Technical Brief

Mapping of Intervertebral Disk Annulus Fibrosus Compressive Properties Is Sensitive to Specimen Boundary Conditions

[+] Author and Article Information
Sarah E. Duclos

Department of Mechanical & Aeronautical Engineering,
Clarkson University,
P.O. Box 5725,
Potsdam, NY 13699

Arthur J. Michalek

Department of Mechanical & Aeronautical Engineering,
Clarkson University,
P.O. Box 5725,
Potsdam, NY 13699
e-mail: ajmichal@clarkson.edu

1Corresponding author.

Manuscript received May 20, 2018; final manuscript received January 4, 2019; published online February 13, 2019. Assoc. Editor: David Corr.

J Biomech Eng 141(4), 044501 (Feb 13, 2019) (5 pages) Paper No: BIO-18-1240; doi: 10.1115/1.4042600 History: Received May 20, 2018; Revised January 04, 2019

Predicting the mechanical behavior of the intervertebral disk (IVD) in health and in disease requires accurate spatial mapping of its compressive mechanical properties. Previous studies confirmed that residual strains in the annulus fibrosus (AF) of the IVD, which result from nonuniform extracellular matrix deposition in response to in vivo loads, vary by anatomical regions (anterior, posterior, and lateral) and zones (inner, middle, and outer). We hypothesized that as the AF is composed of a nonlinear, anisotropic, viscoelastic material, the state of residual strain in the transverse plane would influence the apparent values of axial compressive properties. To test this hypothesis, axial creep indentation tests were performed, using a 1.6 mm spherical probe, at nine different anatomical locations on bovine caudal AFs in both the intact (residual strain present) and strain relieved states. The results showed a shift toward increased spatial homogeneity in all measured parameters, particularly instantaneous strain. This shift was not observed in control AFs, which were tested twice in the intact state. Our results confirm that time-dependent axial compressive properties of the AF are sensitive to the state of residual strain in the transverse plane, to a degree that is likely to affect whole disk behavior.

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Grahic Jump Location
Fig. 3

Instantaneous strain was markedly more spatially heterogeneous when the AF was tested in the intact state (top) than in the strain relieved state (bottom)

Grahic Jump Location
Fig. 2

Typical fit of single exponential to experimental creep data. Experimental data have been down-sampled for illustrative purposes.

Grahic Jump Location
Fig. 1

Bovine AF specimens were tested twice using one of two protocols, first in the intact state, then in either the strain relieved or intact state. Approximate indentation locations are indicated by red dots.



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