Low-level mechanical vibrations can influence bone resorption and bone formation in the growing skeleton

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Xie, Liqin¹; Jacobson, Jeffrey M.¹; Choi, Edna S.¹; Busa, Bhavin¹; Donahue, Leah Rae²; Miller, Lisa M.³; Rubin, Clinton T.¹; Judex, Stefan¹

Low-level mechanical vibrations can influence bone resorption and bone formation in the growing skeleton

Bone. November 2006;39(5):1059-1066

©2006 Elsevier Inc. All rights reserved.

Affiliations

¹Department of Biomedical Engineering, Psychology A, 3rd Floor, State University of New York at Stony Brook, Stony Brook, NY 11794-2580, USA

²The Jackson Laboratory, Bar Harbor, ME 04609, USA

³National Synchrotron Light Source, Brookhaven National Laboratory, Upton, NY 11973-5000, USA
Abstract and keywords

Short durations of extremely small magnitude, high-frequency, mechanical stimuli can promote anabolic activity in the adult skeleton. Here, it is determined if such signals can influence trabecular and cortical formative and resorptive activity in the growing skeleton, if the newly formed bone is of high quality, and if the insertion of rest periods during the loading phase would enhance the efficacy of the mechanical regimen. Eight-week-old female BALB/cByJ mice were divided into four groups, baseline control (n = 8), age-matched control (n = 10), whole-body vibration (WBV) at 45 Hz (0.3 g) for 15 min day₋₁ (n = 10), and WBV that were interrupted every second by 10 of rest (WBV-R, n = 10). In vivo strain gaging of two additional mice indicated that the mechanical signal induced strain oscillations of approximately 10 microstrain on the periosteal surface of the proximal tibia. After 3 weeks of WBV, applied for 15 min each day, osteoclastic activity in the trabecular metaphysis and epiphysis of the tibia was 33% and 31% lower (P < 0.05) than in age-matched controls. Bone formation rates (BFR·BS₋₁) on the endocortical surface of the metaphysis were 30% greater (P< 0.05) in WBV than in age-matched control mice but trabecular and middiaphyseal BFR were not significantly altered. The insertion of rest periods (WBV-R) failed to potentiate the cellular effects. Three weeks of either WBV or WBV-R did not negatively influence body mass, bone length, or chemical bone matrix properties of the tibia. These data indicate that in the growing skeleton, short daily periods of extremely small, high-frequency mechanical signals can inhibit trabecular bone resorption, site specifically attenuate the declining levels of bone formation, and maintain a high level of matrix quality. If WBV prove to be efficacious in the growing human skeleton, they may be able to provide the basis for a non-pharmacological and safe means to increase peak bone mass and, ultimately, reduce the incidence of osteoporosis or stress fractures later in life.

Keywords: High-frequency mechanical stimuli; Peak bone mass; Bone quality; Mechanical strain
Links

DOI: 10.1016/j.bone.2006.05.012

PubMed: 16824816

WoS: 000241584500013
History

Received: 2006-02-10

Revised: 2006-05-09

Accepted: 2006-05-15

Online: 2006-07-07

Cited Works (13)

