Isolated Cyclic Loading During Adolescence Improves Tibial Bone Microstructure and Strength at Adulthood

Mustafy, Tanvir; Londono, Irène; Moldovan, Florina; Villemure, Isabelle

doi:10.1002/jbm4.10349

Cited by 4 publications

(1 citation statement)

References 101 publications

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“…46 Similarly, increases in bone mineral density, bone volume fraction, trabecular bone thickness, trabecular number, and decreased trabecular spacing were observed after 1250 με at 2 Hz was applied in vivo to rat tibiae for eight weeks. 47 However, at a nonstress-normalized intermittent cyclic load of 17 N at 2 Hz applied for 10 min/day to adolescent rat ulnae, mineralization was arrested completely, and furthermore partially suppressed at 8.5 and 4 N loads applied in a similar manner. 18 One possibly contra-indicating study by Niehoff et al 20 reported that adolescent rats allowed unlimited exercise showed increased osteonectin in the hypertrophic zone relative to limited or no exercise groups, which correlates to promotion of ossification.…”

Section: Matrix Mineralizationmentioning

confidence: 90%

Part 2. Review and meta‐analysis of studies on modulation of longitudinal bone growth and growth plate activity: A micro‐scale perspective

D'Andrea

Alfraihat

Singh

et al. 2021

Journal Orthopaedic Research

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Macro-scale changes in longitudinal bone growth resulting from mechanical loading were shown in Part 1 of this review to depend on load magnitude, anatomical location, and species. While no significant effect on longitudinal growth was observed by varying frequency and amplitude of cyclic loading, such variations, in addition to loading duration and species, were shown to affect the morphology, viability, and gene and protein expression within the growth plate. Intermittent compression regimens were shown to preserve or increase growth plate height while stimulating increased chondrocyte presence in the hypertrophic zone relative to persistent and static loading regimens. Gene and protein expressions related to matrix synthesis and degradation, as well as regulation of chondrocyte apoptosis were shown to exhibit magnitude-, frequency-, and duration-dependent responses to loading regimen. Chondrocyte viability was shown to be largely preserved within physiological bounds of magnitude, frequency, amplitude, and duration. Persistent static loading was shown to be associated with overall growth plate height in tension only, reducing it in compression, while affecting growth plate zone heights differently across species and encouraging mineralization relative to intermittent cyclic loading. Lateral loading of the growth plate, as well as microfluidic approaches are relatively understudied, and age, anatomical location, and species effects within these approaches are undefined. Understanding the micro-scale effects of varied loading regimes can assist in the development of growth modulation methods and device designs optimized for growth plate viability preservation or mineralization stimulation based on patient age and anatomical location.

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Section: Matrix Mineralizationmentioning

confidence: 90%