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European Journal of Medical Research
Published in: European Journal of Medical Research 1/2018

Open Access 01-12-2018 | Research

Whole bone testing in small animals: systematic characterization of the mechanical properties of different rodent bones available for rat fracture models

Authors: Peter M. Prodinger, Peter Foehr, Dominik Bürklein, Oliver Bissinger, Hakan Pilge, Kilian Kreutzer, Rüdiger von Eisenhart-Rothe, Thomas Tischer

Published in: European Journal of Medical Research | Issue 1/2018

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Abstract

Objectives

Rat fracture models are extensively used to characterize normal and pathological bone healing. Despite, systematic research on inter- and intra-individual differences of common rat bones examined is surprisingly not available. Thus, we studied the biomechanical behaviour and radiological characteristics of the humerus, the tibia and the femur of the male Wistar rat—all of which are potentially available in the experimental situation—to identify useful or detrimental biomechanical properties of each bone and to facilitate sample size calculations.

Methods

40 paired femura, tibiae and humeri of male Wistar rats (10–38 weeks, weight between 240 and 720 g) were analysed by DXA, pQCT scan and three-point-bending. Bearing and loading bars of the biomechanical setup were adapted percentually to the bone’s length. Subgroups of light (skeletal immature) rats under 400 g (N = 11, 22 specimens of each bone) and heavy (mature) rats over 400 g (N = 9, 18 specimens of each bone) were formed and evaluated separately.

Results

Radiologically, neither significant differences between left and right bones, nor a specific side preference was evident. Mean side differences of the BMC were relatively small (1–3% measured by DXA and 2.5–5% by pQCT). Over all, bone mineral content (BMC) assessed by DXA and pQCT (TOT CNT, CORT CNT) showed high correlations between each other (BMC vs. TOT and CORT CNT: R2 = 0.94–0.99). The load–displacement diagram showed a typical, reproducible curve for each type of bone. Tibiae were the longest bones (mean 41.8 ± 4.12 mm) followed by femurs (mean 38.9 ± 4.12 mm) and humeri (mean 29.88 ± 3.33 mm). Failure loads and stiffness ranged from 175.4 ± 45.23 N / 315.6 ± 63.00 N/mm for the femurs, 124.6 ± 41.13 N / 260.5 ± 59.97 N/mm for the humeri to 117.1 ± 33.94 N / 143.8 ± 36.99 N/mm for the tibiae. Smallest interindividual differences were observed in failure loads of the femurs (CV% 8.6) and tibiae (CV% 10.7) of heavy animals, light animals showed good consistency in failure loads of the humeri (CV% 7.7). Most consistent results of both sides (left vs. right) in failure loads were provided by the femurs of light animals (mean difference 4.0 ± 2.8%); concerning stiffness, humeri of heavy animals were most consistent (mean difference of 6.2 ± 5%). In general, the failure loads showed strong correlations to the BMC (R2 = 0.85–0.88) whereas stiffness correlated only moderate, except for the humerus (BMC vs. stiffness: R2 = 0.79).