Year	Entry
2001	Robling AG, Duijvelaar KM, Geevers JV, Ohashi N, Turner CH. Modulation of appositional and longitudinal bone growth in the rat ulna by applied static and dynamic force. Bone. August 2001;29(2):105-113.
2004	Ward K, Alsop C, Caulton J, Rubin C, Adams J, Mughal Z. Low magnitude mechanical loading is osteogenic in children with disabling conditions. J Bone Miner Res. March 2004;19(3):360-369.
2003	Burr DB, Miller L, Grynpas M, Li J, Boyde A, Mashiba T, Hirano T, Johnston CC. Tissue mineralization is increased following 1-year treatment with high doses of bisphosphonates in dogs. Bone. December 2003;33(6):960-969.
1987	Matheson GO, Clement DB, Mckenzie DC, Taunton JE, Lloyd-Smith DR, Macintyre JG. Stress fractures in athletes: a study of 320 cases. Am J Sports Med. January–February 1987;15(1):46-58.
2002	Rubin C, Turner AS, Müller R, Mittra E, McLeod K, Lin W, Qin Y. Quantity and quality of trabecular bone in the femur are enhanced by a strongly anabolic, noninvasive mechanical intervention. J Bone Miner Res. February 2002;17(2):349-357.
2001	Paschalis EP, Verdelis K, Doty SB, Boskey AL, Mendelsohn R, Yamauchi M. Spectroscopic characterization of collagen cross‐links in bone. J Bone Miner Res. October 2001;16(10):1821-1828.
2004	Rubin C, Recker R, Cullen D, Ryaby J, McCabe J, McLeod K. Prevention of postmenopausal bone loss by a low‐magnitude, high‐frequency mechanical stimuli: a clinical trial assessing compliance, efficacy, and safety. J Bone Miner Res. March 2004;19(3):343-351.
1983	Bryant JD. The effect of impact on the marrow pressure of long bones in vitro. J Biomech. 1983;16(8):659-665.
1994	Turner CH, Forwood MR, Otter MW. Mechanotransduction in bone: do bone cells act as sensors of fluid flow? FASEB J. August 1994;8(11):875-878.
2000	Judex S, Zernicke RF. High-impact exercise and growing bone: relation between high strain rates and enhanced bone formation. J Appl Physiol. June 2000;88(6):2183-2191.
2002	Judex S, Donahue L, Rubin C. Genetic predisposition to low bone mass is paralleled by an enhanced sensitivity to signals anabolic to the skeleton. FASEB J. August 2002;16(10):1280-1282.
2004	Han Y, Cowin SC, Schaffler MB, Weinbaum S. Mechanotransduction and strain amplification in osteocyte cell processes. Proc Natl Acad Sci USA. November 23, 2004;101(47):16689-16694.
2003	Judex S, Boyd S, Qin Y-X, Turner S, Ye K, Müller R, Rubin C. Adaptations of trabecular bone to low magnitude vibrations result in more uniform stress and strain under load. Ann Biomed Eng. January 2003;31(1):12-20.

