Loading-related reorientation of bone proteoglycan in vivo:​ strain memory in bone tissue?

Skerry, T. M.; Bitensky, L.; Chayen, J.; Lanyon, L. E.

Affiliations

¹Department of Anatomy, Royal Veterinary College

²Division of Cellular Biology, Kennedy Institute of Rheumatology, London, England

Abstract and keywords

The load-carrying capacity of the skeleton is achieved and maintained as the result of a continued functional stimulus to the cell populations responsible for bone remodeling. Although some bone cells have been assumed to be influenced by the load-induced changes in strain throughout the matrix, no evidence is available to indicate which cells are susceptible to such strain change or how such transient events provide a sustained influence on cell behaviour. In the present study, we showed that a short period of dynamic loading in vivo affects the orientation of proteoglycan within bone tissue. This reorientation declines only slowly, thus providing a persistent record of the tissue's recent strain history. Such a record has the ability not only to “capture” strain transients but also to “update” and “average” them. In this way, the bone cells could be presented with a sustained and coherent stimulus directly related to dynamic strain transients. These transients are the tissue's principal function variable.

Keywords: Bone tissue; Proteoglycan; Bone strain; Dynamic loading

Links

DOI: 10.1002/jor.1100060411

PubMed: 3379508

WoS: A1988N883700010

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Cited By (23)

Year	Entry
1991	Lanyon LE. Biomechanical properties of bone and response of bone to mechanical stimuli: functional strain as a controlling influence on bone modeling and remodeling behavior. In: Hall BK, ed. Bone. Volume 3: Bone Matrix and Bone Specific Products. Boca Raton, FL: Inc., CRC Press; 1991:79-108.
2001	Knothe Tate ML. Bone poroelasticity. In: Cowin SC, ed. Bone Mechanics Handbook. 2nd ed. Boca Raton, FL: CRC Press; 2001:22-1–22-29.
2001	Goodship AE, Cunningham JL. Pathophysiology of functional adaptation of bone in remodeling and repair in vivo. In: Cowin SC, ed. Bone Mechanics Handbook. 2nd ed. Boca Raton, FL: CRC Press; 2001:26-1–26-31.
1994	Goodman SB. The effects of micromotion and particulate materials on tissue differentiation: bone chamber studies in rabbits. Acta Orthop Scand. 1994;65(suppl 258).
1993	Riggs CM, Lanyon LE, Boyde A. Functional associations between collagen fibre orientation and locomotor strain direction in cortical bone of the equine radius. Anat Embryol. March 1993;187(3):231-238.
1991	Bertram JEA, Swartz SM. The “law of bone transformation”: a case of crying Wolff? Biol Rev. August 1991;66(3):245-273.
1992	Lanyon LE. The success and failure of the adaptive response to functional load-bearing in averting bone fracture. Bone. 1992;13(2):S17-S21.
1989	Pead MJ, Lanyon LE. Indomethacin modulation of load-related stimulation of new bone formation in vivo. Calcif Tiss Int. January 1989;45(1):34-40.
1990	Skerry TM, Suswillo R, El Haj AJ, Ali NN, Dodds RA, Lanyon LE. Load-induced proteoglycan orientation in bone tissuein vivo and in vitro. Calcif Tiss Int. May 1990;46(5):318-326.
1994	Rubin CT, McLeod KJ. Promotion of bony ingrowth by frequency-specific, low-amplitude mechanical strain. Clin Orthop Relat Res. January 1994;298:165-174.
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1989	Skerry TM, Bitensky L, Chayen J, Lanyon LE. Early strain‐related changes in enzyme activity in osteocytes following bone loading in vivo. J Bone Miner Res. October 1989;4(5):783-788.
1990	El Haj AJ, Minter SL, Rawlinson SCF, Suswillo R, Lanyon LE. Cellular responses to mechanical loading in vitro. J Bone Miner Res. September 1990;5(9):923-932.
1992	Lanyon LE. Control of bone architecture by functional load bearing. J Bone Miner Res. December 1992;7(suppl 2):S369-S375.
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1994	Levenston ME. Simulation of Functional Adaptation in Trabecular and Cortical Bone [PhD thesis]. Stanford University; September 1994.
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