REFERENCES
- BowmanSMKeavenyTMGibsonLJHayesWCMcmahonTA. 1994. Compressive creep behavior of bovine trabecular bone. J Biomech.76:2307–2316.
- CottonJRWinwoodKZiouposPTaylorM. 2005. Damage rate is a predictor of fatigue life and creep strain rate in tensile fatigue of human cortical bone samples. J Biomech Eng Trans ASME.127:213–219.
- Ertas AHSindeler BJCotton JR. 2011. Creep simulation of a micro-CT based finite element model of porcine cancellous bone. Paper Presented at Proceedings of the ASME Summer Bioengineering Conference (SBC 2011); June 22–25; Farmington (PA): ASME.
- ErtasAHWinwoodKZiouposPCottonJR. 2012. Simulation of creep in non-homogenous of human cortical bone. Comput Methods Biomech.15:1121–1128.
- Garcia-AznarJMRuebergTDoblareM. 2005. A bone remodelling model coupling microdamage growth and repair by 3D BMU-activity. Biomech Model Mechan Biol.4:147–167.
- GiesenEBWDingMDalastraMEijdenTMGJ. 2001. Mechanical properties of cancellous bone in the human mandibular condyle are anisotropic. J Biomech.34:799–803.
- PearceAIRichardsRGMilzSSchneiderEPearceSG. 2007. Animal models for implant biomaterial research in bone: a review. Eur Cells Mater.13:1–10.
- SindelarBJEdwardsSHerringSW. 2002. Morphologic changes in the TMJ following splint wear. Anat Rec.266:167–176.
- TaylorMTannerKE. 1997. Fatigue failure of cancellous bone: a possible cause of implant migration and loosening. J Bone Joint Surg Br.79B:181–182.
- TaylorSDTsiridisEInghamEJinZFisherJWilliamsS. 2012. Comparison of human and animal femoral head chondral properties and geometries. Proc Inst Mech Eng H.226:55–62.
- TengSHerringSW. 1996. Anatomic and directional variation in the mechanical properties of the mandibular condyle in pigs. J Dent Res.75:1842–1850.