Homeostatic control of bone structure: an application of feedback theory

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Turner, Charles H.¹

Homeostatic control of bone structure: an application of feedback theory

Bone. 1991;12(3):203-217

©1991 Pergamon Press plc

Affiliations

¹Center For Hard Tissue Research, Creighton University, Omaha, NE 68178, U.S.A.
Abstract and keywords

The regulation of bone mass and structure in the weightbearing skeleton is governed to a great extent by the mechanical demands placed upon the bone tissue. The apparent biological goal is the maintenance of a minimum adequate structure, in which the margin of safety between normal mechanical demands and fracture is balanced by the cost of excessive bone mass on mobility. Frost has developed two powerful postulates concerning bone adaptation: (a) there exist threshold levels of mechanical strain, above or below which bone adaptation is turned on, and (b) the set point for normal bone structure can be modulated by hormones. A model was developed, using Frost's postulates and simple feedback theory, that describes the interaction between biochemical influences and mechanical influences on bone structure. The model predicts that biochemical agents that influence bone structure independently of the mechanical feedback system (e.g., calcitonin) are capable of only limited anabolic effects on bone mass because their influences conflict with mechanical influences. However, biochemical agents that influence bone structure by changing the set point of the mechanical feedback system (e.g., estrogen) will provide lasting changes in bone structure. Age-related changes occur within the effector and transduction components of the mechanical feedback system that tend to make it sluggish. These changes may lead to increased bone fragility because the system is no longer capable of maintaining adequate bone structure.

Keywords: Mechanical adaptation; Bone; Osteoporosis; Estrogen
Links

DOI: 10.1016/8756-3282(91)90043-I

PubMed: 1910962

WoS: A1991FT97700009
History

Received: 1990-09-24

Revised: 1990-11-14

Accepted: 1990-12-15

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1998	Turner CH. Three rules for bone adaptation to mechanical stimuli. Bone. November 1998;23(5):399-407.
1995	Duncan RL, Turner CH. Mechanotransduction and the functional response of bone to mechanical strain. Calcif Tiss Int. December 1995;57(5):344-358.
1995	Hung T Clark, Pollack R Solomon, Reilly TM, Brighton T Carl. Real-time calcium response of cultured bone cells to fluid flow. Clin Orthop Relat Res. April 1995;313:256-269.
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1997	Turner CH, Annet V, Pidaparti RMV. A uniform strain criterion for trabecular bone adaptation: do continuum-level strain gradients drive adaptation? J Biomech. June 1997;30(6):555-563.
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2020	Kemmler W, Kohl M, Fröhlich M, Jakob F, Engelke K, von Stengel S, Schoene D. Effects of high‐intensity resistance training on osteopenia and sarcopenia parameters in older men with osteosarcopenia: one‐year results of the randomized controlled Franconian Osteopenia and Sarcopenia Trial (FrOST). J Bone Miner Res. September 2020;35(9):1634-1644.
2021	Palumbo C, Ferretti M. The osteocyte: from “prisoner” to “orchestrator”. J Funct Morphol Kinesiol. 2021;6(1):28.
1998	Turner CH, Pavalko FM. Mechanotransduction and functional response of the skeleton to physical stress: the mechanisms and mechanics of bone adaptation. J Orthop Sci. November 1998;3(6):346-355.
2020	Della Corte A, Giorgio I, Scerrato D. A review of recent developments in mathematical modeling of bone remodeling. Proc Inst Mech Eng Part H-J Eng Med. March 2020;243(3):273-281.
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