The effect of step-wise increased stretching on rat calvarial osteoblast collagen production

Journal of Biomechanics

Volumn 37, Issue 1, 2004, Pages 157-161

  Tang, Li Ling ^a   Wang, Yuan Liang ^a   Pan, Jun ^a   Cai, Shao Xi ^a  

^a CHONGQING UNIVERSITY   (China)

Author keywords

Collagen synthesis; Osteoblast; The step wise increased stretching

Indexed keywords

BONE; CELLS; COLLAGEN; STRAIN; SYNTHESIS (CHEMICAL);

CYCLIC STRETCHING;

BIOMECHANICS;

COLLAGEN; PROLINE;

ANALYTIC METHOD; ANIMAL CELL; ANIMAL TISSUE; ARTICLE; BONE MATRIX; CALVARIA; CELL STRUCTURE; CELLULAR DISTRIBUTION; COLLAGEN SYNTHESIS; CONTROLLED STUDY; CYTOKINE RELEASE; LOADING TEST; MECHANICAL STRESS; NEWBORN; NONHUMAN; OSTEOBLAST; PRIORITY JOURNAL; RAT; SIGNAL TRANSDUCTION; STRAIN IDENTIFICATION; STRETCHING;

EID: 0346996700     PISSN: 00219290     EISSN: None     Source Type: Journal    
DOI: 10.1016/S0021-9290(03)00237-9     Document Type: Article

References (21)

1. Binderman I., Zor U., Kaye A.M., Shimshoni Z., Harell A., Somjen D. The transduction of mechanical force into biomechanical events in bone cells may involve activation of phospholipase A2. Calcified Tissue International. 42:1988;261-266.
2. Brighton C.T., Strafford B., Gross S.B., Leatherwood D.F., Williams J.L., Pollack S.R. The proliferative and synthetic response of isolated calvarial bone cells of rats to cyclic biaxial mechanical strain. Journal of Bone and Joint Surgery American. 73:1991;320-331.
3. Brighton C.T., Fisher J.R. Jr., Levine S.E., Corsetti J.R., Reilly T., Landsman A.S., Williams J.L., Thibault L.E. The biochemical pathway mediatiing the proliferative reponse of bone cells to a mechanical stimulus. Journal of Bone and Joint Surgery American. 78:1996;1337-1347.
4. Buckley M.J., Banes A.J., Jordan R.D. The effects of mechanical strain on osteoblasts in vitro. Journal of Oral and Maxillofacical Surgery. 48:1990;276-282.
5. Buckwalter J.A., Glimcher M.J., Cooper R.R., Recker R. Bone biology (II). formation, form, modeling, remodeling and regulation of cell function Instructional Course Lectures. 45:1996;387-399.
6. Burr D.B., Milgrom C., Fyhrie D., Forwood M., Nyska M., Finestone A., Hoshaw S., Saiag E., Simkin A. In vivo measurement of human tibal strains during vigorous activity. Bone. 18:1996;405-410.
7. Cowin S.C., Moss-Salentijn L., Moss M.L. Candidates for the mechanosensory system in bone. Journal of Biomechnical Engineering. 113:1991;191-197.
8. Harter L.V., Hruska K.A., Duncan R.L. Human osteoblast-like cells respond to mechanical strain with increased bone matrix protein production independent of hormonal regulation. Endocrinology. 136:1995;528-535.
9. Hasegawa S., Sato S., Saito S., Suzuki Y., Brunette D.M. Mechanical stretching increase the number of cultured bone cells synthesizing DNA and alters their pattern of protein synthesis. Calcified Tissue International. 37:1985;431-436.
10. Jones D.B., Nolte H., Scholubbers J.G., Turner E., Veltel D. Biochemical signal transduction of mechanical strain in osteoblast-like cells. Biomaterials. 12:1991;101-109.
11. Kaspar D., Seidl W., Neidlinger-Wilke C., Ignatius A., Claes L. Dynamic cell stretching increases human osteoblast proliferation and CICP synthesis but decreases osteocalcin synthesis and alkaline phosphatase activity. Journal of Biomechanics. 33:2000;45-51.
12. Meyer U., Terodde M., Joos U., Wiesmann H.P. Mechanical stimulation of osteoblasts in cell culture. Mund-, Kiefer-und Gesichtschirugie. 5:2001;166-172.
13. Peake M.A., Cooling L.M., Magnay J.L., Thomas P.B., El Haj A.J. Selected contribution. regulatory pathways involved in mechanical induction of c-fos gene expression in bone cells Journal of Applied Physiology. 89:2000;2498-2507.
14. Raab-Cullen D.M., Thiede M.A., Petersen D.N., Kimmel D.B., Recker R.R. Mechanical loading stimulates rapid changes in periosteal gene expression. Calcified Tissue International. 55:1994;473-478.
15. Reich K.M., Frangos J.A. Effects of flow on prostaglandin E2 and inositol triphosphate levels in osteoblasts. American Journal of Physiology. 261(3 Part 1):1991;c428-432.
16. Reich K.M., Gay C.V., Frangos J.A. Fluid shear stress as a mediator of osteoblast cyclic adnosine monophosphate production. Journal of Cell Physiology. 143:1990;100-104.
17. Robey P.G., Termine J.D. Human bone cells in vitro. Calcified Tissue International. 37:1985;453-460.
18. Rubin C.T., McLeod K.J. Promotion of bony ingrowth by frequency-specific, low amplitude mechanical strain. Clinica Orthopedica. 298:1994;165-174.
19. Skerry T.M., Bitensky L., Chayen J., Lanyon L.E. Early strain-related changes in enzyme activity in osteocytes following bone loading in vivo. Journal of Bone and Mineral Research. 4:1989;783-788.
20. Takashi U., Toshimasa U., Tetsuya T. Changes in cell proliferation, alkaline phosphatase activity and cAMP production by mechanical strain in osteoblast-like cells differentiated from rat bone marrow. Materials Science and Engineering C. 17:2001;51-53.
21. Zhang X.Z., Kuang Z.B., Cai S.X. The development of a cyclic four-point-bend loading device with uniaxial strain to cells. Medical Equipment Journal. 83:1999;6-8.