Internal three-dimensional strains in human intervertebral discs under axial compression quantified noninvasively by magnetic resonance imaging and image registration. Yoder, J. H., Peloquin, J. M., Song, G., Tustison, N. J., Moon, S. M., Wright, A. C., Vresilovic, E. J., Gee, J. C., & Elliott, D. M. Journal of Biomechanical Engineering, November, 2014.
doi  abstract   bibtex   
Study objectives were to develop, validate, and apply a method to measure three-dimensional (3D) internal strains in intact human discs under axial compression. A custom-built loading device applied compression and permitted load-relaxation outside of the magnet while also maintaining compression and hydration during imaging. Strain was measured through registration of 300 μm isotropic resolution images. Excellent registration accuracy was achieved, with 94% and 65% overlap of disc volume and lamellae compared to manual segmentation, and an average Hausdorff, a measure of distance error, of 0.03 and 0.12 mm for disc volume and lamellae boundaries, respectively. Strain maps enabled qualitative visualization and quantitative regional annulus fibrosus (AF) strain analysis. Axial and circumferential strains were highest in the lateral AF and lowest in the anterior and posterior AF. Radial strains were lowest in the lateral AF, but highly variable. Overall, this study provided new methods that will be valuable in the design and evaluation surgical procedures and therapeutic interventions.
@article{yoder_internal_2014,
	title = {Internal three-dimensional strains in human intervertebral discs under axial compression quantified noninvasively by magnetic resonance imaging and image registration},
	volume = {136},
	issn = {1528-8951},
	doi = {10.1115/1.4028250},
	abstract = {Study objectives were to develop, validate, and apply a method to measure three-dimensional (3D) internal strains in intact human discs under axial compression. A custom-built loading device applied compression and permitted load-relaxation outside of the magnet while also maintaining compression and hydration during imaging. Strain was measured through registration of 300 μm isotropic resolution images. Excellent registration accuracy was achieved, with 94\% and 65\% overlap of disc volume and lamellae compared to manual segmentation, and an average Hausdorff, a measure of distance error, of 0.03 and 0.12 mm for disc volume and lamellae boundaries, respectively. Strain maps enabled qualitative visualization and quantitative regional annulus fibrosus (AF) strain analysis. Axial and circumferential strains were highest in the lateral AF and lowest in the anterior and posterior AF. Radial strains were lowest in the lateral AF, but highly variable. Overall, this study provided new methods that will be valuable in the design and evaluation surgical procedures and therapeutic interventions.},
	language = {eng},
	number = {11},
	journal = {Journal of Biomechanical Engineering},
	author = {Yoder, Jonathon H. and Peloquin, John M. and Song, Gang and Tustison, Nick J. and Moon, Sung M. and Wright, Alexander C. and Vresilovic, Edward J. and Gee, James C. and Elliott, Dawn M.},
	month = nov,
	year = {2014},
	pmid = {25109533},
	pmcid = {PMC4181341},
	keywords = {intervertebral disc (IVD)}
}
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