Abstract
Reliable and reproducible experimental methods for studying enhancement of osteoblast proliferation and metabolic activity in vitro provide invaluable tools for the research of biochemical processes involved in bone turnover in vivo. Some of the current methods used for this purpose are based on the ability of the osteoblasts to react metabolically to mechanical stimulation. These methods are based on the hypothesis that intracellular metabolic pathways could be influenced by the excitation of cytoskeletal components by mechanical cell deformation. Based on the same assumptions we developed a new experimental approach of biomechanical stimulation of cultured osteoblast-like cells by vibration. This method is based on the use of a specially designed vibration device that consists of an electric shaker with horizontally mounted well plate containing cell cultures. We used a first passage explant outgrowth of human osteoblast-like cell cultures, originating from samples of cancelous bone, collected from femoral necks of six donors during surgical arthroplasties of osteoarthritic hips. Well plates with replicates of cultured cells were exposed to a sine shaped vibration protocol in a frequency range of 20–60 Hz with displacement amplitude of 25 (±5) μm. We found that vibration at a distinct set of mechanical parameters of 20 Hz frequency and peak to peak acceleration of 0.5 ± 0.1 m/sec2 is optimal for cell proliferation, and at 60 Hz frequency with peak to peak acceleration of 1.3 ± 0.1 m/sec2 for metabolic activity. The presented easily reproducible experimental model should improve and simplify further research on the interactions between mechanical stimuli and intracellular biochemical pathways in osteoblasts.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Banes A.J., Link G.W., Gilbert J.W., Tran Son Tay R. and Monbuireau O. 1990. Culturing cells in a mechanically active environment. Am Biotech Lab 8: 12-22.
Bessey O.A., Lowry O.H. and Brock M.J. 1946. A method for the rapid determination of alkaline phosphatase with five cubic millimeters of serum. J Biol Chem 164: 321-329.
Boppart M.D., Kimmel D.B., Yee J.A. and Cullen D.M. 1998. Time course of osteoblast appearance after in vivo mechanical loading. Bone 23: 409-415.
Buckley M.J., Banes A.J., Levin L.G., Sumpio B.E., Sato M., Jordan R. et al. 1988. Osteoblasts increase their rate of division and align in response to cyclic, mechanical tension in vitro. Bone Min 4: 225-236.
Burger E.H. and Klein-Nulend J. 1998. Microgravity and bone cell mechanosensitivity. Bone 22: 127S-130S.
Duncan R.L. and Turner C.H. 1995. Mechanotransduction and functional response of bone to mechanical strain. Calcif Tissue Int 57: 344-358.
Gundle R., Stewart K., Screen J. and Beresford J.N. 1998. Isolation and culture of human bone-derived cells. In: Beresford N. and Owen M.E. (eds), Marrow Stromal Cell Culture. Cambridge university press, Cambridge, UK, pp. 43-66.
Jacobs C.R., Yellowley C.E., Davis B.R., Zhou Z., Cimbala J.M. and Donahue H.J. 1998. Differential effect of steady versus oscillating flow on bone cells. J Biomech 31: 969-976.
Jones D.B., Nolte H., Scholubbers J.G., Turner E. and Veltel D. 1991. Biochemical signal transduction of mechanical strain in osteoblast-like cells. Biomaterials 12: 101-110.
Khalil A.M. and Qassem W. 1996. A search for possible cytogenetic effects of low frequency vibrations in cultured human lymphocytes. Human Exp Toxicol 15: 504-507.
Labarca C. and Paigen K. 1980. A simple, rapid and sensitive DNA assay procedure. Analytical Biochem 102: 344-352.
Levy M., Joyner C., Simpson A.H., Kenwright J. and Francis M.J. 1999. Mechanical vibration stimulates adult human bone-derived cell proliferation in vitro. J Bone Joint Surgery 81B Supp 3: 328.
Liu C.C. and Kalu D.N. 1990. Human parathyroid hormone-(1-34) prevents bone loss and augments bone formation in sexually mature ovariectomized rats. J Bone Min Res 5: 973-982.
Neidlinger-Wilke C., Wilke H.J. and Claes L. 1994. Cyclic stretching of human osteoblasts affects proliferation and metabolism: A new experimental method and its application. J Orthop Res 12: 70-78.
Nigg B.M. 1998. Acceleration. In: Nigg B.M. and Herzog W. (eds), Biomechanics of the Musculo-Skeletal System, 2nd edn. John Wiley & Sons, Chichester, pp. 300-301.
Reich K.M., McAllister T.N., Gudi S. and Frangos J.A. 1997. Activation of G proteins mediates flow-induced prostaglandin E2 production in odsteoblasts. Endocrinology 138: 1014-1018.
Rubin C., Li C., Sun Y., Fritton C. and McLeod K. 1995. Non-invasive stimulation of trabecular bone formation via low magnitude, high frequency strain. Trans ORS 20: 548.
Smith E.L. and Gilligan C. 1996. Dose-Response relationship between physical loading and mechanical competence of bone. Bone 18: 45S-50S.
Soejima K., Klein-Nulend J., Semeins C.M. and Burger E.H. 1999. Calvarial and long bone cells derived from adult mice respond similarly to pulsating fluid flow with rapid nitric oxide production. Calcif Tissue Int 64: S113.
Stanford C.M., Morcuende J.A. and Brand R.A. 1995. Proliferative and phenotypic responses of bone-like cells to mechanical deformation. J Orth Res 13: 664-670.
Tjandrawinata R.R., Vincent V.L. and Hughes-Fulford M. 1997. Vibrational force alters m RNA expression in osteoblasts. FASEB 11: 493-497.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Rosenberg, N., Levy, M. & Francis, M. Experimental model for stimulation of cultured human osteoblast-like cells by high frequency vibration. Cytotechnology 39, 125–130 (2002). https://doi.org/10.1023/A:1023925230651
Issue Date:
DOI: https://doi.org/10.1023/A:1023925230651