Your search keyword '"Intervertebral Disc chemistry"' showing total 4 results

1. Effects of enzymatic digestion on compressive properties of rat intervertebral discs.

Author

Barbir A, Michalek AJ, Abbott RD, and Iatridis JC

Subjects

Animals, Biomechanical Phenomena, Collagen chemistry, Collagen physiology, Collagenases, Compressive Strength, Elastin chemistry, Elastin physiology, In Vitro Techniques, Intervertebral Disc chemistry, Intervertebral Disc Degeneration physiopathology, Models, Biological, Movement, Rats, Rats, Sprague-Dawley, Intervertebral Disc physiology

Abstract

Enzymatic treatments were applied to rat motion segments to establish structure-function relationships and determine mechanical parameters most sensitive to simulated remodeling and degeneration. Rat caudal and lumbar disc biomechanical behaviors were evaluated to improve knowledge of their similarities and differences due to their frequent use during in vivo models. Caudal motion segments were assigned to four groups: soaked (control), genipin treated, elastase treated, and collagenase treated. Fresh lumbar and caudal discs were also compared. The mechanical protocol involved five force-controlled loading stages: equilibration, cyclic compression-tension, quasi-static compression, frequency sweep, and creep. Crosslinking was found to have the greatest effect on IVD properties at resting stress. Elastin's role was greatest in tension and at higher force conditions, where GAG content was also a contributing factor. Collagenase treatment caused tissue compaction, which impacted mechanical properties at both high and low force conditions. Equilibration creep and cyclic compression-tension tests were the mechanical tests most sensitive to alterations in specific matrix constituents. Caudal and lumbar motion segments had many similarities but biomechanical differences suggested some distinctions in collagenous structure and water transport characteristics in addition to the geometric differences. Results provide a basis for interpreting biomechanical changes observed in animal model studies of degeneration and remodeling, and underscore the need to maintain and/or repair collagen integrity in IVD health and disease., (Copyright 2009 Elsevier Ltd. All rights reserved.)

Published

2010

2. Assessment of compressive modulus, hydraulic permeability and matrix content of trypsin-treated nucleus pulposus using quantitative MRI.

Author

Périé D, Iatridis JC, Demers CN, Goswami T, Beaudoin G, Mwale F, and Antoniou J

Subjects

Animals, Cattle, Compressive Strength, Diffusion, Elasticity, Permeability, Radiography, Stress, Mechanical, Tail diagnostic imaging, Diffusion Magnetic Resonance Imaging, Image Interpretation, Computer-Assisted, Intervertebral Disc chemistry, Intervertebral Disc diagnostic imaging, Trypsin chemistry

Abstract

A clinical strength MRI and intact bovine caudal intervertebral discs were used to test the hypotheses that (1) mechanical loading and trypsin treatment induce changes in NMR parameters, mechanical properties and biochemical contents; and (2) mechanical properties are quantitatively related to NMR parameters. MRI acquisitions, confined compression stress-relaxation experiments, and biochemical assays were applied to determine the NMR parameters (relaxation times T1 and T2, magnetization transfer ratio (MTR) and diffusion trace (TrD)), mechanical properties (compressive modulus H(A0) and hydraulic permeability k(0)), and biochemical contents (H(2)O, proteoglycan and total collagen) of nucleus pulposus tissue from bovine caudal discs subjected to one of two injections and one of two mechanical loading conditions. Significant correlations were found between k(0) and T1 (r=0.75,p=0.03), T2 (r=0.78, p=0.02), and TrD (r=0.85, p=0.007). A trend was found between H(A0) and TrD (r=0.56, p=0.12). However, loading decreased these correlations (r=0.4, p=0.2). The significant effect of trypsin treatment on mechanical properties, but not on NMR parameters, may suggest that mechanical properties are more sensitive to the structural changes induced by trypsin treatment. The significant effect of loading on T1 and T2, but not on H(A0) or k(0), may suggest that NMR parameters are more sensitive to the changes in water content enhanced by loading. We conclude that MRI offers promise as a sensitive and non-invasive technique for describing alterations in material properties of intervertebral disc nucleus, and our results demonstrate that the hydraulic permeability correlated more strongly to the quantitative NMR parameters than did the compressive modulus; however, more studies are necessary to more precisely characterize these relationships.

