Debye function analysis and 2D imaging of nanoscaled engineered bone

Biomaterials

Volumn 31, Issue 32, 2010, Pages 8289-8298

  Guagliardi, Antonietta ^a,b   Cedola, Alessia ^c   Giannini, Cinzia ^a   Ladisa, Massimo ^a   Cervellino, Antonio ^d   Sorrentino, Andrea ^c   Lagomarsino, Stefano ^c   Cancedda, Ranieri ^e   Mastrogiacomo, Maddalena ^e  

^a CNR   (Italy)

^b UNIVERSITY OF INSUBRIA   (Italy)

^c IFN CNR   (Italy)

^d PAUL SCHERRER INSTITUTE   (Switzerland)

^e UNIVERSITY OF GENOA   (Italy)

Author keywords

Bone tissue engineering; Crystallography; Hydroxyapatite; Microstructure; Molecular modelling; XRD (X ray diffraction)

Indexed keywords

2D IMAGING; AVERAGE DEGREE; AVERAGE SIZE; BIVARIATE; BONE REMODELLING; BONE TISSUE ENGINEERING; CANONICAL CORRELATION ANALYSIS; COLLAGEN I; CONTINUOUS DEPOSITION; DEBYE FUNCTION; GAP REGIONS; HIGH RESOLUTION; HYDROXYAPATITE NANOCRYSTALS; MINERAL COMPONENT; MOLECULAR MODELLING; NANO-SIZED; NANOSCALED; ORTHOTOPIC; RESORBABLE; SIGNAL MODELS; SIZE AND SHAPE; SIZE GRADIENT; TRI-CALCIUM PHOSPHATES; X RAY MICRODIFFRACTION; XRD;

APATITE; BIOMATERIALS; BONE; CRYSTAL STRUCTURE; CRYSTALS; DIFFRACTION PATTERNS; HOLOGRAPHIC INTERFEROMETRY; HYDROXYAPATITE; MICROSTRUCTURE; MINERALOGY; MOLECULAR MODELING; NANOCRYSTALS; SCAFFOLDS; SILICATE MINERALS; TISSUE ENGINEERING; X RAY CRYSTALLOGRAPHY; X RAY DIFFRACTION; X RAYS;

X RAY DIFFRACTION ANALYSIS;

ARTICLE; BONE GROWTH; CRYSTAL STRUCTURE; DEBYE FUNCTION ANALYSIS; IMAGING; MINERALIZATION; OSTEOBLAST; OSTEOCLAST; PRIORITY JOURNAL; TISSUE ENGINEERING; X RAY DIFFRACTION;

ANIMALS; BONE MARROW CELLS; BONE SUBSTITUTES; CELLS, CULTURED; CERAMICS; DURAPATITE; IMPLANTS, EXPERIMENTAL; MICE; MODELS, MOLECULAR; NANOPARTICLES; OSTEOGENESIS; POROSITY; SHEEP; STROMAL CELLS; TISSUE ENGINEERING; TISSUE SCAFFOLDS; X-RAY DIFFRACTION;

EID: 77956182122     PISSN: 01429612     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.biomaterials.2010.07.051     Document Type: Article

References (39)

