Cell proliferation in CPC scaffold with a central channel

Bio-Medical Materials and Engineering

Volumn 17, Issue 1, 2007, Pages 1-8

  Xu, Shanglong ^a   Li, Dichen ^a   Wang, Chaofeng ^b   Wang, Zhen ^b   Lu, Bingheng ^a  

^a XI'AN JIAOTONG UNIVERSITY   (China)

^b FOURTH MILITARY MEDICAL UNIVERSITY   (China)

Author keywords

Cell cultures; Channel; CPC; Scaffold

Indexed keywords

CALCIUM PHOSPHATE; CELL CULTURE; CELL PROLIFERATION; CHANNEL FLOW; RAPID PROTOTYPING;

CALCIUM PHOSPHATE CEMENT (CPC); CELL MIGRATION; CENTRAL CHANNELS; MARROW STEM CELLS (MSC);

BONE CEMENT;

BONE CEMENT; CALCIUM PHOSPHATE;

ANIMAL CELL; ARTICLE; BIOENGINEERING; BIOTECHNOLOGY; CELL ADHESION; CELL CULTURE; CELL GROWTH; CELL LABELING; CELL PROLIFERATION; EXPERIMENTAL STUDY; HEMATOPOIETIC STEM CELL; IMAGE ANALYSIS; LINEAR SYSTEM; NONHUMAN; POROSITY; PRIORITY JOURNAL; STEREORADIOGRAPHY;

ANIMALS; CALCIUM PHOSPHATES; CELL ADHESION; CELL CULTURE TECHNIQUES; CELL PROLIFERATION; CELLS, CULTURED; CEMENTATION; POROSITY; RABBITS; SURFACE PROPERTIES; TIME FACTORS;

ORYCTOLAGUS CUNICULUS;

EID: 33947543871     PISSN: 09592989     EISSN: None     Source Type: Journal    
DOI: None     Document Type: Article

References (21)

1. F.J. O'Brien, B.A. Harleyc, I.V. Yannas and L.J. Gibson, The effect of pore size on cell adhesion in collagen-GAG scaffolds, Biomaterials 26 (2005), 433-441.
2. S.L. Ishaug-Riley, G.M. Crane-Kruger, M.J. Yaszemski and A.G. Mikos, Three-dimensional culture of rat calvarial osteoblasts in porous biodegradable polymers, Biomaterials 19(15) (1998), 1405-1412.
3. D.W. Hutmacher, Scaffold design, fabrication technologies for engineering tissue state of the art and future perspective, J. Biomater. Sci. Polym. Edn. II: 107-124.
4. Itoh Soichiro, Kikuchi Masanori, Koyama Yosihisa, et al., Development of a novel biomaterial, hydroxyapatite/collagen (HAp/Col) composite for medical use, Bio-Medical Materials & Engineering 15 (2005), 29-41.
5. Y. Sakaia, M. Otsukab, S. Hanadaa, Y. Nishiyamac, Y. Konishic and A. Yamashitab, A novel poly-L-lactic acid scaffold that possesses a macroporous structure and a branching/joining three-dimensional flow channel network: its fabrication and application to perfusion culture of human hepatoma Hep G2 cells, Materials Science and Engineering C 24 (2004), 379-386.
6. K.T. Chu, Y. Oshida, E.B. Hancock, et al., Hydroxyapatite/PMMA composites as bone cements, Bio-Medical Materials & Engineering 14 (2004), 87-105.
7. A.S.P. Lin, T.H. Barrows, S.H. Cartmell and R.E. Guldberg, Microarchitectural and mechanical characterization of orientated porous polymer scaffolds, Biomaterials 24 (2003), 481-489.
8. T.M. Gabriel Chu, D.G. Orton, S.J. Hollister, S.E. Feinburg and J.W. Halloran, Mechanical and in vivo performance of hydroxyapatite implants with controlled architectures, Biomaterials 23 (2002), 1283-1293.
9. E. Charriere, J. Lemaitre and Ph. Zysset, Hydroxyapatite cement scaffolds with controlled macroporosity: fabrication protocol and mechanical properties, Biomaterials 24 (2003), 809-817.
10. J. Zeltinger, J.K. Sherwood, D.A. Graham, R. Mueller and L.G. Griffith, Effect of pore size and void fraction on cellular adhesion, proliferation, and matrix deposition, Tissue Eng. 7(5) (2201), 557-572.
11. M.C. Wake, C.W. Patrick Jr. and A.G. Mikos, Pore morphology effects on the fibrovascular tissue growth in porous polymer substrates, Cell Transplatant. 3(4) (1994), 339-343.
12. Hockin H.K. Xu a and Carl G. Simon Jr., Self-hardening calcium phosphate composite scaffold for bone tissue engineering, Journal of Orthopaedic Research 22 (2004), 535-543.
13. H.H.K. Xu and J.B. Quinn, Calcium phosphate cement containing resorbable fibers for short-term reinforcement and macroporosity, Biomaterials 23 (2002), 193-202.
14. W. Suchanek and M. Yoshimura, Processing and properties of hydroxyapatite-based biomaterials for use as hard tissue replacement implants, J. Mater. Res. 13 (1998), 94-117.
15. Richard P. Haugland, Fluorescent lipophilic tracer. In: Richard P. Haugland, Michelle T.Z. Spence, Iain D. Johnson, eds, Handbook of fluorescent probes and research hemicals, 6th ed., Oregon: Eugene, 1996, 344-350.
16. Prasad K.D.V. Yarlagadda, Margam Chandrasekharan and John Yong Ming Shyan, Recent advances and current developments in tissue scaffolding, Bio-Medical Materials & Engineering 15 (2005), 159-177.
17. Humberto E. Soriano, The use of DiI-marked hepatocytes to demonstrate or orthotopic, intra hepaticeng raftment following hepatocellular transplantation, Transplantation 54 (1992), 717-723.
18. A.S. Goldstein, T.M. Juarez, C.D. Helmke, M.C. Gustin and A.G. Mikos, Effect of convection on osteoblastic cell growth and function in biodegradable polymer foam scaffolds, Biomaterials 22 (2001), 1279-1288.
19. E.A. Botchwey, M.A. Dupree, S.R. Pollack, E.M. Levine and C.T. Laurencin, Tissue engineered bone: measurement of nutrient transport in three-dimensional matrices, J. Biomed. Mater. Res. 67A (2003), 357-367.
20. S.L. Ishaug, G.M. Crane, M.J. Miller, A.W. Yasko, M.J. Yaszemski and A.G. Mikos, Bone formation by three-dimensional stromal osteoblast culture in biodegradable polymer scaffolds, J. Biomed. Mater. Res. 36(1) (1997), 17-18.
21. K.H. Frosch, F. Barvencik, C.H. Lohmann, V. Viereck, H. Siggelkow, J. Breme, K. Dresing and K.M. Strurmer, Migration, matrix production and lamellar bone formation of human osteoblast-like cells in porous titanium implants, Cell Tissues Organs 170 (2002), 214-227.