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Abstract

The aim of this work was to introduce high-resolution computed tomography (micro-CT) for scaffolds made from soft natural biomaterials, and to compare these data with the conventional techniques scanning electron microscopy and light microscopy. Collagen-based scaffolds were used as examples. Unlike mineralized tissues, collagen scaffolds do not provide enough X-ray attenuation for micro-CT imaging. Therefore, various metal-based contrast agents were applied and evaluated using two structurally distinct scaffolds, one with round pores and one with unidirectional lamellae. The optimal contrast techniques for obtaining high-resolution three-dimensional images were either a combination of osmium tetroxide and uranyl acetate, or a combination of uranyl acetate and lead citrate. The data obtained by micro-CT analysis were in line with data obtained by light and electron microscopy. However, small structures (less than a few μm) could not be visualized due to limitation of the spot size of the micro-CT apparatus. In conclusion, reliable three-dimensional images of scaffolds prepared from soft natural biomaterials can be obtained using appropriate contrast protocols. This extends the use of micro-CT analysis to soft materials, such as protein-based biomaterials.

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References

Guldberg

R.B.

Tissue engineering: micro-CT imaging. Sci Med, 9:9. 2003.

Feldkamp

L.A.

, Goldstein

S.A.

, Parfitt

A.M.

, Jesion

, Kleerekoper

The direct examination of three-dimensional bone architecture in vitro by computed tomography. J Bone Miner Res, 4:311. 1989.

Muller

, Hildebrand

, Ruegsegger

Non-invasive bone biopsy: a new method to analyse and display the three-dimensional structure of trabecular bone. Phys Med Biol, 39:145. 1994.

Ruegsegger

, Koller

, Muller

A microtomographic system for the nondestructive evaluation of bone architecture. Calcif Tissue Int, 58:24. 1996.

Goulet

R.W.

, Goldstein

S.A.

, Ciarelli

L, Brown

M.B.

, Feldkamp

L.A.

The relationship between the structural and orthogonal compressive properties of trabecular bone. J Biomech, 27:375. 1994.

S.T.

, Hutmacher

D.W.

A comparison of micro-CT with other techniques used in the characterization of scaffolds. Biomaterials, 27:1362. 2006.

Lin

A.S.P.

, Barrows

T.H.

, Cartmell

S.H.

, Guldberg

R.E.

Microarchitectural and mechanical characterization of oriented porous polymer scaffolds. Biomaterials, 24:481. 2003.

Lin-Gibson

, Copper

J.A.

, Landis

F.A.

, Cicerone

M.T.

Systematic investigation of porogen size and content on scaffold morphometric parameters and properties. Biomacromolecules, 8:1511. 2007.

Peyrin

, Mastrogiacomo

, Cancedda

SEM and 3-D synchrotron radiation. Micro-tomography in the study of bioceramic scaffolds for tissue-engineering applications. Biotechnol Bioeng, 9:638. 2007.

10.

Wang

, Shor

, Darling

, Khalil

, Sun

, Guceri

, Lau

Precision extruding deposition and characterization of cellular poly-ɛ-lactone tissue scaffolds. Rapid Prototyping J, 10:42. 2004.

11.

Faraj

K.A.

, van Kuppevelt

T.H.

, Daamen

W.F.

Construction of collagen scaffolds that mimic the three-dimensional architecture of specific tissues. Tissue Eng, 13:2387. 2007.

12.

Schoof

, Apel

, Heschel

, Rau

Control of pore structure and size in freeze-dried collagen sponges. J Biomed Mater Res, 58:352. 2001.

13.

Ann Ellis

Poststaining grids for transmission electron microscopy conventional and alternative protocols. Methods Mol Biol, 369:97. 2007.

14.

Kelly

R.O.

, Dekker

R.A.

, Bleumink

Ligand-mediated osmium binding: its application in coating biological specimens for scanning electron microscopy. J Utrastruct Res, 45:254. 1973.

15.

Seligman

A.M.

, Wasserkrug

H.L.

, Hanker

J.S.

A new staining method (OTO) for enhancing contrast in lipid-containing membranes and droplets in osmium tetraoxide-fixed tissue with osmiophilic thiocarbohydrazide (TCH)

J Cell Biol, 30:424. 1996.

16.

Inanc

, Elcin

A.E.

, Elcin

Y.M.

Osteogenic induction of human periodontal ligament fibroblasts under two- and three-dimensional culture conditions. Tissue Eng, 12:257. 2006.

17.

Sun

, Jackson

, Haycock

J.W.

, MacNeil

Culture of skin in 3-D rather than 2D improves their ability to survive exposure to cytotoxic agents. J Biotechnol, 122:372. 2006.

18.

Stegemann

J.P.

, Nerem

R.M.

Altered response of vascular smooth muscle cells to exogenous biochemical stimulation in two- and three-dimensional culture. Exp Cell Res, 283:146. 2003.

19.

Cukierman

, Pankov

, Stevens

D.R.

, Yamada

K.M.

Taking cell-matrix adhesions to the third dimension. Science, 294:1708. 2001.

20.

Ritman

E.L.

Micro-computed tomography-current status and developments. Annu Rev Biomed Eng, 6:185. 2004.

21.

van Oosterwyck

, van Der Sloten

, van Der Perre

, Jansen

, Wevers

, Naert

Use of microfocus computerized tomography as a new technique for characterizing bone tissue around oral implants. J Oral Implantol, 26:5. 2000.

22.

Gauthier

, Muller

, Von Stechow

, Lamy

, Weiss

, Bouler

J.M.

, Aguado

, Daculsi

In vivo bone regeneration with injectable calcium phosphate biomaterial: a three-dimensional micro-computed tomographic, biomechanical and SEM study. Biomaterials, 26:5444. 2005.

23.

Cartmell

, Huynh

, Nagaraja

, Guldberg

Quantitative microcomputed tomography analysis of mineralization within three-dimensional scaffolds in vitro. J Biomed Mater Res A, 69:97. 2004.

24.

Buttafoco

, Engbers-Buijtenhuijs

Poot., A.A., Dijkstra

P.J.

, Vermes

, Feijen

Physical characterization of vascular grafts cultured in a bioreactor. Biomaterials, 11:2380. 2006.

25.

Cnudde

, Masschaele

, Dierick

, Vlassenbroeck

, van Hoorebeke

, Jacobs

Recent progress in X-ray CT as a geosciences tool. Appl Geochem, 21:826. 2006.

26.

Duvall

C.L.

, Taylor

W.R.

, Weiss

, Guldberg

R.E.

Quantitative microcomputed tomography analysis of collateral vessel development after ischemic injury. Am J Physiol Heart Circ Physiol, 287:H302. 2004.

27.

Bonse

, Busch

X-ray computed microtomography (microCT) using synchrotron (SR)

Prog Biophys Mol Biol, 65:133. 1996.

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Micro-Computed Tomographical Imaging of Soft Biological Materials Using Contrast Techniques

Abstract

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Supplementary Material