1. Cho G., Wu Y., Ackerman J.L. Detection of hydroxyl ions in bone mineral by solid-state NMR spectroscopy. Science 2003, 300:1123-1127.
2. Pasteris J.D., Wopenka B., Freeman J.J., Rogers K., Valsami-Jones E., van der Houwen J.A.M., et al. Lack of OH in nanocrystalline apatite as a function of degree of atomic order: implications for bone and biomaterials. Biomaterials 2004, 25:229-238.
3. Leventouri Th Synthetic and biological hydroxyapatites: crystal structure questions. Biomaterials 2006, 27:3339-3342.
4. Ivanova T.I., Frank-Kamenetskaya O.V., Kol'tsov A.B., Ugolkov V.L. Crystal structure of calcium-deficient carbonated hydroxyapatite. Thermal decomposition. J Solid State Chem 2001, 160:340-349.
5. Rey C., Combes C., Drouet C., Glimcher M.J. Bone mineral: update on chemical composition and structure. Osteoporos Int 2009, 20:1013-1021.
6. Fratzl P., Gupta H.S., Paschalis E.P., Roschger P. Structural and mechanical quality of the collagen-mineral nanocomposite in bone. J Mater Chem 2004, 14:2115-2123.
7. Meneghini C., Dalconi M.C., Nuzzo S., Mobilio S., Wenk R.H. Rietveld refinement on X-ray diffraction patterns of bioapatite in human fetal bones. Biophys J 2003, 84:2021-2029.
8. Glas J.E., Omnell K.A. Size and shape of the apatite crystallites as deduced from X-ray diffraction data. J Ultrastruct Res 1960, 3:334-344.
9. Fratzl P., Schreiber S., Klaushofer K. Bone mineralization as studied by small-angle X-ray scattering. Connect Tissue Res 1996, 34:247-254.
10. Valenta A. Changes in bone quality due to disease and treatment: combined study of small-angle X-ray scattering (SAXS) and electron backscattering (qBEI). PhD Thesis:University of Leoben Austria.
11. Jiang H., Ramunno-Johnson D., Song C., Amirbekian B., Kohmura Y., Nishino Y., et al. Nanoscale imaging of mineral crystals inside biological composite materials using x-ray diffraction microscopy. Phys Rev Lett 2008, 100:038103.
12. Hartmann M.A., Fratzl P. Sacrificial ionic bonds need to be randomly distributed to provide shear deformability. Nano Lett 2009, 9:3603-3607.
13. LeGeros R.Z. Calcium phosphate-based osteoinductive materials. Chem Rev 2008, 108:4742-4753.
14. Palmer L.C., Newcomb C.J., Kaltz S.R., Spoerke E.D., Stupp S.I. Biomimetic systems for hydroxyapatite mineralization inspired by bone and enamel. Chem Rev 2008, 108:4754-4783.
15. Ohgushi H., Okumura M., Tamai S., Shors E.C., Caplan A.I. Marrow cell induced osteogenesis in porous hydroxyapatite and tricalcium phosphate: a comparative histomorphometric study of ectopic bone formation. J Biomed Mater Res 1990, 24:1563-1570.
16. Goshima J., Goldberg V.M., Caplan A.I. The osteogenic potential of culture-expanded rat marrow mesenchymal cells assayed in vivo in calcium phosphate ceramic blocks. Clin Orthop 1991, 262:298-311.
17. Quarto R., Mastrogiacomo M., Cancedda R., Kutepov S.M., Mukhachev V., Lavronkov A., et al. Repair of large bone defects with the use of autologous bone marrow stromal cells. N Engl J Med 2001, 344:385-386.
18. Muraglia A., Martin I., Cancedda R., Quarto R. A nude mouse model for human bone formation in unloaded conditions. Bone 1998, 22:131S-134S.
19. Derubeis AR, Muraglia A, Mastrogiacomo M, Quarto R, Cancedda R. Bone marrow stromal cells: from the bench to the clinic. Proceedings of the Sixth International Symposium on Tissue Engineering for Therapeutic Use. Suita, Osaka;2002, vol. 6. 25-31.
20. 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 2007, 28:1376-1384.
21. Guagliardi A., Giannini C., Ladisa M., Lamura A., Laudadio T., Cedola A., et al. Canonical correlation and quantitative phase analysis of microdiffraction patterns in bone-tissue engineering. J Appl Cryst 2007, 40:865-873.
22. Cancedda R., Cedola A., Giuliani A., Komlev V., 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 2007, 28:2505-2524.
23. Debye P. Zerstreuung von Röntgenstrahlen. Ann Phys 1915, 46:809-823.
24. Cervellino A., Giannini C., Guagliardi A. Determination of nanoparticle structure type, size and strain distribution from x-ray data for monatomic fcc-derived non-crystallographic nanoclusters. J Appl Cryst 2003, 36:1148-1158.
25. Cervellino A., Giannini C., Guagliardi A. Quantitative analysis of gold nanoparticle from synchrotron data by means of least-squares techniques. Eur Phys J B 2004, 41:485-493.
26. Cervellino A., Giannini C., Guagliardi A. On the efficient evaluation of Fourier patterns for nanoparticles and clusters. J Comput Chem 2006, 27:995-1008.
27. Hotelling H. Relation between two sets of variates. Biometrika 1936, 28:321-377.
28. Laudadio T., Pels P., De Lathauwer L., Van Hecke P., Van Huffel S. Tissue segmentation and classification of MRSI data using canonical correlation analysis. Magn Reson Med 2005, 54:1519-1529.
29. Ladisa M., Lamura A., Laudadio T. Canonical correlation analysis applied to crystallographic data. EURASIP J Adv Sign Proc 2007, 19260:127.
30. Marcacci M., Kon E., Zaffagnini S., Giardino R., Rocca M., Corsi A., et al. Reconstruction of extensive long bone defects in sheep using porous hydroxyapatite sponges. Calcif Tissue Int 1999, 64:83-90.
31. Kon E., Muraglia A., Corsi A., Bianco P., Marcacci M., Martin I., et al. Autologous bone marrow stromal cells loaded onto porous hydroxyapatite ceramic accelerate bone repair in critical defects of sheep long bones. J Biomed Mater Res 2000, 49:328-337.
32. Cervellino A., Guagliardi A. Turning the Debye function into an efficient total scattering method for nanocrystals. Diffraction at the nanoscale. nanocrystals, detective and amorphous materials 2010, 107-126. Insubria University Press, Varese, Italy. A. Guagliardi, N. Masciocchi (Eds.).
33. Kay M.I., Young R.A., Posner A.S. Crystal structure of hydroxyapatite. Nature 1964, 25:1050-1052.
34. Haverty D., Tofail S.A.M., Stanton T.K., McMonagle J.B. Structure and stability of hydroxyapatite: density functional calculation and Rietveld analysis. Phys Rev B 2005, 71:94103-94109.
35. Elliot J.C., Mackie P.E., Young R.A. Monoclinic hydroxyapatite. Science 1973, 180:1055-1057.
36. Sampson P.D., Siegel A.F. The measure of size independent of shape for multivariate lognormal populations. J Am Stat Assoc 1985, 80:910-914.
37. Cheng V.S. Bivariate lognormal distribution for characterizing asbestos fiber aerosols. Aerosol Sci Technol 1986, 5:359-368.
38. Paris O. From diffraction to imaging: new avenues in studying hierarchical biological tissues with x-ray microbeams. BioInterphases 2008, 3:FB16-FB26. Review.
39. Guagliardi A., Giannini C., Cedola A., Mastrogiacomo M., Ladisa M., Cancedda R. Toward the x-ray microdiffraction imaging of bone and tissue-engineered bone. Tissue Eng B 2009, 15:423-442.