DISCSIM
Multi-scale biomechanical modelling and simulation of the intervertebral disc
| Coordinatore | ECOLE NATIONALE SUPERIEURE D'ARTS ET METIERS
Organization address
address: BOULEVARD DE L'HOPITAL 147 contact info |
| Nazionalità Coordinatore | France [FR] |
| Totale costo | 252˙659 € |
| EC contributo | 252˙659 € |
| Programma | FP7-PEOPLE
Specific programme "People" implementing the Seventh Framework Programme of the European Community for research, technological development and demonstration activities (2007 to 2013) |
| Code Call | FP7-PEOPLE-2010-IIF |
| Funding Scheme | MC-IIF |
| Anno di inizio | 2012 |
| Periodo (anno-mese-giorno) | 2012-04-02 - 2014-04-01 |
Partecipanti
| # | ||||
|---|---|---|---|---|
| 1 |
ECOLE NATIONALE SUPERIEURE D'ARTS ET METIERS
Organization address
address: BOULEVARD DE L'HOPITAL 147 contact info |
FR (PARIS) | coordinator | 252˙659.00 |
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Obiettivo del progetto (Objective)
'Computational mechanics techniques have revolutionised the design and analysis of engineered structures. The emerging field of Computational Biomechanics (CB) applies these techniques to study biological structures and systems. A key advantage of CB is the ability to predict physical quantities (such as flow and deformation) over a range of length and timescales in biological tissues, whereas such quantities are difficult or impossible to measure experimentally in living organisms.
This project will develop multiscale CB approaches to analyse the largest avascular structure in the human body, the intervertebral disc. The intervertebral disc is subjected to large deformations during spinal motion, withstands transient loads of up to 9 times body weight during rigorous physical activity, and due to its lack of blood supply, its nutrient supply is provided by fluid-borne diffusion through the disc tissues from the adjacent vertebral bodies. A multiscale model of the intervertebral disc will substantially advance the study of disc mechanics by linking whole disc loading and deformation to the mechanical microenvironment experienced by cells embedded within the disc tissue. This approach promises new insights into tissue repair and remodelling in healthy discs, into tissue damage and cell death in degenerate discs, and in predicting disc response to emerging treatments such as annular repair and nucleus replacement.'
Introduzione (Teaser)
Nearly one third of people show intervertebral disc degeneration to some degree by the time they are 35 and most do by the age of 60. A new biomechanical model of the cushions between the bony vertebrae could lead to new therapies and relief for millions.
Descrizione progetto (Article)
The human spine, also known as the vertebral column or backbone, is made up of bony interconnected vertebrae. The vertebrae are separated by spongy fibrous intervertebral discs with jelly-like cores that play an important role in comfort and function. They absorb loads up to nine times the body's weight during strenuous physical activity while allowing the flexibility necessary for everyday motions.
Acute injury and age-related degeneration of the intervertebral disc result in loss of integrity of the outer fibrous part of the disc (the annulus). Healing is slow because the disc system is the largest avascular structure (without a blood supply) in the human body. A new model developed with EU support of the project 'Multi-scale biomechanical modelling and simulation of the intervertebral disc' (DISCSIM) is providing insight into disc behaviour in health and disease. It promises better treatments for the millions suffering from disc degeneration.
In order to obtain detailed microscopic structural information about the discs, samples from a steer's tail or a human spine were embedded in various media and slices were made on a milling machine. Simultaneously, two microscopes mounted to the milling machine captured images at each level. Samples were also subjected to micromechanical testing. Optimisation of the fixation device is underway but, in the meantime, data were collected to provide tissue-level elastic properties of the steer bone for computational models of the intervertebral disc unit.
Based on experimental data, researchers developed a multi-scale computational model of the intervertebral disc in the commercially available finite element analysis software package ABAQUS. It is the first to accommodate interlamellar sliding, shearing and separation. Shear strain has been implicated as one potential initiator of intervertebral disc annulus failure. Annulus rupture can lead to herniation of the inner gelatinous layer, or a so-called herniated disc. The model was validated against compression data from steer tail intervertebral discs.
Exploration of the parameter space of the DISCSIM model led to enhanced understanding of disc biomechanics that may help ease the socioeconomic burden of disc-related pathologies. The model will benefit scientists, clinicians and eventually patients in areas including scoliosis, back pain and disc degeneration.