Repetitive in vivo manual loading of the spine elicits cellular responses in porcine annuli fibrosi.
John Robert MatyasClaudia KleinDragana PonjevicNeil A DuncanGregory N KawchukPublished in: PloS one (2021)
Back pain and intervertebral disc degeneration are prevalent, costly, and widely treated by manual therapies, yet the underlying causes of these diseases are indeterminate as are the scientific bases for such treatments. The present studies characterize the effects of repetitive in vivo manual loads on porcine intervertebral disc cell metabolism using RNA deep sequencing. A single session of repetitive manual loading applied to the lumbar spine induced both up- and down-regulation of a variety of genes transcribed by cells in the ventral annuli fibrosi. The effect of manual therapy at the level of loading was greater than at a level distant to the applied load. Gene ontology and molecular pathway analyses categorized biological, molecular, and cellular functions influenced by repetitive manual loading, with over-representation of membrane, transmembrane, and pericellular activities. Weighted Gene Co-expression Network Analysis discerned enrichment in genes in pathways of inflammation and skeletogenesis. The present studies support previous findings of intervertebral disc cell mechanotransduction, and are the first to report comprehensively on the repertoire of gene targets influenced by mechanical loads associated with manual therapy interventions. The present study defines the cellular response of repeated, low-amplitude loads on normal healthy annuli fibrosi and lays the foundation for future work defining how healthy and diseased intervertebral discs respond to single or low-frequency manual loads typical of those applied clinically.
Keyphrases
- genome wide
- network analysis
- high frequency
- single cell
- genome wide identification
- cell therapy
- oxidative stress
- physical activity
- poor prognosis
- spinal cord
- magnetic resonance
- genome wide analysis
- induced apoptosis
- functional connectivity
- cell proliferation
- binding protein
- high glucose
- high intensity
- resting state
- diabetic rats
- endoplasmic reticulum stress
- current status
- cell cycle arrest
- working memory
- smoking cessation
- free survival
- transcranial direct current stimulation
- neural network