Modulation of appositional and longitudinal bone growth in the rat ulna by applied static and dynamic force

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Robling, A. G.¹; Duijvelaar, K. M.²; Geevers, J. V.²; Ohashi, N.¹; Turner, C. H.³

Modulation of appositional and longitudinal bone growth in the rat ulna by applied static and dynamic force

Bone. August 2001;29(2):105-113

©2001 Elsevier Science Inc. All rights reserved.

Affiliations

¹Department of Anatomy and Cell Biology, Indiana University School of Medicine, Indianapolis, IN, USA

²Maastricht University School of Medicine, Maastricht, The Netherlands

³Department of Orthopedic Surgery and Biomechanics and Biomaterials Research Center, Indiana University School of Medicine, Indianapolis, IN, USA
Abstract and keywords

Appositional and longitudinal growth of long bones are influenced by mechanical stimuli. Using the noninvasive rat ulna loading model, we tested the hypothesis that brief-duration (10 min/day) static loads have an inhibitory effect on appositional bone formation in the middiaphysis of growing rat ulnae. Several reports have shown that ulnar loading, when applied to growing rats, results in suppressed longitudinal growth. We tested a second hypothesis that load-induced longitudinal growth suppression in the growing rat ulna is proportional to time-averaged load, and that growth plate dimensions and chondrocyte populations are reduced in the loaded limbs. Growing male rats were divided into one of three groups receiving daily 10 min bouts of static loading at 17 N, static loading at 8.5 N, or dynamic loading at 17 N. Periosteal bone formation rates, measured 3 mm distal to the ulnar midshaft, were suppressed significantly (by 28–41%) by the brief static loading sessions despite normal (dynamic) limb use between the daily loading bouts. Static loading neither suppressed nor enhanced endocortical bone formation. Dynamic loading increased osteogenesis significantly on both surfaces. At the end of the 2 week loading experiment, loaded ulnae were approximately 4% shorter than the contralateral controls in the 17 N static and dynamic groups, and approximately 2% shorter than the control side in the 8.5 N static group, suggesting that growth suppression was proportional to peak load magnitude, regardless of whether the load was static or dynamic. The suppressed growth in loaded limbs was associated with thicker distal growth plates, particularly in the hypertrophic zone, and a concurrent retention of hypertrophic cell lacunae. Negligible effects were observed in the proximal growth plate. The results demonstrate that, in growing animals, even short periods of static loading can significantly suppress appositional growth; that dynamic loads trigger the adaptive response in bone; and that longitudinal growth suppression resulting from compressive end-loads is proportional to load magnitude and not average load.

Keywords: Bone growth; Bone modeling; Growth plate; Static loading; Dynamic loading; Rat ulna; Histomorphometry
Links

DOI: 10.1016/S8756-3282(01)00488-4

PubMed: 11502470

WoS: 000170696700002
History

Received: 2000-08-4

Revised: 2001-03-14

Accepted: 2001-03-14

Cited Works (16)

Year	Entry
1987	Parfitt AM, Drezner MK, Glorieux FH, Kanis JA, Malluche H, Meunier PJ, Ott SM, Recker RR. Bone histomorphometry: standardization of nomenclature, symbols, and units: report of the ASBMR histomorphometry nomenclature committee. J Bone Miner Res. December 1987;2(6):595-610.
1984	Lanyon LE, Rubin CT. Static vs dynamic loads as an influence on bone remodelling. J Biomech. 1984;17(12):897-905.
1995	Turner CH, Owan I, Takano Y. Mechanotransduction in bone: role of strain rate. Am J Physiol Endocrinol Metab. September 1995;269(3):E438-E442.
1991	Turner CH, Akhter MP, Raab DM, Kimmel DB, Recker RR. A noninvasive, in vivo model for studying strain adaptive bone modeling. Bone. 1991;12(2):73-79.
1989	Martin RB, Burr DB. Structure, Function, and Adaptation of Compact Bone. New York, NY: Raven Press; 1989.
1971	Heřt J, Lišková M, Landa J. Reaction of bone to mechanical stimuli, I: continuous and intermittent loading of tibia in rabbit. Folia Morphol (Praha). August 1971;19(3):290-300.
1972	Chamay A, Tschantz P. Mechanical influences in bone remodeling: experimental research on Wolff's law. J Biomech. March 1972;5(2):173-180.
1996	Burr DB, Milgrom C, Fyhrie D, Forwood M, Nyska M, Finestone A, Hoshaw S, Saiag E, Simkin A. In vivo measurement of human tibial strains during vigorous activity. Bone. May 1996;18(5):405-410.
1984	Rubin CT, Lanyon LE. Regulation of bone formation by applied dynamic loads. J Bone Joint Surg. March 1984;66A(3):397-402.
1994	Torrance AG, Mosley JR, Suswillo RFL, Lanyon LE. Noninvasive loading of the rat ulna in vivo induces a strain-related modeling response uncomplicated by trauma or periostal pressure. Calcif Tiss Int. March 1994;54(3):241-247.
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.
1984	Meade JB, Cowin SC, Klawitter JJ, Van Buskirk WC, Skinner HB. Bone remodeling due to continuously applied loads. Calcif Tiss Int. March 1984;36(suppl 1):S25-S30.
1997	Mosley JR, March BM, Lynch J, Lanyon LE. Strain magnitude related changes in whole bone architecture in growing rats. Bone. March 1997;20(3):191-198.
1998	Mosley JR, Lanyon LE. Strain rate as a controlling influence on adaptive modeling in response to dynamic loading of the ulna in growing male rats. Bone. October 1998;23(4):313-318.
1999	Ajubi NE, Klein-Nulend J, Alblas MJ, Burger EH, Nijweide PJ. Signal transduction pathways involved in fluid flow-induced PGE₂ production by cultured osteocytes. Am J Physiol Endocrinol Metab. January 1999;276(1):E171-E178.
1990	Reich KM, Gay CV, Frangos JA. Fluid shear stress as a mediator of osteoblast cyclic adenosine monophosphate production. J Cell Physiol. April 1990;143(1):100-103.

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2006	Fritton JC. Mechanical Loading Induced Adaptation of the Mouse Tibia [PhD thesis]. Ithaca, NY: Cornell University; January 2006.
2004	Duty AO. Controlled in Vivo Mechanical Stimulation of Bone Repair Constructs [PhD thesis]. Atlanta, GA: Georgia Institute of Technology; April 2004.
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2006	Hannay G. Mechanical and Electrical Environments to Stimulate Bone Cell Development [PhD thesis]. Queensland University of Technology; August 2006.
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2006	Xie L. Low Level Mechanical Vibrations Enhance Musculoskeletal Accretion in Growing Mice [PhD thesis]. Stony Brook, NY: Stony Brook University; December 2006.
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