Vibrational loading can stimulate the formation of new trabecular bone or maintain bone mass. Studies investigating vibrational loading have often used whole-body vibration (WBV) as their loading method. However, WBV has limitations in small animal studies because transmissibility of vibration is dependent on posture. In this study, we propose constrained tibial vibration (CTV) as an experimental method for vibrational loading of mice under controlled conditions. In CTV, the lower leg of an anesthetized mouse is subjected to vertical vibrational loading while supporting a mass. The setup approximates a one degree-of-freedom vibrational system. Accelerometers were used to measure transmissibility of vibration through the lower leg in CTV at frequencies from . First, the frequency response of transmissibility was quantified in vivo, and dissections were performed to remove one component of the mouse leg (the knee joint, foot, or soft tissue) to investigate the contribution of each component to the frequency response of the intact leg. Next, a finite element (FE) model of a mouse tibia-fibula was used to estimate the deformation of the bone during CTV. Finally, strain gages were used to determine the dependence of bone strain on loading frequency. The in vivo mouse leg in the CTV system had a resonant frequency of for vibration ( peak to peak). Removing the foot caused the natural frequency of the system to shift from , removing the soft tissue caused no change in natural frequency, and removing the knee changed the natural frequency from . By using the FE model, maximum tensile and compressive strains during CTV were estimated to be on the cranial-medial and caudolateral surfaces of the tibia, respectively, and the peak transmissibility and peak cortical strain occurred at the same frequency. Strain gage data confirmed the relationship between peak transmissibility and peak bone strain indicated by the FE model, and showed that the maximum cyclic tibial strain during CTV of the intact leg was and occurred at . This study presents a comprehensive mechanical analysis of CTV, a loading method for studying vibrational loading under controlled conditions. This model will be used in future in vivo studies and will potentially become an important tool for understanding the response of bone to vibrational loading.
Skip Nav Destination
e-mail: bchrist1@bidmc.harvard.edu
Article navigation
August 2008
Technical Briefs
Constrained Tibial Vibration in Mice: A Method for Studying the Effects of Vibrational Loading of Bone
Blaine A. Christiansen,
Blaine A. Christiansen
Department of Orthopaedic Surgery, and Department of Biomedical Engineering,
e-mail: bchrist1@bidmc.harvard.edu
Washington University in St. Louis
, Campus Box 8233, St. Louis, MO 63110
Search for other works by this author on:
Philip V. Bayly,
Philip V. Bayly
Department of Mechanical Engineering,
Washington University in St. Louis
, Campus Box 8233, St. Louis, MO 63110
Search for other works by this author on:
Matthew J. Silva
Matthew J. Silva
Department of Orthopaedic Surgery, and Department of Biomedical Engineering,
Washington University in St. Louis
, Campus Box 8233, St. Louis, MO 63110
Search for other works by this author on:
Blaine A. Christiansen
Department of Orthopaedic Surgery, and Department of Biomedical Engineering,
Washington University in St. Louis
, Campus Box 8233, St. Louis, MO 63110e-mail: bchrist1@bidmc.harvard.edu
Philip V. Bayly
Department of Mechanical Engineering,
Washington University in St. Louis
, Campus Box 8233, St. Louis, MO 63110
Matthew J. Silva
Department of Orthopaedic Surgery, and Department of Biomedical Engineering,
Washington University in St. Louis
, Campus Box 8233, St. Louis, MO 63110J Biomech Eng. Aug 2008, 130(4): 044502 (6 pages)
Published Online: May 16, 2008
Article history
Received:
May 25, 2007
Revised:
March 10, 2008
Published:
May 16, 2008
Citation
Christiansen, B. A., Bayly, P. V., and Silva, M. J. (May 16, 2008). "Constrained Tibial Vibration in Mice: A Method for Studying the Effects of Vibrational Loading of Bone." ASME. J Biomech Eng. August 2008; 130(4): 044502. https://doi.org/10.1115/1.2917435
Download citation file:
Get Email Alerts
Simulating the Growth of TATA-Box Binding Protein-Associated Factor 15 Inclusions in Neuron Soma
J Biomech Eng (December 2024)
Effect of Structure and Wearing Modes on the Protective Performance of Industrial Safety Helmet
J Biomech Eng (December 2024)
Sex-Based Differences and Asymmetry in Hip Kinematics During Unilateral Extension From Deep Hip Flexion
J Biomech Eng (December 2024)
Related Articles
ANCF Finite Element/Multibody System Formulation of the Ligament/Bone Insertion Site Constraints
J. Comput. Nonlinear Dynam (July,2010)
Finite Element and Experimental Cortex Strains of the Intact and Implanted Tibia
J Biomech Eng (October,2007)
Comparison of the Linear Finite Element Prediction of Deformation and Strain of Human Cancellous Bone to 3D Digital Volume Correlation Measurements
J Biomech Eng (February,2006)
A Finite Element Model of the Human Knee Joint for the Study of Tibio-Femoral Contact
J Biomech Eng (June,2002)
Related Proceedings Papers
Related Chapters
Data Tabulations
Structural Shear Joints: Analyses, Properties and Design for Repeat Loading
Transverse Free Vibration Analysis of Hybrid SPR Steel Joints
Proceedings of the 2010 International Conference on Mechanical, Industrial, and Manufacturing Technologies (MIMT 2010)
Subsection NB—Class 1 Components
Companion Guide to the ASME Boiler & Pressure Vessel Codes, Volume 1 Sixth Edition