Micromechanics of bone tissue-engineering scaffolds, based on resolution error-cleared computer tomography

Biomaterials

Volumn 30, Issue 12, 2009, Pages 2411-2419

  Scheiner, Stefan ^a   Sinibaldi, Raffaele ^b   Pichler, Bernhard ^a   Komlev, Vladimir ^b,c   Renghini, Chiara ^b   Vitale Brovarone, Chiara ^d   Rustichelli, Franco ^b   Hellmich, Christian ^a  

^a VIENNA UNIVERSITY OF TECHNOLOGY   (Austria)

^b UNIVERSITÀ POLITECNICA DELLE MARCHE   (Italy)

^c BAIKOV INSTITUTE OF METALLURGY AND MATERIALS SCIENCE   (Russian Federation)

^d POLITECNICO DI TORINO   (Italy)

Author keywords

Bone tissue engineering; CEL2 glass ceramic; Continuum micromechanics; Finite element method; Microtomography; Scaffold

Indexed keywords

ATTENUATION COEFFICIENTS; BONE TISSUE ENGINEERING; CEL2 GLASS-CERAMIC; CHARACTERISTIC LENGTHS; COMPUTER TOMOGRAPHIES; CONTINUUM MICROMECHANICS; CT DATUM; ELASTIC PROPERTIES; EXPERIMENTAL VALUES; FINITE ELEMENT SIMULATIONS; FINITE-ELEMENT ANALYSIS; GLASS-CERAMIC MATRICES; INSTRUMENTAL RESOLUTIONS; LORENTZ FUNCTIONS; MACHINE ERRORS; MACRO-PORES; MACROPOROUS; MICRO-COMPUTED TOMOGRAPHIES; MICROTOMOGRAPHY; NANO POROSITIES; PREDICTIVE CAPABILITIES; PROBABILITY DENSITIES; SCAFFOLD STRUCTURES; SPECIFIC ATTENUATIONS; SYSTEMATIC RESOLUTIONS; TOMOGRAPH; ULTRASONIC TESTS; UNIAXIAL COMPRESSION TESTS; YOUNG'S MODULUS;

BONE; CERAMIC MATERIALS; COMPRESSION TESTING; COMPUTERIZED TOMOGRAPHY; DIAGNOSTIC RADIOGRAPHY; ELASTICITY; FINITE ELEMENT METHOD; GLASS; MICROMECHANICS; PROBABILITY DENSITY FUNCTION; SECONDARY BATTERIES; TESTING; TISSUE ENGINEERING; TOMOGRAPHY; ULTRASONIC TESTING;

SCAFFOLDS;

GLASS;

ARTICLE; BONE TISSUE; CERAMICS; COMPRESSION; CONTROLLED STUDY; ELASTICITY; ERROR; FINITE ELEMENT ANALYSIS; MICRO-COMPUTED TOMOGRAPHY; POROSITY; PRIORITY JOURNAL; SKELETON; SYNCHROTRON RADIATION; TISSUE ENGINEERING; YOUNG MODULUS;

BIOMECHANICS; BONE AND BONES; ELASTICITY; MODELS, BIOLOGICAL; NANOSTRUCTURES; POROSITY; TISSUE ENGINEERING; TISSUE SCAFFOLDS; TOMOGRAPHY, X-RAY COMPUTED;

EID: 60549102261     PISSN: 01429612     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.biomaterials.2008.12.048     Document Type: Article

References (44)

