Tissue Injury and Effects of Applied Vibration on the Intervertebral Disc
Date
2013-04-29
Authors
Journal Title
Journal ISSN
Volume Title
Publisher
Abstract
It is thought that disc degeneration can cause spine related pain. New treatments acting at
cellular levels in the intervertebral discs (IVD) may offer potential to improve long-term disc
health. Hence, optimized loading that induces positive cellular changes in the disc may improve
disc health delaying the onset of degeneration, thus delaying the onset of pain. This dissertation
evaluates and improves a vibration based spinal intervention called the Khan Kinetic Treatment
(KKT) while describing some of its mechanisms of treatment of the intervertebral disc.
Objectives of this study are to: 1) test effects of vibration on disc biosynthesis prior to
device modifications (KKT_v1); 2) determine vibration conditions that are most effective in
positively altering IVD gene expression; 3) implement findings from objective 2 by modifying
the spinal intervention (KKT_v2) and repeating tests; and 4) design, build, validate, and
experiment with a novel bioreactor so that other tissues may be targeted.
It could be concluded that the un-modified interventions (KKT_v1) vibration loading
profile did not fall within the influential range that affects the cells of the bovine IVD. Objective
2 results showed that expression of certain extracellular matrix genes were significantly up
regulated with specific vibration loading patterns, indicating a potential therapeutic stimulus (10
min. total duration of an equal mix of 16 Hz and a 50-80 Hz frequency sweep at a minimum of
0.4 g amplitude). Objective 3 had KKT_v1’s firmware edited to drive the new frequencies found
to be most effective in objective 2 making KKT_v2; results of objective 3 showed that
expression of certain extracellular matrix genes were significantly up regulated when vibrated
with the modified intervention (KKT_v2) indicating a potential therapeutic stimulus of the
intervention itself. Objective 4 results confirmed the positive influence of mRNA expression
with the new bioreactor by utilizing the optimal vibration patterns identified in objective 2. This research has moved past the proof of concept stage as it has been shown that specific
vibration conditions (10 min, 16 & 50-80 Hz, 0.4g) can influence the expression of cell genes in
the IVD. The novel bioreactor built as a result of chapter 4 allows us to test other tissues, while
mimicking in-vivo conditions. This information could be used to construct future experiments in
protein expression or in-vivo MRI studies of human IVD.
Description
Keywords
Engineering--Biomedical
Citation
Desmoulin, G. (2013). Tissue Injury and Effects of Applied Vibration on the Intervertebral Disc (Doctoral thesis, University of Calgary, Calgary, Canada). Retrieved from https://prism.ucalgary.ca. doi:10.11575/PRISM/28458