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01-12-2015 | Original Article

Analysis of β-tricalcium phosphate granules prepared with different formulations by nano-computed tomography and scanning electron microscopy

Authors: Lisa Terranova, Hélène Libouban, Romain Mallet, Daniel Chappard

Published in: Journal of Artificial Organs | Issue 4/2015

Abstract

Among biomaterials used for filling bone defects, beta-tricalcium phosphate (β-TCP) is suitable in non-bearing bones, particularly in dental implantology, oral and maxillofacial surgery. When β-TCP granules are placed in a bone defect, they occupy the void 3D volume. Little is known about the 3D arrangement of the granules, which depends on the nature and size of the granules. The aim of this study was to examine the 3D architecture of porous β-TCP granules. Granules were prepared with different concentrations of β-TCP powder in slurry (10, 11, 15, 18, 21, and 25 g of β-TCP powder in distilled water). Granules were prepared by the polyurethane foam method. They were analyzed by nano-computed tomography (nanoCT) and compared with scanning electron microscopy (SEM). Commercial granules of hydroxyapatite-β-TCP prepared by the same methodology were also used. The outer and inner architectures of the granules were shown by nanoCT which evidenced macroporosity, internal porosity and microporosity between the sintered grains. Macroporosity was reduced at high concentration and conversely, numerous concave surfaces were observed. Internal porosity, related to the sublimation of the polyurethane foam, was present in all the granules. Microporosity at the grain joints was evidenced by SEM and on 2D nanoCT sections. Granules presented a heterogeneous aspect due to the different mineralization degree of the sintered powder grains in the β-TCP granules; the difference between hydroxyapatite and β-TCP was also evidenced. NanoCT is an interesting method to analyze the fine morphology of biomaterials with a resolution close to synchrotron and better than microcomputed tomography.

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Jensen OT, Shulman LB, Block MS, Iacono VJ. Report of the Sinus Consensus Conference of 1996. Int J Oral Maxillofac Implants. 1998;13:11–45.PubMed

Dorozhkin SV. Biphasic, triphasic and multiphasic calcium orthophosphates. Acta Biomater. 2012;8:963–77.CrossRefPubMed

Carrodeguas R, De Aza S. α-Tricalcium phosphate: synthesis, properties and biomedical applications. Acta Biomater. 2011;7:3536–46.CrossRefPubMed

Chazono M, Tanaka T, Komaki H, Fujii K. Bone formation and bioresorption after implantation of injectable beta-tricalcium phosphate granules-hyaluronate complex in rabbit bone defects. J Biomed Mater Res Part A. 2004;70:542–9.CrossRef

Lu J, Descamps M, Dejou J, Koubi G, Hardouin P, Lemaitre J, Proust JP. The biodegradation mechanism of calcium phosphate biomaterials in bone. J Biomed Mater Res. 2002;63:408–12.CrossRefPubMed

TenHuisen KS, Brown PW. Phase evolution during the formation of alpha-tricalcium phosphate. J Am Ceramic Soc. 1999;82:2813–8.CrossRef

Vallet-Regi M, Rodriguez-Lorenzo LM, Salinas AJ. Synthesis and characterisation of calcium deficient apatite. Solid State Ion. 1997;101:1279–85.CrossRef

Chappard D, Guillaume B, Mallet R, Pascaretti-Grizon F, Baslé MF, Libouban H. Sinus lift augmentation and beta-TCP: a microCT and histologic analysis on human bone biopsies. Micron. 2010;41:321–6.CrossRefPubMed

Suzuki O. Octacalcium phosphate (OCP)-based bone substitute materials. Jpn Dent Sci Rev. 2013;49:58–71.CrossRef

10.

Anderson JM, Cook G, Costerton B, Hanson SR, Hensten-Pettersen A, Jacobsen N, Johnson RJ, Mitchell RN, Pasmore M, Schoen FJ, Shirtliff MPS. Host response to biomaterials and their evaluation. In: Ratner BD, Schoen FJ, Lemons JE, editors. Biomaterials science: an introduction to materials in medicine 2nd Ed. San Diego: Elsevier; 2004. pp 293–300.

11.

Ndiaye M, Terranova L, Mallet R, Mabilleau G, Chappard D. Three-dimensional arrangement of beta-tricalcium phosphate granules evaluated by microcomputed tomography and fractal analysis. Acta Biomater. 2015;11:404–11.CrossRefPubMed

12.

Schwartzwalder K, Somers H, Somers AV. Inventors; 3090094 A, assignee. Method of making porous ceramics. US Patent 3 090 094. 1963.

13.

Filmon R, Retailleau-Gaborit N, Brossard G, Grizon-Pascaretti F, Baslé MF, Chappard D. Preparation of β-TCP granular material by polyurethane foam technology. Image Anal Stereol. 2009;28:1–10.CrossRef

14.

Nogueira LP, Braz D, Barroso RC, Oliveira LF, Pinheiro CJG, Dreossi D, Tromba G. 3D histomorphometric quantification of trabecular bones by computed microtomography using synchrotron radiation. Micron. 2010;41:990–6.CrossRefPubMed

15.

Ruegsegger P, Koller B, Muller R. A microtomographic system for the nondestructive evaluation of bone architecture. Calcif Tissue Int. 1996;58:24–9.CrossRefPubMed

16.

