Krzysztof W. Luczynski, Tomasz Brynk, Barbara Ostrowska, Wojciech Swieszkowski, Roland Reihsner, Christian Hellmich


  1. [1] A. A. Abdel-Wahab, K. Alam, V. V. Silberschmidt,Analysis of anisotropic viscoelastoplastic properties ofcortical bone tissues, Journal of the Mechanical Behaviorof Biomedical Materials 4, 2011, 807-820.
  2. [2] I. Balac, P. S. Uskokovic, R. Aleksic, D. Uskokovic,Predictive Modeling of the Mechanical Properties ofParticulate Hydroxyapatite Reinforced PolymerComposites, Journal of Biomedical Materials Research63(6), 2002, 793-799.
  3. [3] J. M. Carcione, Wave Fields in Real Media: WavePropagation in Anisotropic, Anelastic and Porous Media(Pergamon, Oxford, UK, 2001).
  4. [4] M. Charles-Harris, S. del Valle, E. Hentges, P. Bleut,D. Lacroix, J. A. Planell, Mechanical and structuralcharacterisation of completly degradable polyacticacid/calcium phospate glass scaffolds, Biomaterials 28,2007, 4429-4438.
  5. [5] E. Charrière, S. Terrazzoni, C Pittet, Ph. Mordasini,M. Dutoit, J. Lemaître, Ph. Zysset, Mechanicalcharacterization of brushite and hydroxyapatite cements,Biomaterials 22, 2001, 2937-2945.
  6. [6] T.-M. G. Chu, D. G. Orton, S. J. Hollister, S. E.Feinberg, J. W. Halloran, Mechanical and in vivoperformance of hydroxyapatite implants with controlledarchitectures, Biomaterials 23, 2002, 1283-1293.
  7. [7] J. M. Cordell, M. L. Vogl, A. J. Wagoner Johnson,The influence of micropore size on the mechanicalproperties of bulk hydroxyapatite and hydroxyapatitescaffolds, Journal of the Mechanical Behavior ofBiomedical Materials 2, 2009, 560-570.
  8. [8] F. Despang, A. Bernhardt, A. Lode, Th. Hanke, D.Handtrack, B. Kieback. M. Gelinsky, Response of humanbone marrow stromal cells to a novel ultra-fine-grainedand dispersion-strengthend titanium-based material, ActaBiomaterialia 6, 2010, 1006-1013.
  9. [9] G. de With, H. J. A. van Dijk, N. Hattu, K. Prijs,Preparation, microstructure and mechanical properties ofdense polycrystalline hydroxyl apatite, Journal ofMaterials Science 16, 1981, 1592-1598
  10. [10] Y. C. Fung, P. Tong, Classical and Computationalsolid mechanics (Advanced Series in EngineeringScience) (World Scientific Publishing Co. Pte. Ltd.Singapore, 2001)
  11. [11] P. Janicki, G. Schmidmaier, What should be thecharacteristics of the ideal bone graft substitute?Combining scaffolds with growth factors and/or stemcells, Injury, doi:10.1016/j.injury.2011.06.014.
  12. [12] C. Kohlhauser, C. Hellmich, C. Vitale-Brovarone, A.R. Boccaccini, A. Rota, J. Eberhardsteiner, UltrasonicCharacterisation of Porous Biomaterials, Strain 45, 2009,34-44.
  13. [13] D. M. Liu, Preparation and characterization of poroushydroxyapatite bioceramic via a slip-casting route,Ceramics International 24, 1998, 441-446.
  14. [14] V. Maquet, A. R. Boccaccini, L. Pravata, I.Notingher, R. Jérôme, Porous poly(α-hydroxyacid)/Bioglass® composite scaffolds for bonetissue engineering. I: preparation and in vitrocharacterisation, Biomaterials 25, 2004, 4185-4194.
  15. [15] D. S. Metseger, M. R. Rieger, D. W. Foreman,Mechanical properties of sintered hydroxyapatite andtricalcium phosphate ceramic, Journal of MaterialsScience: Materials in Medicine 10, 1999, 9-17.
  16. [16] J. Salençon, Handbook of Continuum Mechanics(Springer, Germany, 2001)
  17. [17] J. Vuola, R. Taurio, H. Göransson, S. Asko-Seljavaara, Compresive strength of calcium carbonate andhydroxyapatite implants after bone-marrow-inducedosteogenesis, Biomaterials 19, 1998, 223-227.
  18. [18] W. Swieszkowski, B. H. Tuan, K. J. Kurzydlowski,D. W. Hutmacher, Repair and regeneration ofosteochondral defects in the articular joints, BiomolecularEngineering 24 (5), 2007, 489-495.
  19. [19] A. Zaoui, Continuum micromechanics: survey,Journal of Engineering Mechanics (ASCE), 128 (8), 2002,808–816.
  20. [20] L. Zhixia, M. Kawashita, Current progress ininorganic artificial biomaterials, The InternationalJournal of Artificial Organs, DOI 10.1007/s10047-011-0585-5.

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