Mechanical characteristics of solid-freeform-fabricated porous calcium polyphosphate structures with oriented stacked layers

Acta Biomaterialia

Volumn 7, Issue 4, 2011, Pages 1788-1796

  Shanjani, Yaser ^a   Hu, Youxin ^b   Pilliar, Robert M ^b   Toyserkani, Ehsan ^a  

^a UNIVERSITY OF WATERLOO   (Canada)

^b UNIVERSITY OF TORONTO   (Canada)

Author keywords

Additive manufacturing; Bone substitutes; Calcium polyphosphate (CPP); Mechanical properties; Solid freeform fabrication (SFF)

Indexed keywords

3D PRINTERS; CALCIUM COMPOUNDS; COMPRESSION TESTING; COMPRESSIVE STRENGTH; FABRICATION; SCANNING ELECTRON MICROSCOPY; STRUCTURAL PROPERTIES; TENSILE TESTING;

BONE SUBSTITUTES; CALCIUM POLYPHOSPHATE; FABRICATION TECHNIQUE; FREEFORMS; MECHANICAL CHARACTERISTICS; POROUS STRUCTURES; POWDER-BASED; SOLID FREEFORM FABRICATION; STACKED LAYER;

TENSILE STRENGTH;

CALCIUM POLYPHOSPHATE; POLYPHOSPHATE; POROUS POLYMER; UNCLASSIFIED DRUG;

ANISOTROPY; ARTICLE; MECHANICAL STRESS; NANOFABRICATION; PARTICLE SIZE; PRIORITY JOURNAL; SCANNING ELECTRON MICROSCOPY; TENSILE STRENGTH;

EID: 79952188003     PISSN: 17427061     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.actbio.2010.12.017     Document Type: Article

References (65)