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2012	Webster D, Wirth A, van Lenthe GH, Müller R. Experimental and finite element analysis of the mouse caudal vertebrae loading model: prediction of cortical and trabecular bone adaptation. Biomech Model Mechanobiol. January 2012;11(1-2):221-230.
2010	Lau E, Al-Dujaili S, Guenther A, Liu D, Wang L, You L. Effect of low-magnitude, high-frequency vibration on osteocytes in the regulation of osteoclasts. Bone. June 2010;46(6):1508-1515.
2011	Lambers FM, Schulte FA, Kuhn G, Webster DJ, Müller R. Mouse tail vertebrae adapt to cyclic mechanical loading by increasing bone formation rate and decreasing bone resorption rate as shown by time-lapsed in vivo imaging of dynamic bone morphometry. Bone. December 2011;49(6):1340-1350.
2021	Pagnotti GM, Thompson WR, Guise TA, Rubin CT. Suppression of cancer-associated bone loss through dynamic mechanical loading. Bone. September 2021;150:115998.
2008	Webster DJ, Morley PL, van Lenthe GH, Müller R. A novel in vivo mouse model for mechanically stimulated bone adaptation: a combined experimental and computational validation study. Comput Methods Biomech Biomed Eng. October 2008;11(5):435-441.
2012	Thompson WR, Rubin CT, Rubin J. Mechanical regulation of signaling pathways in bone. Gene. July 25, 2012;503(2):179-193.
2010	Chen J-H, Liu C, You L, Simmons CA. Boning up on Wolff's Law: mechanical regulation of the cells that make and maintain bone. J Biomech. January 5, 2010;43(1):108-118.
2009	Boerckel JD, Dupont KM, Kolambkar YM, Lin ASP, Guldberg RE. In vivo model for evaluating the effects of mechanical stimulation on tissue-engineered bone repair. J Biomech Eng. August 2009;131(8):084502.
2009	Luu YK, Capilla E, Rosen CJ, Gilsanz V, Pessin JE, Judex S, Rubin CT. Mechanical stimulation of mesenchymal stem cell proliferation and differentiation promotes osteogenesis while preventing dietary-induced obesity. J Bone Miner Res. January 2009;24(1):50-61.
2007	Garman R, Gaudette G, Donahue L-R, Rubin C, Judex S. Low-level accelerations applied in the absence of weight bearing can enhance trabecular bone formation. J Orthop Res. June 2007;25(6):732-740.
2014	Fonseca H, Moreira-Gonçalves D, Coriolano H-JA, Duarte JA. Bone quality: the determinants of bone strength and fragility. Sports Med. January 2014;44(1):37-53.
2008	Webster DJ. A Combined Experimental and Computational Model for Genetic Control of Micro Structural Bone Adaptation [PhD thesis]. Swiss Federal Institute of Technology Zürich; 2008.
2011	Lambers FM. Functional Bone Imaging in an in Vivo Mouse Model of Bone Adaptation, Aging and Disease [PhD thesis]. Swiss Federal Institute of Technology Zürich; 2011.
2011	Boerckel JD. Mechanical Regulation of Bone Regeneration and Vascular Growth in Vivo [PhD thesis]. Atlanta, GA: Georgia Institute of Technology; August 2011.
2014	Ellman R. Skeletal Adaptation to Reduced Mechanical Loading [PhD thesis]. Cambridge, MA: Massachusetts Institute of Technology; September 2014.
2016	Metzger TA. Experimental and Computational Investigation of Bone Marrow Mechanobiology [PhD thesis]. University of Notre Dame; April 2016.
2015	Noble GJ. Evaluation of a Press Fit, Percutaneous, Skeletally Anchored Endoprosthesis for Prosthetic Limb Attachment: Bone Response and the Effect of Low Intensity Vibration [PhD thesis]. The Ohio State University; 2015.
2022	Kunath BA. Design and Validation of an Open-Source 3D Printable Bioreactor System for Ex Vivo Bone Culture [Master's thesis]. Queen's University; June 2022.
2006	Garman RA. Low-Level Accelerations Applied in the Absence of Weight Bearing Can Alter Cellular Activity and Tissue Morphology in the Skeleton [PhD thesis]. Stony Brook, NY: Stony Brook University; May 2006.
2006	Xie L. Low Level Mechanical Vibrations Enhance Musculoskeletal Accretion in Growing Mice [PhD thesis]. Stony Brook, NY: Stony Brook University; December 2006.
2008	Luu YK. Biomechanical Promotion of Mesenchymal Stem Cell Proliferation as a Countermeasure to the Development of Obesity and Osteoporosis [PhD thesis]. Stony Brook, NY: Stony Brook University; May 2008.
2009	Ferreri SL. Anti-Catabolic Role of Ultrasonic Mechanical Perturbation in Prevention of Bone Loss and Turnover in OVX Rat Model: A Combined Empirical, Nanomechanical and Micro-Numerical Simulation Approach [PhD thesis]. Stony Brook, NY: Stony Brook University; August 2009.
2009	Ozcivici E. Recovery of Trabecular Bone from Disuse Induced Deterioration in Cellular, Morphological and Biomechanical Properties [PhD thesis]. Stony Brook, NY: Stony Brook University; May 2009.
2010	Holguin N. Low-Level Vibrations Maintain the Intervertebral Disc During Unloading [PhD thesis]. Stony Brook, NY: Stony Brook University; December 2010.
2010	Jatkar A. Whole Body Vibration as a Treatment to Counter Bone Detriment and Obesity Caused by Poor Nutritional Intake [Master's thesis]. Stony Brook, NY: Stony Brook University; May 2010.
2012	Hu M. Mitigation of Bone Loss and Augment of Anabolic Adaptation by Physiological Dynamic Fluid Flow Stimulation [PhD thesis]. Stony Brook, NY: Stony Brook University; December 2012.
2012	Uzer G. Role of Fluid Shear Modulation on Bone Cell Metabolism During High-Frequency Oscillatory Vibrations [PhD thesis]. Stony Brook, NY: Stony Brook University; December 2012.
2015	Pongkitwitoon S. Mechanotransduction of Low Intensity Vibration in Human Bone Marrow Mesenchymal Stem Cells and Macrophages [PhD thesis]. Stony Brook, NY: Stony Brook University; May 2015.
2018	Patel VS. Harnessing Cell Mechanosensitivity to Combat Obesity-Induced Systemic Metabolic Disruptions and to Promote Protein Production for Bioprocessing [PhD thesis]. Stony Brook, NY: Stony Brook University; December 2018.
2010	Manske SL. Muscle Disuse and Vibration Effects on Bone Morphology [PhD thesis]. Calgary, AB: University of Calgary; December 2010.
2011	Coza A. Effects of Mechanical Vibrations and Compression on Muscle Contractile Properties and Physiology [PhD thesis]. Calgary, AB: University of Calgary; January 2011.
2013	Bhatia V. Loading Induced Bone Adaptation in the Distal Radius of Women: Influence of Mechanical Environment [PhD thesis]. University of Illinois at Chicago; 2013.
2007	Christiansen BA. Vibrational Stimulation of Bone Formation in Mice [PhD thesis]. St. Louis, MO: Washington University in St. Louis; December 2007.