Do regional modifications in tissue mineral content and microscopic mineralization heterogeneity adapt trabecular bone tracts for habitual bending? Analysis in the context of trabecular architecture of deer calcanei

Do regional modifications in tissue mineral content and microscopic mineralization heterogeneity adapt trabecular bone tracts for habitual bending? Analysis in the context of trabecular architecture of deer calcanei

Calcanei of mature mule deer have the largest mineral content (percent ash) difference between their dorsal ‘compression’ and plantar ‘tension’ cortices of any bone that has been studied. The opposing trabecular tracts, which are contiguous with the cortices, might also show important mineral conten...

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Veröffentlicht in:Journal of anatomy 2012-03, Vol.220 (3), p.242-255
Hauptverfasser: Skedros, John G., Knight, Alex N., Farnsworth, Ryan W., Bloebaum, Roy D.
Format: Artikel
Sprache:eng
Schlagworte:
Adaptability
Animals
Architecture
artiodactyl calcaneus
Biomechanical Phenomena
Bone (trabecular)
bone adaptation
Bone Density - physiology
Bone imaging
bone mineral content
bone mineralization
Bone Remodeling - physiology
Bones
Calcaneus - anatomy & histology
Calcaneus - physiology
Calcaneus - ultrastructure
Calcification, Physiologic - physiology
cancellous bone
Compression
Computed tomography
Data processing
Deer
deer calcaneus
Honeycombs
Male
Mechanical properties
Mineralization
Original
phenotypic plasticity
strain
trabecular bone
X-Ray Microtomography
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Zusammenfassung:Calcanei of mature mule deer have the largest mineral content (percent ash) difference between their dorsal ‘compression’ and plantar ‘tension’ cortices of any bone that has been studied. The opposing trabecular tracts, which are contiguous with the cortices, might also show important mineral content differences and microscopic mineralization heterogeneity (reflecting increased hemi‐osteonal renewal) that optimize mechanical behaviors in tension vs. compression. Support for these hypotheses could reveal a largely unrecognized capacity for phenotypic plasticity – the adaptability of trabecular bone material as a means for differentially enhancing mechanical properties for local strain environments produced by habitual bending. Fifteen skeletally mature and 15 immature deer calcanei were cut transversely into two segments (40% and 50% shaft length), and cores were removed to determine mineral (ash) content from ‘tension’ and ‘compression’ trabecular tracts and their adjacent cortices. Seven bones/group were analyzed for differences between tracts in: first, microscopic trabecular bone packets and mineralization heterogeneity (backscattered electron imaging, BSE); and second, trabecular architecture (micro‐computed tomography). Among the eight architectural characteristics evaluated [including bone volume fraction (BVF) and structural model index (SMI)]: first, only the ‘tension’ tract of immature bones showed significantly greater BVF and more negative SMI (i.e. increased honeycomb morphology) than the ‘compression’ tract of immature bones; and second, the ‘compression’ tracts of both groups showed significantly greater structural order/alignment than the corresponding ‘tension’ tracts. Although mineralization heterogeneity differed between the tracts in only the immature group, in both groups the mineral content derived from BSE images was significantly greater (P 
ISSN:0021-8782
1469-7580
DOI:10.1111/j.1469-7580.2011.01470.x