Published

2006

3. Heat-induced changes in porcine annulus fibrosus biomechanics.

Author

Bass EC, Wistrom EV, Diederich CJ, Nau WH, Pellegrino R, Ruberti J, and Lotz JC

Subjects

Animals, Biomechanical Phenomena methods, Calorimetry, Differential Scanning, Collagen chemistry, Collagen ultrastructure, Dose-Response Relationship, Radiation, Elasticity, In Vitro Techniques, Intervertebral Disc chemistry, Intervertebral Disc cytology, Protein Denaturation, Swine, Temperature, Collagen physiology, Collagen radiation effects, Energy Transfer physiology, Hot Temperature, Intervertebral Disc physiology, Intervertebral Disc radiation effects

Abstract

The intervertebral disc is implicated as the source of low-back pain in a substantial number of patients. Because thermal therapy has been thought to have a therapeutic effect on collagenous tissues, this technique has recently been incorporated into several minimally invasive back pain treatments. However, patient selection criteria and precise definition of optimum dose are hindered by uncertainty of treatment mechanisms. The purpose of this study was to quantify acute changes in annulus fibrosus biomechanics after a range of thermal exposures, and to correlate these results with tissue denaturation. Intact annulus fibrosus (attached to adjacent vertebrae) from porcine lumbar spines was tested ex vivo. Biomechanical behavior, microstructure, peak of denaturation endotherm, and enthalpy of denaturation (mDSC) were determined before and after hydrothermal heat treatment at 37 degrees C, 50 degrees C, 60 degrees C, 65 degrees C, 70 degrees C, 75 degrees C, 80 degrees C, and 85 degrees C. Shrinkage of excised annular tissue (removed from adjacent vertebrae) was also measured after treatment at 85 degrees C. Significant differences in intact annulus biomechanics were observed after treatment, but the effects were much smaller in magnitude than those observed in excised annulus and those reported previously for other tissues. Consistent with this, intact tissue was only minimally denatured by treatment at 85 degrees C for 15 min, whereas excised tissue was completely denatured by this protocol. Our data suggest that in situ constraint imposed by the joint structure significantly retards annular thermal denaturation. These findings should aid the interpretation of clinical outcomes and provide a basis for the future design of optimum dosing regimens.

Published

2004

4. Fluid flow and convective transport of solutes within the intervertebral disc.

Author

Ferguson SJ, Ito K, and Nolte LP

Subjects

Animals, Biological Transport physiology, Body Fluids chemistry, Computer Simulation, Diffusion, Elasticity, Humans, Intervertebral Disc chemistry, Mechanotransduction, Cellular physiology, Pressure, Solutions chemistry, Stress, Mechanical, Body Fluids metabolism, Circadian Rhythm physiology, Intervertebral Disc physiology, Microfluidics methods, Models, Biological, Solutions pharmacokinetics, Water-Electrolyte Balance physiology, Weight-Bearing physiology

Abstract

Previous experimental and analytical studies of solute transport in the intervertebral disc have demonstrated that for small molecules diffusive transport alone fulfils the nutritional needs of disc cells. It has been often suggested that fluid flow into and within the disc may enhance the transport of larger molecules. The goal of the study was to predict the influence of load-induced interstitial fluid flow on mass transport in the intervertebral disc. An iterative procedure was used to predict the convective transport of physiologically relevant molecules within the disc. An axisymmetric, poroelastic finite-element structural model of the disc was developed. The diurnal loading was divided into discrete time steps. At each time step, the fluid flow within the disc due to compression or swelling was calculated. A sequentially coupled diffusion/convection model was then employed to calculate solute transport, with a constant concentration of solute being provided at the vascularised endplates and outer annulus. Loading was simulated for a complete diurnal cycle, and the relative convective and diffusive transport was compared for solutes with molecular weights ranging from 400 Da to 40 kDa. Consistent with previous studies, fluid flow did not enhance the transport of low-weight solutes. During swelling, interstitial fluid flow increased the unidirectional penetration of large solutes by approximately 100%. Due to the bi-directional temporal nature of disc loading, however, the net effect of convective transport over a full diurnal cycle was more limited (30% increase). Further study is required to determine the significance of large solutes and the timing of their delivery for disc physiology.

Published

2004