Synchrotron radiation micro-CT at the micrometer scale for the analysis of the three-dimensional morphology of microcracks in human trabecular bone

Larrue, Aymeric<sup>1,2</sup>; Rattner, Aline<sup>3</sup>; Peter, Zsolt-Andrei<sup>1,4</sup>; Olivier, Cécile<sup>1,2</sup>; Laroche, Norbert<sup>3</sup>; Vico, Laurence<sup>3</sup>; Peyrin, Françoise<sup>1,2</sup>

Affiliations

¹CREATIS, Inserm U1044, CNRS 5220, INSA Lyon, Université Lyon I, Université de Lyon, Villeurbanne, France

²ESRF, Grenoble, France

³LBTO, Inserm U890, IFR143, IFRESIS, Université de Lyon, St Etienne, France

⁴Université Paris 10 – Ouest Nanterre La Défense, PST/IUT de Ville d'Avray, Département GTE, Ville d'Avray, France

Abstract

Bone quality is an important concept to explain bone fragility in addition to bone mass. Among bone quality factors, microdamage which appears in daily life is thought to have a marked impact on bone strength and plays a major role in the repair process. The starting point for all studies designed to further our understanding of how bone microdamage initiate or dissipate energy, or to investigate the impact of age, gender or disease, remains reliable observation and measurement of microdamage. In this study, 3D Synchrotron Radiation (SR) micro-CT at the micrometric scale was coupled to image analysis for the three-dimensional characterization of bone microdamage in human trabecular bone specimens taken from femoral heads. Specimens were imaged by 3D SR micro-CT with a voxel size of 1.4 µm. A new tailored 3D image analysis technique was developed to segment and quantify microcracks. Microcracks from human trabecular bone were observed in different tomographic sections as well as from 3D renderings. New 3D quantitative measurements on the microcrack density and morphology are reported on five specimens. The 3D microcrack density was found between 3.1 and 9.4/mm3 corresponding to a 2D density between 0.55 and 0.76 /mm2. The microcrack length and width measured in 3D on five selected microcrack ranged respectively from 164 µm to 209 µm and 100 µm to 120 µm. This is the first time that various microcracks in unloaded human trabecular bone - from the simplest linear crack to more complex cross-hatch cracks - have been examined and quantified by 3D imaging at this scale. The suspected complex morphology of microcracks is here considerably more evident than in the 2D observations. In conclusion, this technique opens new perspective for the 3D investigation of microcracks and the impact of age, disease or treatment.

Links

DOI: 10.1371/journal.pone.0021297

PubMed: 21750707

PubMedCentral: PMC3131277

WoS: 000292655400003

History

Received: 2010-11-03

Accepted: 2011-05-26

Published: 2011-07-07

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