Whole-body vibration in the skeleton: development of a resonance-based testing device

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Fritton, J. Chris¹; Rubin, Clinton T.¹; Qin, Yi-Xian¹; McLeod, Kenneth J.¹

Whole-body vibration in the skeleton: development of a resonance-based testing device

Ann Biomed Eng. September–October 1997;25(5):831-839

©1997 Biomedical Engineering Society

Affiliations

¹Musculo-Skeletal Research Laboratory, Department of Orthopaedics, SUNY at Stony Brook, Stony Brook
Abstract and keywords

Whole-body vibration (WBV) has been demonstrated to have a strong influence on physiological systems, ranging from severely destructive to potentially beneficial. Unfortutely, the study of WBV in a controlled manner is commonly constrained by space and budgetary factors, particularly where vibration in the low frequency range is considered. In the work presented here, a small, low-cost device for performing WBV of the human skeleton is developed to assist in studies of vertical acceleration in a clinical setting. The device design consists of a spring-supported plate driven by an 18N peak-force electromagnetic actuator, and the associated driving and monitoring electronics. Animal and human lumped-mass models have been coupled with a model of the loading device to seek a resonance response in the vicinity of 30Hz. This approach minimizes the loading requirements of such a device, and thus a major component of the cost, yet can provide peak accelerations of 0.15 g at a frequency of 30 Hz in a small, lightweight package capable of use in a clinical or laboratory setting.

Keywords: Mechanical amplification; Dynamic testing; Frequency response; Biomechanical model; Dynamic stiffness; Mechanical load; Osteoporosis; Strain; Biodynamics; Exogenous
Links

DOI: 10.1007/BF02684167

PubMed: 9300107

WoS: A1997XU86800009
History

Received: 1996-05-20

Revised: 1997-02-10

Accepted: 1997-02-20

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Cited By (17)

Year	Entry
2002	Rubin C, Turner AS, Mallinckrodt C, Jerome C, Mcleod K, Bain S. Mechanical strain, induced noninvasively in the high-frequency domain, is anabolic to cancellous bone, but not cortical bone. Bone. March 2002;30(3):445-452.
2001	Rubin C, Xu G, Judex S. The anabolic activity of bone tissue, suppressed by disuse, is normalized by brief exposure to extremely low‐magnitude mechanical stimuli. FASEB J. October 2001;15(12):2225-2229.
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.
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.
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.
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.
2008	Kiiski J, Heinonen A, Järvinen TL, Kannus P, Sievänen H. Transmission of vertical whole body vibration to the human body. J Bone Miner Res. August 2008;23(8):1318-1325.
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.
2021	Rajapakse CS, Johncola AJ, Batzdorf AS, Jones BC, Al Mukaddam M, Sexton K, Shults J, Leonard MB, Snyder PJ, Wehrli FW. Effect of low‐intensity vibration on bone strength, microstructure, and adiposity in pre‐osteoporotic postmenopausal women: a randomized placebo‐controlled trial. J Bone Miner Res. April 2021;36(4):673-684.
2022	Munford MJ, Xiao D, Jeffers JRT. Lattice implants that generate homeostatic and remodeling strains in bone. J Orthop Res. April 2022;40(4):871-877.
2001	Rubin C, Turner AS, Bain S, Mallinckrodt C, McLeod K. Low mechanical signals strengthen long bones. Nature. August 9, 2001;412(6847):603-604.
2003	Rubin CP, Pope M, Fritton C, Magnusson M, Hansson T, McLeod K. Transmissibility of 15-Hertz to 35-Hertz vibrations to the human hip and lumbar spine: determining the physiologic feasibility of delivering low-level anabolic mechanical stimuli to skeletal regions at greatest risk of fracture because of osteoporosis. Spine. December 1, 2003;28(23):2621-2627.
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.
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.
1999	Judex S. The Effect of Exercise-Induced Mechanical Stimuli on Cortical Bone [PhD thesis]. Calgary, AB: University of Calgary; 1999.
2004	LaMothe JM. Functional Adaptation of Bone [PhD thesis]. Calgary, AB: University of Calgary; September 2004.
2007	Christiansen BA. Vibrational Stimulation of Bone Formation in Mice [PhD thesis]. St. Louis, MO: Washington University in St. Louis; December 2007.