Discussion

Altogether, the rat’s femur of mature specimens showed the most accurate and consistent radiological and biomechanical results. In synopsis with the common experimental use enabling comparison among different studies, this bone offers ideal biomechanical conditions for three point bending experiments. This can be explained by the combination of a superior aspect ratio and a round and long, straight morphology, which satisfies the beam criteria more than other bones tested.
Appendix
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Literature
1.
Bissinger O, et al. A biomechanical, micro-computertomographic and histological analysis of the influence of diclofenac and prednisolone on fracture healing in vivo. BMC Musculoskelet Disord. 2016;17(1):383.CrossRefPubMedPubMedCentral
2.
Prodinger PM, et al. Does anticoagulant medication alter fracture-healing? A morphological and biomechanical evaluation of the possible effects of rivaroxaban and enoxaparin using a rat closed fracture model. PLoS ONE. 2016;11(7):e0159669.CrossRefPubMedPubMedCentral
3.
Sugiyama T, et al. Warfarin-induced impairment of cortical bone material quality and compensatory adaptation of cortical bone structure to mechanical stimuli. J Endocrinol. 2007;194(1):213–22.CrossRefPubMed
4.
5.
Leppanen OV, Sievanen H, Jarvinen TL. Biomechanical testing in experimental bone interventions—may the power be with you. J Biomech. 2008;41(8):1623–31.CrossRefPubMed
6.
Voide R, van Lenthe GH, Muller R. Bone morphometry strongly predicts cortical bone stiffness and strength, but not toughness, in inbred mouse models of high and low bone mass. J Bone Miner Res. 2008;23(8):1194–203.CrossRefPubMed
7.
Bagi CM, et al. The use of micro-CT to evaluate cortical bone geometry and strength in nude rats: correlation with mechanical testing, pQCT and DXA. Bone. 2006;38(1):136–44.CrossRefPubMed
8.
Jamsa T, et al. Comparison of three-point bending test and peripheral quantitative computed tomography analysis in the evaluation of the strength of mouse femur and tibia. Bone. 1998;23(2):155–61.CrossRefPubMed
9.
Jarvinen TL, et al. Dual-energy X-ray absorptiometry in predicting mechanical characteristics of rat femur. Bone. 1998;22(5):551–8.CrossRefPubMed
10.
11.
Jarvinen TL, et al. Revival of bone strength: the bottom line. J Bone Miner Res. 2005;20(5):717–20.CrossRefPubMed
12.
Jepsen KJ, et al. Establishing biomechanical mechanisms in mouse models: practical guidelines for systematically evaluating phenotypic changes in the diaphyses of long bones. J Bone Miner Res. 2015;30(6):951–66.CrossRefPubMedPubMedCentral
13.
Schriefer JL, et al. A comparison of mechanical properties derived from multiple skeletal sites in mice. J Biomech. 2005;38(3):467–75.CrossRefPubMed
14.
Turner CH, Burr DB. Basic biomechanical measurements of bone: a tutorial. Bone. 1993;14(4):595–608.CrossRefPubMed
15.
Eckstein F, et al. Insulin-like growth factor-binding protein-2 (IGFBP-2) overexpression negatively regulates bone size and mass, but not density, in the absence and presence of growth hormone/IGF-I excess in transgenic mice. Anat Embryol (Berl). 2002;206(1–2):139–48.CrossRef
16.
Schmidt C, et al. Precision and accuracy of peripheral quantitative computed tomography (pQCT) in the mouse skeleton compared with histology and microcomputed tomography (microCT). J Bone Miner Res. 2003;18(8):1486–96.CrossRefPubMed
17.
Chen L, et al. Biomechanical characteristics of osteoporotic fracture healing in ovariectomized rats: a systematic review. PLoS ONE. 2016;11(4):e0153120.CrossRefPubMedPubMedCentral
18.
Stuermer EK, et al. Estrogen and raloxifene improve metaphyseal fracture healing in the early phase of osteoporosis. A new fracture-healing model at the tibia in rat. Langenbecks Arch Surg. 2010;395(2):163–72.CrossRefPubMed
19.
Spatz HC, O’Leary EJ, Vincent JF. Young’s moduli and shear moduli in cortical bone. Proc Biol Sci. 1996;263(1368):287–94.CrossRefPubMed
20.
Meyers N, et al. Characterization of interfragmentary motion associated with common osteosynthesis devices for rat fracture healing studies. PLoS ONE. 2017;12(4):e0176735.CrossRefPubMedPubMedCentral
21.
Poser L, et al. A standardized critical size defect model in normal and osteoporotic rats to evaluate bone tissue engineered constructs. Biomed Res Int. 2014;2014:348635.CrossRefPubMedPubMedCentral
22.
Sun Y, et al. mir-21 overexpressing mesenchymal stem cells accelerate fracture healing in a rat closed femur fracture model. Biomed Res Int. 2015;2015:412327.PubMedPubMedCentral
23.
Frankle M, Borrelli J. The effects of testosterone propionate and methenolone enanthate on the healing of humeral osteotomies in the Wistar rat. J Investig Surg. 1990;3(2):93–113.CrossRef
24.
Rundle CH, et al. Direct lentiviral-cyclooxygenase 2 application to the tendon-bone interface promotes osteointegration and enhances return of the pull-out tensile strength of the tendon graft in a rat model of biceps tenodesis. PLoS ONE. 2014;9(5):e98004.CrossRefPubMedPubMedCentral
25.
Bonnarens F, Einhorn TA. Production of a standard closed fracture in laboratory animal bone. J Orthop Res. 1984;2(1):97–101.CrossRefPubMed
26.
Shefelbine SJ, et al. Intact fibula improves fracture healing in a rat tibia osteotomy model. J Orthop Res. 2005;23(2):489–93.CrossRefPubMed
27.
Histing T, et al. Small animal bone healing models: standards, tips, and pitfalls results of a consensus meeting. Bone. 2011;49(4):591–9.CrossRefPubMed
28.
Hung LK, et al. Low BMD is a risk factor for low-energy Colles’ fractures in women before and after menopause. Clin Orthop Relat Res. 2005;435:219–25.CrossRef
29.
Hudelmaier M, et al. Can geometry-based parameters from pQCT and material parameters from quantitative ultrasound (QUS) improve the prediction of radial bone strength over that by bone mass (DXA)? Osteoporos Int. 2004;15(5):375–81.CrossRefPubMed
30.
Fritton SP, McLeod KJ, Rubin CT. Quantifying the strain history of bone: spatial uniformity and self-similarity of low-magnitude strains. J Biomech. 2000;33(3):317–25.CrossRefPubMed
31.
Silva MJ, et al. Decreased collagen organization and content are associated with reduced strength of demineralized and intact bone in the SAMP6 mouse. J Bone Miner Res. 2006;21(1):78–88.CrossRefPubMed
32.
Leppanen O, et al. Three-point bending of rat femur in the mediolateral direction: introduction and validation of a novel biomechanical testing protocol. J Bone Miner Res. 2006;21(8):1231–7.CrossRefPubMed
33.
Smith LM, et al. Genetic perturbations that impair functional trait interactions lead to reduced bone strength and increased fragility in mice. Bone. 2014;67:130–8.CrossRefPubMedPubMedCentral
34.
Linde F, Sorensen HC. The effect of different storage methods on the mechanical properties of trabecular bone. J Biomech. 1993;26(10):1249–52.CrossRefPubMed
Metadata
Title
Whole bone testing in small animals: systematic characterization of the mechanical properties of different rodent bones available for rat fracture models
Authors
Peter M. Prodinger
Peter Foehr
Dominik Bürklein
Oliver Bissinger
Hakan Pilge
Kilian Kreutzer
Rüdiger von Eisenhart-Rothe
Thomas Tischer
Publication date
01-12-2018
Publisher
BioMed Central
Published in
European Journal of Medical Research / Issue 1/2018
Electronic ISSN: 2047-783X
DOI
https://doi.org/10.1186/s40001-018-0307-z

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