1. Radon J. Über die Bestimmung von Funktionen durch ihre Integralwerte längs gewisser Mannigfaltigkeiten (On the determination of functions from their integrals along certain manifolds). Berichte der Sächsischen Akademie der Wissenschaften 29 (1917) 262-277 [in German]
2. Hounsfield G. A method of an apparatus for examination of a body by radiation such as X-ray or gamma-radiation. Patent specification 1283915, The Patent Office; 1972.
3. Bonse U., and Busch F. X-ray computed microtomography (μCT) using synchrotron radiation (SR). Prog Biophys Mol Biol 65 1-2 (1996) 133-169
4. Duliu O.G. Computer axial tomography in geosciences: an overview. Earth Sci Rev 48 4 (1999) 265-281
5. Gallucci E., Scrivener K., Groso A., Stampanoni M., and Margaritondo G. 3D experimental investigation of the microstructure of cement pastes using synchrotron X-ray microtomography (μCT). Cement Concrete Res 37 3 (2007) 360-368
6. Komlev V.S., Peyrin F., Mastrogiacomo M., Cedola A., Papadimitropoulos A., Rustichelli F., et al. Kinetics of in vivo bone deposition by bone marrow stromal cells into porous calcium phosphate scaffolds: an X-ray computed microtomography study. Tissue Eng 12 12 (2006) 3449-3458
7. Lim K.S., and Barigou M. X-ray micro-computed tomography of cellular food products. Food Res Int 37 10 (2004) 1001-1012
8. Malzbender J., and Steinbrech R.W. Advanced measurement techniques to characterize thermo-mechanical aspects of solid oxide fuel cells. J Power Sources 173 1 (2007) 60-67
9. Rolland du Roscoat S., Decain M., Thibault X., Geindreau C., and Bloch J.F. Estimation of microstructural properties from synchrotron X-ray microtomography and determination of the REV in paper materials. Acta Mater 55 8 (2007) 2841-2850
10. Shu H., Liu B., Zhu P., Gao X., Yin H., Yuan Q., et al. Investigation of biological microstructures by using diffraction-enhanced imaging computed tomography. Radiat Phys Chem 75 11 (2006) 1835-1840
11. Cancedda R., Cedola A., Giuliani A., Komlev V.S., Lagomarsino S., Mastrogiacomo M., et al. Bulk and interface investigations of scaffolds and tissue-engineered bones by X-ray microtomography and X-ray microdiffraction. Biomaterials 28 15 (2007) 2505-2524
12. Cancedda R., Giannoni P., and Mastrogiacomo M. A tissue engineering approach to bone repair in large animal models and in clinical practice. Biomaterials 28 29 (2007) 4240-4250
13. Mastrogiacomo M., Papadimitropoulos A., Cedola A., Peyrin F., Giannoni P., Pearce S.G., et al. Engineering of bone using bone marrow stromal cells and a silicon-stabilized tricalcium phosphate bioceramic: evidence for a coupling between bone formation and scaffold resorption. Biomaterials 28 7 (2007) 1376-1384
14. Papadimitropoulos A., Mastrogiacomo M., Peyrin F., Molinari E., Komlev V.S., Rustichelli F., et al. Kinetics of in vivo bone deposition by bone marrow stromal cells within a resorbable porous calcium phosphate scaffold: an X-ray computed microtomography study. Biotechnol Bioeng 98 1 (2007) 271-281
15. Peyrin F., Mastrogiacomo M., Cancedda R., and Martinetti R. SEM and 3D synchrotron radiation micro-tomography in the study of bioceramic scaffolds for tissue-engineering applications. Biotechnol Bioeng 97 3 (2007) 638-648
16. Rustichelli F., Romanzetti S., Dubini B., Girardin E., Raven C., Snigirev A., et al. Phase-contrast microtomography of thin biomaterials. J Mater Sci Mater Med 15 9 (2004) 1053-1057
17. Barrére F., Mahmood T.A., de Groot K., and van Blitterswijk C.A. Advanced biomaterials for skeletal tissue regeneration: instructive and smart functions. Mater Sci Eng R Rep 59 1-6 (2008) 38-71
18. Chen Q.Z., Harding S.E., Ali N.N., Lyon A.R., and Boccaccini A.R. Biomaterials in cardiac tissue engineering: ten years of research survey. Mater Sci Eng R Rep 59 1-6 (2008) 1-37
19. Hutmacher D.W. Scaffolds in tissue engineering bone and cartilage. Biomaterials 21 24 (2000) 2529-2543
20. 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
21. Leong K.F., Chua C.K., Sudarmadji N., and Yeong W.Y. Engineering functionally graded tissue engineering scaffolds. J Mech Behav Biomed Mater 1 2 (2008) 140-152
