Transient-steady state phenomena in microdamage physiology: a proposed algorithm for lamellar bone

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Transient-steady state phenomena in microdamage physiology: a proposed algorithm for lamellar bone

Calcif Tiss Int. June 1989;44(6):367-381

©1989 Springer-Verlag New York Inc.

Affiliations

¹Southern Colorado Clinic, Department of Orthopaedic Surgery; Purdue University; A.A.O.S.; A.B.J.S., Pueblo, Colorado, USA
Abstract and keywords

This algorithm suggests that in steady states the momentary burden of unrepaired microdamage (MDx) in lamellar bone equals the rate of creation of new MDx multiplied by the time taken to repair a locus of MDx completely in the biomechanical sense. That “repair period” equals about 0.6 years in healthy human adults. When MDx production suddenly increases, the momentary MDx burden begins to increase too, and does so for a time equal to the repair period and in proportion to the increased MDx production. After the repair period elapses, the momentary MDx would tend to reach and stay at a maximum value as long as increased MDx production continued. Prolonging the repair period, preventing the creation of new remodeling units to repair MDx, or delaying mineralization of the new bone made by those units would also increase MDx burdens. Reducing MDx production or the repair period, or accelerating the creation of new modeling units would have the opposite effects on the momentary MDx burden but would also go through a transient phase before developing the new steady state conditions. Exploiting these relationships quantitatively and experimentally requires expressing them mathematically and using for the terms in any equations things one can define logically and measure practically. Accordingly, the article suggests a special definition of a unit amount of microdamage, how to measure it, and simple algebra and equations for calculating some effects of microdamage on the biologic system.

Keywords: Bone; Fatigue; Microdamage; Bone remodeling; Stress fracture
Links

DOI: 10.1007/BF02555964

PubMed: 2504449

WoS: A1989U644100001
History

Received: 1988-01-18

Revised: 1988-03-27

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Cited By (27)

Year	Entry
1990	Frost HM. Skeletal structural adaptations to mechanical usage (SATMU), II: redefining Wolff's Law: the remodeling problem. Anat Rec. April 1990;226(4):414-422.
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1992	Frost HM. Perspectives: bone's mechanical usage windows. Bone Miner. December 1992;19(3):257-271.
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2001	Li J, Mashiba T, Burr DB. Bisphosphonate treatment suppresses not only stochastic remodeling but also the targeted repair of microdamage. Calcif Tiss Int. November 2001;69(5):281-286.
1990	Burr DB, Stafford T. Validity of the bulk-staining technique to separate artifactual from in vivo bone microdamage. Clin Orthop Relat Res. November 1990;260:305-308.
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2009	Meardon SA. Skeletal Loading: Implications for Injury and Treatment [PhD thesis]. Iowa State University; 2009.
1998	Robling AG. Histomorphometric Assessment of Mechanical Loading History from Human Skeletal Remains: The Relation Between Micromorphology and Macromorphology At the Femoral Midshaft [PhD thesis]. University of Missouri; December 1998.
2001	Arthur Moore TL. Microdamage Accumulation in Bovine Trabecular Bone [PhD thesis]. Cambridge, MA: Massachusetts Institute of Technology; June 2001.
2011	Agnew AM. Histomorphometry of the Elderly Rib: A Methodological Approach With Implications for Biomechanics, Function, and Fracture Risk [PhD thesis]. The Ohio State University; 2011.
1991	Pattin CAG. Cyclic Mechanical Property Degradation in Bone During Fatigue Loading [PhD thesis]. Stanford University; March 1991.
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2019	Martig S. Compressive Fatigue Life and Micromorphology of Equine Metacarpal Subchondral Bone [PhD thesis]. University of Melbourne; June 2019.