. 14, 2206-2212. [Pg.30]

Mahmood, A. et al.. Treatment of traumatic brain injury in adult rats with intravenous administration of human bone marrow stromal cells. Neurosurgery, 53,697-703,2003. [Pg.490]

Kasten, R, Luginbuhl, R., van Griensven, M., Barkhausen, T., Krettek, C., Bohner, M., and Bosch, U. 2003. Comparison of human bone marrow stromal cells seeded on calcium-deficient hydroxyapatite, P-tricalcium phosphate and deminerahzed bone matrix. Biomaterials 24 2593-603. [Pg.68]

Agata, H., Watanabe, N., Ishii, Y., Kubo, N., Ohshima, S., Yamazaki, M., Tojo, A., and Kagami, H. 2009. Feasibility and efficacy of bone tissue engineering using human bone marrow stromal cells cultivated in serum-free conditions. Biochem Biophys Res Commun, 382,353-8. [Pg.185]

Banfi, A., Muragha, A., Dozin, B., Mastrogiacomo, M., Cancedda, R., and Quarto, R. 2000. Prohferation kinetics and differentiation potential of ex vivo expanded human bone marrow stromal cells Implications for their use in ceU therapy. Exp Hematol, 28, 707-15. [Pg.185]

Shi, D., Reinecke, H., Murry, C.E. et al. 2004. Myogenic fusion of human bone marrow stromal cells, but not hematopoietic cells. Blood 104(l) 290-94. [Pg.423]

Farrell, E., Van Der Jagt, O. R, Koevoet, W. et al. 2009. Chondrogenic priming of human bone marrow stromal cells A better route to bone repair Tissue EngPt C, Meth 15 285-95. [Pg.549]

Akintoye, S. O., Lam, T., Shi, S. et al. 2006. Skeletal site-specific characterization of orofacial and iliac crest human bone marrow stromal cells in same individuals. Bone 38(6) 758-768. [Pg.571]

Marolt, D. et al.. Bone and cartilage tissue constructs grown using human bone marrow stromal cells, silk scaffolds and rotating bioreactors. Biomaterials, 2006.27(36) 6138-49. [Pg.618]

Paul, C, Samdani, AF, Betz, RR, Fischer, 1, and Neuhuber, B. 2009. Grafting of human bone marrow stromal cells into spinal cord injury A comparison of delivery methods. Spine (PhilaPa 1976) 34(4) 328-34. [Pg.723]

Progress made in electrospinning in the past decade has allowed for the production of fibers in nanoscale diameters from various polymers. Tissue engineering has benefited a lot from this process and quite often silk protein is used to produce nanofiber scaffolds for ceU cultures. Human bone marrow stromal cells were found to proHferate in vitro very well on mats made from poly(ethylene oxide) (PEO) and B. mori silk aqueous solution electrospun nanofibers [27]. A very interesting work by... [Pg.488]

See other pages where Human bone marrow stromal cells is mentioned: [Pg.383]    [Pg.288]    [Pg.486]    [Pg.517]    [Pg.112]    [Pg.48]    [Pg.841]    [Pg.845]    [Pg.218]    [Pg.288]    [Pg.327]    [Pg.612]   
See also in sourсe #XX -- [ Pg.16 , Pg.20 ]



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