Porous titanium scaffolds fabricated using a rapid prototyping and powder metallurgy technique

Biomaterials

Volumn 29, Issue 27, 2008, Pages 3625-3635

  Ryan, Garrett E ^a   Pandit, Abhay S ^a   Apatsidis, Dimitrios P ^a  

^a NATIONAL UNIVERSITY OF IRELAND   (Ireland)

Author keywords

Microstructure; Rapid prototyping; Scaffold; Three dimensional printing; Titanium

Indexed keywords

ALUMINUM POWDER METALLURGY; ANISOTROPY; ARCHITECTURAL DESIGN; BIOMECHANICS; CHEMICAL ENGINEERING; COMPACTION; COMPUTER NETWORKS; COMPUTERIZED TOMOGRAPHY; CONCURRENT ENGINEERING; CRYSTALLOGRAPHY; DIAGNOSTIC RADIOGRAPHY; ELECTRON MICROSCOPES; ELECTRON MICROSCOPY; ELECTRON OPTICS; IMAGING TECHNIQUES; JOB ANALYSIS; MEDICAL IMAGING; METALLURGY; METALS; METROPOLITAN AREA NETWORKS; MICROSCOPIC EXAMINATION; NETWORK PROTOCOLS; ORES; PORE SIZE; POROSITY; POWDER METALLURGY; POWDERS; PRODUCT DEVELOPMENT; RAPID PROTOTYPING; RECONSTRUCTION (STRUCTURAL); SCANNING; SCANNING ELECTRON MICROSCOPY; SINTERING; SMELTING; STEEL ANALYSIS; THREE DIMENSIONAL; TITANIUM; TOMOGRAPHY;

(PL) PROPERTIES; ARCHITECTURAL PARAMETERS; AXIAL DIRECTIONS; BIOMECHANICAL PROPERTIES; COMPACTION PRESSURES; COMPRESSION STRENGTHS; ELSEVIER (CO); IMPLANT DESIGN; INTERCONNECTED PORE NETWORKS; MICRO COMPUTED TOMOGRAPHY (MICRO CT); MULTI-STAGE; ORTHOPAEDIC APPLICATIONS; POROUS TITANIUM; PROTOTYPING; RESEARCH REPORTS; SINTERING TEMPERATURES; SLURRY CONCENTRATION; STRUCTURAL DISORDERING; THREE DIMENSIONAL (3 D) RECONSTRUCTION; TITANIUM SCAFFOLDS; TRANSVERSE DIRECTION (TD);

SCAFFOLDS;

MOLECULAR SCAFFOLD; TITANIUM;

ANIMAL CELL; ANISOTROPY; ARTICLE; COMPOSITE GRAFT; CONTROLLED STUDY; METALLURGY; MICRO-COMPUTED TOMOGRAPHY; NONHUMAN; PARTICLE SIZE; POROSITY; POWDER; PRIORITY JOURNAL; SCANNING ELECTRON MICROSCOPY; TEMPERATURE;

BIOCOMPATIBLE MATERIALS; CELL LINE; HUMANS; METALLURGY; MICROSCOPY, ELECTRON, SCANNING; POWDERS; TISSUE ENGINEERING; TITANIUM;

EID: 46749083754     PISSN: 01429612     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.biomaterials.2008.05.032     Document Type: Article

References (58)