1. M.D. Kwan, D.C. Wan, and M.T. Longaker Skeletal-tissue engineering R. Lanza, R. Langer, J. Vacanti, Principles of tissue engineering 3rd ed. 2007 Elsevier New York 935 944
2. D.W. Hutmacher Scaffolds in tissue engineering bone and cartilage Biomaterials 21 24 2000 2529 2543
3. C.Y. Lin, N. Kikuchi, and S.J. Hollister A novel method for biomaterial scaffold internal architecture design to match bone elastic properties with desired porosity J Biomech 37 5 2004 623 636 (Pubitemid 38445024)
4. W.J.E.M. Habraken, H.B. Liao, Z. Zhang, J.G.C. Wolke, D.W. Grijpma, and A.G. Mikos In vivo degradation of calcium phosphate cement incorporated into biodegradable microspheres Acta Biomater 6 6 2010 2200 2211
5. E.L. Hedberg, H.C. Kroese-Deutman, C.K. Shih, R.S. Crowther, D.H. Carney, and A.G. Mikos In vivo degradation of porous poly(propylene fumarate)/poly(dl-lactic-co-glycolic acid) composite scaffolds Biomaterials 26 22 2005 4616 4623 (Pubitemid 40269278)
6. H.M. Frost Bone "mass" and the "mechanostat": a proposal Anat Rec 219 1 1987 1 9
7. J. Hollister Porous scaffold design for tissue engineering Nat Mater 4 2005 518 524
8. A.S.P. Lin, T.H. Barrows, S.H. Cartmell, and R.E. Guldberg Microarchitectural and mechanical characterization of oriented porous polymer scaffolds Biomaterials 24 3 2003 481 489 (Pubitemid 35287519)
9. P.X. Ma, J. Elisseeff, Scaffolding in tissue engineering 2006 Taylor & Francis Boca Raton, FL
10. A.S. Mistry, and A.G. Mikos Tissue engineering strategies for bone regeneration Adv Biochem Eng Biotechnol 94 2005 1 22 (Pubitemid 44608653)
11. S.V. Dorozhkin Bioceramics of calcium orthophosphates Biomaterials 31 7 2010 1465 1485
12. D. Shi, Introduction to biomaterials 2006 World Scientific Singapore
13. F. Guilak, D.L. Butler, S.A. Goldstein, D. Mooney, Functional tissue engineering 1st ed. 2004 Springer Verlag New York
14. R.A. Kandel, M. Grynpas, R. Pilliar, J. Lee, J. Wang, and S. Waldman Repair of osteochondral defects with biphasic cartilage-calcium polyphosphate constructs in a sheep model Biomaterials. 27 2006 4120 4131
15. R.M. Pilliar, M.J. Filiaggi, J.D. Wells, M.D. Grynpas, and R.A. Kandel Porous calcium polyphosphate scaffolds for bone substitution applications - in vitro characterization Biomaterials. 22 2001 963 972 (Pubitemid 32201447)
16. I. Gibson, D.W. Rosen, and B. Stucker Additive manufacturing technologies: rapid prototyping to direct digital 2010 Springer Verlag New York
17. K.F. Leong, C.M. Cheah, and C.K. Chua Solid freeform fabrication of three-dimensional scaffolds for engineering replacement tissues and organs Biomaterials 24 2003 2363 2378 (Pubitemid 36434056)
18. Chua CK, Leong KF, Lim CS. Rapid prototyping: principles and applications, 2nd ed. Singapore: Springer; 2003.
19. E. Sachlos, and J.T. Czernuszka Making tissue engineering scaffolds work. Review on the application of solid freeform fabrication technology to the production of tissue engineering scaffolds Eur Cell Mater 5 2003 29 40 (Pubitemid 38957399)
20. D.W. Hutmacher, M. Michael Sittinger, and M.V. Risbud Scaffold-based tissue engineering: rationale for computer-aided design and solid free-form fabrication systems Trends Biotechnol 22 7 2004 354 362 (Pubitemid 38887544)
21. J.K. Sherwood, S.L. Riley, R. Palazzolo, S.C. Brown, D.C. Monkhouse, and M. Coates A three-dimensional osteochondral composite scaffold for articular cartilage repair Biomaterials 23 24 2002 4739
22. U. Gbureck, T. Holzel, I. Biermann, J.E. Barralet, and L.M. Grover Preparation of tricalcium phosphate/calcium pyrophosphate structures via rapid prototyping J Mater Sci: Mater Med 19 2008 1559 1563
23. P. Habibovic, U. Gbureck, C.J. Doillon, D.C. Bassett, C.A. Blitterswijk, and J.E. Barralet Osteoconduction and osteoinduction of low-temperature 3D printed bioceramic implants Biomaterials 29 7 2008 944 953 (Pubitemid 350284589)
24. U. Gbureck, T. Holzel, U. Klammert, K. Wurzler, F.A. Muller, and J.E. Barralet Resorbable dicalcium phosphate bone substitutes prepared by 3D powder printing Adv Funct Mater 17 2007 3940 3945
25. E. Vorndran, M. Klarner, U. Klammert, L.M. Grover, S. Patel, and J.E. Barralet 3D powder printing of β-tricalcium phosphate ceramics using different strategies Adv Eng Mater 10 12 2008 B67 B71
26. R. Chumnanklang, T. Panyathanmaporn, K. Sitthiseripratip, and J. Suwanprateeb 3D printing of hydroxyapatite: effect of binder concentration in pre-coated particle on part strength Mater Sci Eng: C 27 4 2007 914 921 (Pubitemid 46656217)
27. H. Seitz, W. Rieder, S. Irsen, B. Leukers, and C. Tille Three-dimensional printing of porous ceramic scaffolds for bone tissue engineering J Biomed Mater Res B Appl Biomater 74B 2 2005 782
28. K.H. Tan, C.K. Chua, K.F. Leong, C.M. Cheah, P. Cheang, and M.S. Abu Bakar Scaffold development using selective laser sintering of polyetheretherketone-hydroxyapatite biocomposite blends Biomaterials 24 18 2003 3115 3123 (Pubitemid 36944942)
29. M.J. Mondrinos, R. Dembzynski, L. Lu, V.K.C. Byrapogu, D.M. Wootton, and P.I. Lelkes Porogen-based solid freeform fabrication of polycaprolactone-calcium phosphate scaffolds for tissue engineering Biomaterials 27 25 2006 4399 4408
30. F.C. Fierz, F. Beckmann, M. Huser, S.H. Irsen, B. Leukers, and F. Witte The morphology of anisotropic 3D-printed hydroxyapatite scaffolds Biomaterials. 29 2008 3799 3806
31. A. Khalyfa, S. Vogt, J. Weisser, G. Grimm, A. Rechtenbach, and W. Meyer Development of a new calcium phosphate powder-binder system for the 3D printing of patient specific implants J Mater Scir: Mater Med 18 5 2007 909 916 (Pubitemid 46764024)