Sasov A, Van Dyck D. Desktop X-ray microscopy and microtomography. J Microsc. 1998;191:151–8.CrossRef

17.

Borah B, Gross GJ, Dufresne TE, Smith TS, Cockman MD, Chmielewski PA, Lundy MW, Hartke JR, Sod EW. Three-dimensional microimaging (MRmicroI and microCT), finite element modeling, and rapid prototyping provide unique insights into bone architecture in osteoporosis. Anat Rec. 2001;265:101–10.CrossRefPubMed

18.

Massai D, Pennella F, Gentile P, Gallo D, Ciardelli G, Bignardi C, Audenino A, Morbiducci U. Image-based three-dimensional analysis to characterize the texture of porous scaffolds. Bio Med Res Int. 2014; ID 161437.

19.

Schladitz K. Quantitative micro-CT. J Microsc. 2011;243:111–7.CrossRefPubMed

20.

Simon JL, Rekow ED, Thompson VP, Beam H, Ricci JL, Parsons JR. MicroCT analysis of hydroxyapatite bone repair scaffolds created via three-dimensional printing for evaluating the effects of scaffold architecture on bone ingrowth. J Biomed Mater Res Part A. 2008;85:371–7.CrossRef

21.

van Lenthe GH, Hagenmuller H, Bohner M, Hollister SJ, Meinel L, Muller R. Nondestructive micro-computed tomography for biological imaging and quantification of scaffold-bone interaction in vivo. Biomaterials. 2007;28:2479–90.CrossRefPubMed

22.

Klein M, Goetz H, Pazen S, Al-Nawas B, Wagner W, Duschner H. Pore characteristics of bone substitute materials assessed by microcomputed tomography. Clin Oral Implants Res. 2009;20:67–74.CrossRefPubMed

23.

Wilkins S, Gureyev T, Gao D, Pogany A, Stevenson A. Phase-contrast imaging using polychromatic hard X-rays. Nature. 1996;384:335–8.CrossRef

24.

Kerckhofs G, Sainz J, Wevers M, Van de Putte T, Schrooten J. Contrast-enhanced nanofocus computed tomography images the cartilage subtissue architecture in three dimensions. Eur Cell Mater. 2013;25:179–89.PubMed

25.

Naveh GR, Brumfeld V, Shahar R, Weiner S. Tooth periodontal ligament: direct 3D microCT visualization of the collagen network and how the network changes when the tooth is loaded. J Struct Biol. 2013;181:108–15.CrossRefPubMed

26.

Pascaretti-Grizon F, Libouban H, Camprasse G, Camprasse S, Mallet R, Chappard D. The interface between nacre and bone after implantation in the sheep: a nanotomographic and Raman study. J Raman Spectrosc. 2014;45:558–64.CrossRef

27.

Weiss P, Obadia L, Magne D, Bourges X, Rau C, Weitkamp T, Khairoun I, Bouler JM, Chappard D, Gauthier O, Daculsi G. Synchrotron X-ray microtomography (on a micron scale) provides three-dimensional imaging representation of bone ingrowth in calcium phosphate biomaterials. Biomaterials. 2003;24:4591–601.CrossRefPubMed

28.

Sullivan RM, Ghosn LJ, Lerch BA. A general tetrakaidecahedron model for open-celled foams. Int J Solids Struct. 2008;45:1754–65.CrossRef

29.

Richardson J, Peng Y, Remue D. Properties of ceramic foam catalyst supports: pressure drop. Appl Catal A Gen. 2000;204:19–32.CrossRef

30.

Gibson LJ, Ashby MF. Cellular solids: structure and properties. Cambridge: Cambridge University Press; 1999.

31.

Borah B, Ritman EL, Dufresne TE, Jorgensen SM, Liu S, Sacha J, Phipps RJ, Turner RT. The effect of risedronate on bone mineralization as measured by micro-computed tomography with synchrotron radiation: correlation to histomorphometric indices of turnover. Bone. 2005;37:1–9.CrossRefPubMed

32.

Roschger P, Fratzl P, Eschberger J, Klaushofer K. Validation of quantitative backscattered electron imaging for the measurement of mineral density distribution in human bone biopsies. Bone. 1998;23:319–26.CrossRefPubMed

33.

Fellah BH, Gauthier O, Weiss P, Chappard D, Layrolle P. Comparison of osteoinduction by autologous bone and biphasic calcium phosphate ceramic in goats. Key Engen Mater. 2007;330:1063–6.CrossRef

Title: Analysis of β-tricalcium phosphate granules prepared with different formulations by nano-computed tomography and scanning electron microscopy
Authors: Lisa Terranova
Hélène Libouban
Romain Mallet
Daniel Chappard
Publication date: 01-12-2015
Publisher: Springer Japan
Published in: Journal of Artificial Organs / Issue 4/2015
Print ISSN: 1434-7229
Electronic ISSN: 1619-0904
DOI: https://doi.org/10.1007/s10047-015-0838-9

At a glance: The STEP trials

Springer Medicine

Analysis of β-tricalcium phosphate granules prepared with different formulations by nano-computed tomography and scanning electron microscopy

Abstract

At a glance: The STEP trials

Springer Medicine

Abstract

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