1. Karageorgiou V., and Kaplan D. Porosity of 3D biomaterial scaffolds and osteogenesis. Biomaterials 26 27 (2005) 5474-5491
2. Giannoudis P.V., Dinopoulos H., and Tsiridis E. Bone substitutes: an update. Injury 36 Suppl. 3 (2005) S20-S27
3. Al Ruhaimi K.A. Bone graft substitutes: a comparative qualitative histologic review of current osteoconductive grafting materials. Int J Oral Maxillofac Implants 16 1 (2001) 105-114
4. Laurencin C., Khan Y., and El-Amin S.F. Bone graft substitutes. Expert Rev Med Dev 3 1 (2006) 49-57
5. Fantigrossi A., Galbusera F., Raimondi M.T., Sassi M., and Fornari M. Biomechanical analysis of cages for posterior lumbar interbody fusion. Med Eng Phys 29 1 (2007) 101-109
6. Agazzi S., Reverdin A., and May D. Posterior lumbar interbody fusion with cages: an independent review of 71 cases. J Neurosurg 91 Suppl. 2 (1999) 186-192
7. Lin C.Y., Wirtz T., Lamarca F., and Hollister S.J. Structural and mechanical evaluations of a topology optimized titanium interbody fusion cage fabricated by selective laser melting process. J Biomed Mater Res A (2007)
8. Takemoto M., Fujibayashi S., Neo M., So K., Akiyama N., Matsushita T., et al. A porous bioactive titanium implant for spinal interbody fusion: an experimental study using a canine model. J Neurosurg Spine 7 4 (2007) 435-443
9. Assad M., Jarzem P., Leroux M.A., Coillard C., Chernyshov A.V., Charette S., et al. Porous titanium-nickel for intervertebral fusion in a sheep model: part 1. Histomorphometric and radiological analysis. J Biomed Mater Res B Appl Biomater 64B 2 (2003) 107-120
10. Likibi F., Assad M., Coillard C., Chabot G., and Rivard C.H. Bone integration and apposition of porous and non porous metallic orthopaedic biomaterials. Ann Chir 130 4 (2005) 235-241
11. Levi A.D., Choi W.G., Keller P.J., Heiserman J.E., Sonntag V.K., and Dickman C.A. The radiographic and imaging characteristics of porous tantalum implants within the human cervical spine. Spine 23 11 (1998) 1245-1250 Discussion 1251
12. Wigfield C., Robertson J., Gill S., and Nelson R. Clinical experience with porous tantalum cervical interbody implants in a prospective randomized controlled trial. Br J Neurosurg 17 5 (2003) 418-425
13. Levine B., Sporer S., Della Valle C.J., Jacobs J.J., and Paprosky W. Porous tantalum in reconstructive surgery of the knee: a review. J Knee Surg 20 3 (2007) 185-194
14. Head W.C., Bauk D.J., and Emerson Jr. R.H. Titanium as the material of choice for cementless femoral components in total hip arthroplasty. Clin Orthop 311 (1995) 85-90
15. Hirschhorn J.S., McBeath A.A., and Dustoor M.R. Porous titanium surgical implant materials. J Biomed Mater Res Symp (1971) 49-67
16. Oh I.H., Nomura N., Masahashi N., and Hanada S. Mechanical properties of porous titanium compacts prepared by powder sintering. Script Mat 49 (2003) 1197-1202
17. Weiss M.B. Titanium fiber-mesh metal implant. J Oral Implantol 12 3 (1986) 498-507
18. Zhang X., Ayers R.A., Thorne K., Moore J.J., and Schowengerdt F. Combustion synthesis of porous materials for bone replacement. Biomed Sci Instrum 37 (2001) 463-468
19. Heinl P., Muller L., Korner C., Singer R.F., and Muller F.A. Cellular Ti-6Al-4V structures with interconnected macro porosity for bone implants fabricated by selective electron beam melting. Acta Biomater (2008)
20. Ponader S., Vairaktaris E., Heinl P., Wilmowsky C.V., Rottmair A., Korner C., et al. Effects of topographical surface modifications of electron beam melted Ti-6Al-4V titanium on human fetal osteoblasts. J Biomed Mater Res A 84 4 (2008) 1111-1119
