Vertebral Fragility and Structural Redundancy

Overview

Journal J Bone Miner Res

Publisher Oxford University Press

Date 2012 May 25

PMID 22623120

Citations 14

Authors

Aaron J Fields

Shashank Nawathe

Senthil K Eswaran

Michael G Jekir

Mark F Adams

Panayiotis Papadopoulos

Tony M Keaveny

Affiliations

Soon will be listed here.

Abstract

The mechanisms of age-related vertebral fragility remain unclear, but may be related to the degree of "structural redundancy" of the vertebra; ie, its ability to safely redistribute stress internally after local trabecular failure from an isolated mechanical overload. To better understand this issue, we performed biomechanical testing and nonlinear micro-CT-based finite element analysis on 12 elderly human thoracic ninth vertebral bodies (age 76.9 ± 10.8 years). After experimentally overloading the vertebrae to measure strength, we used nonlinear finite element analysis to estimate the amount of failed tissue and understand the failure mechanisms. We found that the amount of failed tissue per unit bone mass decreased with decreasing bone volume fraction (r(2) = 0.66, p < 0.01). Thus, for the weak vertebrae with low bone volume fraction, overall failure of the vertebra occurred after failure of just a tiny proportion of the bone tissue (<5%). This small proportion of failed tissue had two sources: the existence of fewer vertically oriented load paths to which load could be redistributed from failed trabeculae; and the vulnerability of the trabeculae in these few load paths to undergo bending-type failure mechanisms, which further weaken the bone. Taken together, these characteristics suggest that diminished structural redundancy may be an important aspect of age-related vertebral fragility: vertebrae with low bone volume fraction are highly susceptible to collapse because so few trabeculae are available for load redistribution if the external loads cause any trabeculae to fail.

Citing Articles

Relationships Among Bone Morphological Parameters and Mechanical Properties of Cadaveric Human Vertebral Cancellous Bone.

Al-Barghouthi A, Lee S, Solitro G, Latta L, Travascio F JBMR Plus. 2023; 4(5):e10351.

PMID: 37780057 PMC: 10540741. DOI: 10.1002/jbm4.10351.

Relative Effects of Radiation-Induced Changes in Bone Mass, Structure, and Tissue Material on Vertebral Strength in a Rat Model.

Emerzian S, Wu T, Vaidya R, Tang S, Abergel R, Keaveny T J Bone Miner Res. 2023; 38(7):1032-1042.

PMID: 37191221 PMC: 10524463. DOI: 10.1002/jbmr.4828.

Diet X Gene Interactions Control Femoral Bone Adaptation to Low Dietary Calcium.

Chanpaisaeng K, Reyes-Fernandez P, Dilkes B, Fleet J JBMR Plus. 2022; 6(9):e10668.

PMID: 36111202 PMC: 9465001. DOI: 10.1002/jbm4.10668.

The normal stiffness of the edentulous alveolar process.

Chen S, Rittel D, Shemtov Yona K Bone Rep. 2021; 14:101066.

PMID: 33898661 PMC: 8060551. DOI: 10.1016/j.bonr.2021.101066.

Load-transfer in the human vertebral body following lumbar total disc arthroplasty: Effects of implant size and stiffness in axial compression and forward flexion.

Bonnheim N, Keaveny T JOR Spine. 2020; 3(1):e1078.

PMID: 32211590 PMC: 7084059. DOI: 10.1002/jsp2.1078.

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