Extracting accurate strain measurements in bone mechanics: a critical review of current methods

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Grassi, Lorenzo¹; Isaksson, Hanna¹

Extracting accurate strain measurements in bone mechanics: a critical review of current methods

J Mech Behav Biomed Mater. October 2015;50:43-54

©2015 Elsevier Ltd. All rights reserved.

Affiliations

¹Department of Biomedical Engineering, and Department of Orthopedics, Lund University, Lund, Sweden
Abstract and keywords

Osteoporosis related fractures are a social burden that advocates for more accurate fracture prediction methods. Mechanistic methods, e.g. finite element models, have been proposed as a tool to better predict bone mechanical behaviour and strength. However, there is little consensus about the optimal constitutive law to describe bone as a material. Extracting reliable and relevant strain data from experimental tests is of fundamental importance to better understand bone mechanical properties, and to validate numerical models.

Several techniques have been used to measure strain in experimental mechanics, with substantial differences in terms of accuracy, precision, time- and length-scale. Each technique presents upsides and downsides that must be carefully evaluated when designing the experiment. Moreover, additional complexities are often encountered when applying such strain measurement techniques to bone, due to its complex composite structure.

This review of literature examined the four most commonly adopted methods for strain measurements (strain gauges, fibre Bragg grating sensors, digital image correlation, and digital volume correlation), with a focus on studies with bone as a substrate material, at the organ and tissue level. For each of them the working principles, a summary of the main applications to bone mechanics at the organ- and tissue-level, and a list of pros and cons are provided.

Keywords: Strain; Femur; Validation; Strain gauges; Strain gages; Fibre Bragg grating; Digital image correlation; Digital volume correlation
Links

DOI: 10.1016/j.jmbbm.2015.06.006

PubMed: 26099201

WoS: 000361775000005
History

Received: 2015-01-08

Revised: 2015-06-01

Accepted: 2015-06-02

Online: 2015-06-11

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