Adipose stem cells

Lu ZF et al (2007) Differentiation of adipose stem cells by nucleus pulposus cells configuration effect. Biochem Biophys Res Commun 359(4) 991-996... [Pg.229]

The use of mature cell types such as chondrocytes and osteoblasts is associated with several drawbacks including their limited availability, donor site morbidity, dedifferentiation, and limited proliferative capacity. These problems have urged researchers to study the chondrogenic and osteogenic lineage differentiation of ESCs and adipose stem cells. Human embryoid body cells were combined with Matrigel and seeded onto thin PLGA/PLA scaffolds. The hESC proliferation... [Pg.38]

Lu, Z., Wang, G., Roohani-Esfahani, I., Dunstan, C.R., and Zreiqat, H. (2014) Baghdadite ceramics modulate the crosstalk between human adipose stem cells and osteoblasts for bone regeneration. Tissue Eng. A, 20 (5-6), 992-1002. [Pg.66]

M.P. Francis, et al.. Electrospinning adipose tissue-derived extracellular matrix for adipose stem cell culture, J Biomed Mater Res A 100 (2012) 1716-1724. [Pg.242]

Figure 19.1 Cardiac tissue engineering triad. Schematic representation of the interplay between the components of the cardiac tissue engineering triad. Biomaterials are key components for cardiac tissue engineering applications and play a critical role in this technology. MSC, mesenchymal stem cell ADSC, adipose stem cell iPS, induced pluripotent cell CPC, cardiac progenitor cell VEGF, vascular endothelial growth factor FGF, fibroblast growth factor NRG, neuregulin EPO, erythropoietin HGF, hepatocyte growth factor SDF-1, stromal cell—derived factor 1.

Desiderio, V., De Francesco, F., Schiraldi, C., De Rosa, A., La Gatta, A., Paino, F., D aquino, R., Ferraro, G.A., Tirino, V., Papacdo, G., 2013. Human Ng2 adipose stem cells loaded in vivo on a new crosslinked hyaluronic acid-lys scaffold fabricate a skeletal muscle tissue. J. Cell Physiol. 228, 1762—1773. [Pg.488]

Pirraco, R.P., Melo-Ferreira, B., Santos, T.C., et al., 2013. Adipose stem cell-derived osteoblasts sustain the functionahty of endothelial progenitors from the mononuclear fiaction of umbilical cord blood. Acta Biomater. 9, 5234—5242. [Pg.135]

Lindroos, B., Boucher, S., Chase, L., Kuokkanen, H., Huhtala, H., Haataja, R., Vemuri, M.,Suuronen, R., and Miettinen, S. 2009. Serum-free, xeno-free culture media maintain the proliferation rate and multipotentiality of adipose stem cells in vitro. Cytotherapy, 11,958-72. [Pg.188]

MoioU, E. K., Chen, M., Yang, R. et al. 2010. Hybrid adipogenic implants from adipose stem cells for soft tissue reconstruction in vivo. Tissue Eng Part A 16(11) 3299-3307. [Pg.573]

Maenpaa, K., Ella, V., Mauno, J. et al. 2010. Use of adipose stem cells and polylactide discs for tissue engineering of the temporomandibular joint disc. / R Soc Interface 7(42).T77-88. [Pg.629]

S. Sugii, Y. Kida, W.T. Berggren, and R.M. Evans, Feeder-dependent and feeder-independent iPS cell derivation from human and mouse adipose stem cells. Nature Protoc., 6 (3) 346-358, Mar. 2011. [Pg.210]

Marino, G., Rosso, E, Cafiero, G., Tortora, G., Moraci, M., Barbarisi, M., and Barbarisi, A. 2010. P-Tricalcium phosphate 3D scaffold promote alone osteogenic differentiation of human adipose stem cells In vitro study. / Mater Sci Mater Med, 21, 353-363. [Pg.737]

Ribeiro, C., Parssinen, J., Sencadas, V., Correia, V., Miettinen, S., Hytonen, V.P., et al., 2015c. Dynamic piezoelectric stimulation enhances osteogenic differentiation of human adipose stem cells. J. Biomed. Mater. Res. A 103 (6), 2172—2175. [Pg.96]

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