21. Davis N.G., Teisen J., Schuh C., and Dunand D.C. Solid-state foaming of titanium by superplastic expansion of argon-filled pores. J Mater Res 16 5 (2001) 1508-1519
22. Li J.P., Li S.H., van Blitterswijk C.A., and de Groot K. A novel porous Ti6Al4V: characterization and cell attachment. J Biomed Mater Res 73A 2 (2005) 223-233
23. Yeong W.Y., Chua C.K., Leong K.F., and Chandrasekaran M. Rapid prototyping in tissue engineering: challenges and potential. Trends Biotechnol 22 12 (2004) 643-652
24. Hutmacher D.W., Sittinger M., and Risbud M.V. Scaffold-based tissue engineering: rationale for computer-aided design and solid free-form fabrication systems. Trends Biotechnol 22 7 (2004) 354-362
25. Sun W., Darling A., Starly B., and Nam J. Computer-aided tissue engineering: overview, scope and challenges. Biotechnol Appl Biochem 39 Pt 1 (2004) 29-47
26. Curodeau A., Sachs E., and Caldarise S. Design and fabrication of cast orthopedic implants with freeform surface textures from 3-D printed ceramic shell. J Biomed Mater Res 53 5 (2000) 525-535
27. Lopez-Heredia M.A., Goyenvalle E., Aguado E., Pilet P., Leroux C., Dorget M., et al. Bone growth in rapid prototyped porous titanium implants. J Biomed Mater Res A 85 3 (2008) 664-673
28. Lopez-Heredia M.A., Sohier J., Gaillard C., Quillard S., Dorget M., and Layrolle P. Rapid prototyped porous titanium coated with calcium phosphate as a scaffold for bone tissue engineering. Biomaterials 29 17 (2008) 2608-2615
29. Li J.P., de Wijn J.R., van Blitterswijk C.A., and de Groot K. Porous Ti6Al4V scaffolds directly fabricated by 3D fibre deposition technique: effect of nozzle diameter. J Mater Sci Mater Med 16 12 (2005) 1159-1163
30. Hollander D.A., von Walter M., Wirtz T., Sellei R., Schmidt-Rohlfing B., Paar O., et al. Structural, mechanical and in vitro characterization of individually structured Ti-6Al-4V produced by direct laser forming. Biomaterials 27 7 (2006) 955-963
31. Sachlos E., and Czernuszka J.T. Making tissue engineering scaffolds work. Review: the application of solid freeform fabrication technology to the production of tissue engineering scaffolds. Eur Cell Mater 5 (2003) 29-39 Discussion 39-40
32. Cameron H.U., Pilliar R.M., and Macnab I. The rate of bone ingrowth into porous metal. J Biomed Mater Res 10 2 (1976) 295-302
33. Gomes M.E., Sikavitsas V.I., Behravesh E., Reis R.L., and Mikos A.G. Effect of flow perfusion on the osteogenic differentiation of bone marrow stromal cells cultured on starch-based three-dimensional scaffolds. J Biomed Mater Res A 67 1 (2003) 87-95
34. Cartmell S.H., Porter B.D., Garcia A.J., and Guldberg R.E. Effects of medium perfusion rate on cell-seeded three-dimensional bone constructs in vitro. Tissue Eng 9 6 (2003) 1197-1203
35. Hollister S.J., Maddox R.D., and Taboas J.M. Optimal design and fabrication of scaffolds to mimic tissue properties and satisfy biological constraints. Biomaterials 23 20 (2002) 4095-4103
36. Fang Z., Starly B., and Sun W. Computer-aided characterization for effective mechanical properties of porous tissue scaffolds. Comput-Aided Des 37 1 (2005) 65-72
37. Gupta G., Zbib A., El-Ghannam A., Khraisheh M., and Zbib H. Characterization of a novel bioactive composite using advanced X-ray computed tomography. Compos Struct 71 3-4 (2005) 423-428
38. Knackstedt M.A., Arns C.H., Senden T.J., and Gross K. Structure and properties of clinical coralline implants measured via 3D imaging and analysis. Biomaterials 27 13 (2006) 2776-2786