32. K. Lu, M. Hisera, and W. Wu Effect of particle size on three dimensional printed mesh structures Powder Technol 192 2 2009 178 183
33. S. Eosoly, D. Brabazon, S. Lohfeld, and L. Looney Selective laser sintering of hydroxyapatite/poly - caprolactone scaffolds Acta Biomater 6 7 2010 2511 2517
34. S. Eshraghi, and S. Das Mechanical and microstructural properties of polycaprolactone scaffolds with one-dimensional, two-dimensional, and three-dimensional orthogonally oriented porous architectures produced by selective laser sintering Acta Biomater 6 7 2010 2467 2476
35. B. Caulfield, P.E. McHugh, and S. Lohfeld Dependence of mechanical properties of polyamide components on build parameters in the SLS process J Mater Process Technol 182 1-3 2007 477 488 (Pubitemid 44693327)
36. C.S. Lee, S.G. Kim, H.J. Kim, and S.H. Ahn Measurement of anisotropic compressive strength of rapid prototyping parts J Mater Process Technol. 187-188 2007 627 630 (Pubitemid 46412882)
37. Y. Shanjani, J.N.A. De Croos, R.M. Pilliar, R.A. Kandel, and E. Toyserkani Solid freeform fabrication and characterization of porous calcium polyphosphate structures for tissue engineering purposes J Biomed Mater Res B Appl Biomater 93B 2 2010 510 519
38. Pilliar RM, Hong J, Santerre PJ. Method of manufacture of porous inorganic structures. US patent 7494614; 2009.
39. M. Filiaggi, R.M. Pilliar, and J. Hong On the sintering characteristics of calcium polyphosphates Key Eng Mater 192-195 2001 171 174 (Pubitemid 32073895)
40. R.M. German Sintering theory and practice 1996 John Wiley New York
41. O. Bermúdez, M.G. Boltong, F.C.M. Driessens, and J.A. Planell Compressive strength and diametral tensile strength of some calcium orthophosphate cements: a pilot study J Mater Sci Mater Med 4 1993 389 393 (Pubitemid 23322807)
42. D.K. Shetty, A.R. Rosenfield, and W.H. Duckworth Mixed-mode fracture of ceramics in diametral compression J Am Ceram Soc 69 6 1986 437 443 (Pubitemid 16591539)
43. S.J. Ding, C.W. Wang, D.C.H. Chen, and H.C. Chang In vitro degradation behavior of porous calcium phosphates under diametral compression loading Ceram Int 31 5 2005 691 696
44. R.I. Martin, and P.W. Brown Mechanical properties of hydroxyapatite formed at physiological temperature J Mater Sci Mater Med 6 3 1995 138 143
45. G. With Note on the use of the diametral compression test for the strength measurement of ceramics J Mater Sci Lett 3 11 1984 1000 1002 (Pubitemid 14661502)
46. M. Mellor, and I. Hawkes Measurement of tensile strength by diametral compression of discs and annuli Eng Geol 5 3 1971 173 225
47. W. Weibull A statistical distribution function of wide applicability J Appl Mech - Trans ASME 18 1951 293 297
48. M.J. Bannister Shape sensitivity of initial sintering equations J Am Ceram Soc 51 10 1968 548 553
49. J.C. Le Huec, T. Schaeverbeke, D. Clement, J. Faber, and A. Le Rebeller Influence of porosity on the mechanical resistance of hydroxyapatite ceramics under compressive stress Biomaterials 113 2 1995 113 118
50. E. Ryshkewitch Compression strength of porous sintered alumina and zirconia, 9th communication to ceramography J Am Ceram Soc 36 2 1953 65 68
51. L.H. He, O.C. Standard, T.T.Y. Huang, B.A. Latella, and M.V. Swain Mechanical behaviour of porous hydroxyapatite Acta Biomater 4 3 2008 577 586 (Pubitemid 351461284)
52. E.Z. Wang, and N.G. Shrive Brittle fracture in compression: mechanisms, models and criteria Eng Fract Mech 52 6 1995 1107 1126
53. A.P. Roberts, and E.J. Garboczi Elastic properties of model porous ceramics J Am Ceram Soc 83 12 2000 3041 3048 (Pubitemid 32089690)
54. I. Vardoulakis, J.F. Labuz, E. Papamichos, and J. Tronvoll Continuum fracture mechanics of uniaxial compression on brittle materials Int J Solids Struct 35 31-32 1998 4313 4335 (Pubitemid 128384154)
55. T. Sadowski, and S. Samborski Development of damage state in porous ceramics under compression Comput Mater Sci 43 1 2008 75 81 (Pubitemid 351778350)
56. T. Sadowski, and S. Samborski Prediction of the mechanical behaviour of porous ceramics using mesomechanical modelling Comput Mater Sci 28 3-4 2003 512 517
57. D.J. Green An introduction to the mechanical properties of ceramics 1998 Cambridge University Press Cambridge
58. O. Hoffman The brittle strength of orthotropic materials J Compos Mater 1 2 1967 200 206
59. A. Gebhardt Rapid prototyping 1st ed. 2003 Hanser Munich
60. Albright JA, Brand RA, editors. The scientific basis of orthopaedics, 1st ed. New York: Appleton-Century-Crofts; 1979.
61. T.M.G. Chu, D.G. Orton, S.J. Hollister, S.E. Feinberg, and J.W. Halloran Mechanical and in vivo performance of hydroxyapatite implants with controlled architectures Biomaterials 23 5 2002 1283 1293 (Pubitemid 34112425)
62. P. Miranda, A. Pajares, E. Saiz, A.P. Tomsia, and F. Guiberteau Mechanical properties of calcium phosphate scaffolds fabricated by robocasting J Biomed Mater Res A 85 1 2008 218 227 (Pubitemid 351355371)
63. S. Deville, E. Saiza, and A.P. Tomsia Freeze casting of hydroxyapatite scaffolds for bone tissue engineering Biomaterials 27 32 2006 5480 5489 (Pubitemid 44176143)
64. J. Tian, and J. Tian Preparation of porous hydroxyapatite J Mater Sci 36 12 2001 3061 3066 (Pubitemid 32680851)
65. Q. Fu, M.N. Rahaman, F. Dogan, and B.S. Bal Freeze-cast hydroxyapatite scaffolds for bone tissue engineering applications Biomed Mater 3 2 2008 1 7