22. Stylios G., Wan T., and Giannoudis P. Present status and future potential of enhancing bone healing using nanotechnology. Injury 38 1 (2007) S63-S74
23. van Gaalen S., Kruyt M., Meijer G., Mistry A., Mikos A., van den Beucken J., et al. Tissue engineering of bone. Tissue Eng (2008) 559-610
24. Williams D.F. On the mechanisms of biocompatibility. Biomaterials 29 20 (2008) 2941-2953
25. Akhtar R., Eichhorn S.J., and Mummery P.M. Microstructure-based finite element modelling and characterisation of bovine trabecular bone. J Bionic Eng 3 1 (2006) 3-9
26. Charles-Harris M., del Valle S., Hentges E., Bleuet P., Lacroix D., and Planell J.A. Mechanical and structural characterization of completely degradable polylactic acid/calcium phosphate glass scaffolds. Biomaterials 28 30 (2007) 4429-4438
27. Lacroix D., Chateau A., Ginebra M.P., and Planell J.A. Micro-finite element models of bone tissue-engineering scaffolds. Biomaterials 27 30 (2006) 5326-5334
28. Laschet G., Kashko T., Angel S., Scheele J., Nickel R., Bleck W., et al. Microstructure-based model for permeability predictions of open-cell foams via homogenization. Mater Sci Eng A Struct Mater 472 1-2 (2008) 214-226
29. Youssef S., Maire E., and Gaertner R. Finite element modelling of the actual structure of cellular materials determined by X-ray tomography. Acta Mater 53 3 (2005) 719-730
30. Renghini C., Komlev V., Rustichelli F., Verne E., Baino F., and Vitale-Brovarone C. Micro-CT studies on 3-D bioactive glass-ceramic scaffolds for bone regeneration. Acta Biomater (2008). Available from: www.sciencedirect.com 10.1016/j.actbio.2008.10.017
31. Vitale-Brovarone C., Verné E., Robiglio L., Appendino P., Bassi F., Martinasso G., et al. Development of glass-ceramic scaffolds for bone tissue engineering: characterisation, proliferation of human osteoblasts and nodule formation. Acta Biomater 3 2 (2007) 199-208
32. Vitale-Brovarone C., Di Nunzio S., Bretcanu O., and Verné E. Macroporous glass-ceramic materials with bioactive properties. J Mater Sci Mater Med 15 3 (2004) 209-217
33. Vitale-Brovarone C., Verné E., Robiglio L., Martinasso G., Canuto R.A., and Muzio G. Biocompatible glass-ceramic materials for bone substitution. J Mater Sci Mater Med 19 1 (2008) 471-478
34. Bracewell R.H., and Riddle A.C. Inversion of fan beam scans in radio astronomy. Astrophys J 150 (1967) 427-434
35. Ramachandran G.N., and Lakshminarayanan A.V. Three-dimensional reconstruction from radiographs and electron micrographs: application of convolutions instead of Fourier transforms. Proc Natl Acad Sci U S A 68 9 (1971) 2236-2240
36. Balzar D. Profile fitting of X-ray diffraction lines and Fourier analysis of broadening. J Appl Crystallogr 25 5 (1995) 559-570
37. Ida T., Hibino H., and Toraya H. Peak profile function for synchrotron X-ray diffractometry. J Appl Crystallogr 34 2 (2001) 144-151
38. Schwefel H.P. Numerische Optimierung von Computer-Modellen mittels der Evolutionsstrategie (Numerical optimization of computer models by means of the evolution strategy) (1977), Birkhäuser Verlag, Basel und Stuttgart [in German]
39. Crawley E.O., Evans W.D., and Owen G.M. A theoretical analysis of the accuracy of single-energy CT bone measurements. Phys Med Biol 33 10 (1988) 1113-1127
40. Hellmich C., Kober C., and Erdmann B. Micromechanics-based conversion of CT data into anisotropic elasticity tensors, applied to FE simulations of a mandible. Ann Biomed Eng 36 1 (2008) 108-122
41. Zaoui A. Continuum micromechanics: survey. J Eng Mech - ASCE 128 8 (2002) 808-816
42. Mori T., and Tanaka K. Average stress in matrix and average elastic energy of materials with misfitting inclusions. Acta Metall 21 5 (1973) 571-574
43. Eshelby J. The determination of the elastic field of an ellipsoidal inclusion, and related problems. Proc R Soc Lond Ser A Math Phys Sci 241 (1957) 376-396
44. Kohlhauser C., Hellmich C., Vitale-Brovarone C., Boccaccini A.R., Rota A., and Eberhardsteiner J. Ultrasonic characterization of porous biomaterials across different frequencies. Strain (2008). Available from: www3.interscience.wiley.com 10.1111/j.1475-1305.2008.00417.x