39. Jones J.R., Poologasundarampillai G., Atwood R.C., Bernard D., and Lee P.D. Non-destructive quantitative 3D analysis for the optimisation of tissue scaffolds. Biomaterials 28 7 (2007) 1404-1413
40. Meretoja V.V., De Ruijter A.E., Peltola T.O., Jansen J.A., and Narhi T.O. Osteoblast differentiation with titania and titania-silica-coated titanium fiber meshes. Tissue Eng 11 9-10 (2005) 1489-1497
41. Beloti M.M., and Rosa A.L. Osteoblast differentiation of human bone marrow cells under continuous and discontinuous treatment with dexamethasone. Braz Dent J 16 2 (2005) 156-161
42. Schutze N., Noth U., Schneidereit J., Hendrich C., and Jakob F. Differential expression of CCN-family members in primary human bone marrow-derived mesenchymal stem cells during osteogenic, chondrogenic and adipogenic differentiation. Cell Commun Signal 3 1 (2005) 5
43. Wen C.E., Yamada Y., Shimojima K., Chino Y., Asahina T., and Mabuchi M. Processing and mechanical properties of autogenous titanium implant materials. J Mater Sci Mater Med 13 4 (2002) 397-401
44. Li J.P., Li S.H., de Groot K., and Layrolle P. Preparation and characterization of porous titanium. Key Eng Mater 218 (2002) 51-54
45. Li J.P., de Wijn J.R., Van Blitterswijk C.A., and de Groot K. Porous Ti6Al4V scaffold directly fabricating by rapid prototyping: preparation and in vitro experiment. Biomaterials 27 8 (2006) 1223-1235
46. Gibson L., and Ashby M. Cellular solids: structure and properties. 2nd ed. (1999), Cambridge University Press, Cambridge
47. Cunningham B.W., Orbegoso C.M., Dmitriev A.E., Hallab N.J., Sefter J.C., Asdourian P., et al. The effect of spinal instrumentation particulate wear debris. An in vivo rabbit model and applied clinical study of retrieved instrumentation cases. Spine J 3 1 (2003) 19-32
48. Wang J.C., Yu W.D., Sandhu H.S., Betts F., Bhuta S., and Delamarter R.B. Metal debris from titanium spinal implants. Spine 24 9 (1999) 899-903
49. Robinson S.K., and Paul M.R. Debinding and sintering solutions for metals and ceramics. Met Powder Rep 56 6 (2001) 24-26
50. Jacobs C.R., Simo J.C., Beaupre G.S., and Carter D.R. Adaptive bone remodeling incorporating simultaneous density and anisotropy considerations. J Biomech 30 6 (1997) 603-613
51. Smit T.H., Odgaard A., and Schneider E. Structure and function of vertebral trabecular bone. Spine 22 24 (1997) 2823-2833
52. Lin C.Y., Kikuchi N., and Hollister S.J. A novel method for biomaterial scaffold internal architecture design to match bone elastic properties with desired porosity. J Biomech 37 5 (2004) 623-636
53. Spoerke E.D., Murray N.G., Li H., Brinson L.C., Dunand D.C., and Stupp S.I. Titanium with aligned, elongated pores for orthopedic tissue engineering applications. J Biomed Mater Res A (2007)
54. Kim H.S., and Al-Hassani S.T. A morphological model of vertebral trabecular bone. J Biomech 35 8 (2002) 1101-1114
55. Banerjee R., Nag S., and Fraser H.L. A novel combinatorial approach to the development of beta titanium alloys for orthopaedic implants. Mater Sci Eng C - Biomim Supramol Syst 25 3 (2005) 282-289
56. Eisenbarth E., Velten D., Muller M., Thull R., and Breme J. Biocompatibility of beta-stabilizing elements of titanium alloys. Biomaterials 25 26 (2004) 5705-5713
57. Taddei E.B., Henriques V.A.R., Silva C.R.M., and Cairo C.A.A. Production of new titanium alloy for orthopedic implants. Mater Sci Eng C - Biomim Supramol Syst 24 5 (2004) 683-687
58. Ho S.T., and Hutmacher D.W. A comparison of micro CT with other techniques used in the characterization of scaffolds. Biomaterials 27 8 (2006) 1362-1376