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Sagittal range of motion of the thoracic spine using inertial tracking device and effect of measurement errors on model predictions

Hajibozorgi, M ; Sharif University of Technology

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  1. Type of Document: Article
  2. DOI: 10.1016/j.jbiomech.2015.09.003
  3. Publisher: Elsevier Ltd
  4. Abstract:
  5. Range of motion (ROM) of the thoracic spine has implications in patient discrimination for diagnostic purposes and in biomechanical models for predictions of spinal loads. Few previous studies have reported quite different thoracic ROMs. Total (T1-T12), lower (T5-T12) and upper (T1-T5) thoracic, lumbar (T12-S1), pelvis, and entire trunk (T1) ROMs were measured using an inertial tracking device as asymptomatic subjects flexed forward from their neutral upright position to full forward flexion. Correlations between body height and the ROMs were conducted. An effect of measurement errors of the trunk flexion (T1) on the model-predicted spinal loads was investigated. Mean of peak voluntary total flexion of trunk (T1) was 118.4±13.9°, of which 20.5±6.5° was generated by flexion of the T1 to T12 (thoracic ROM), and the remaining by flexion of the T12 to S1 (lumbar ROM) (50.2±7.0°) and pelvis (47.8±6.9°). Lower thoracic ROM was significantly larger than upper thoracic ROM (14.8±5.4° versus 5.8±3.1°). There were non-significant weak correlations between body height and the ROMs. Contribution of the pelvis to generate the total trunk flexion increased from ~20% to 40% and that of the lumbar decreased from ~60% to 42% as subjects flexed forward from upright to maximal flexion while that of the thoracic spine remained almost constant (~16% to 20%) during the entire movement. Small uncertainties (±5°) in the measurement of trunk flexion angle resulted in considerable errors (~27%) in the model-predicted spinal loads only in activities involving small trunk flexion
  6. Keywords:
  7. Body height ; Inertial tracking ; Modeling ; Range of motion ; Thoracic spine ; Errors ; Forecasting ; Measurement errors ; Models ; Uncertainty analysis ; Bio-mechanical models ; Body height ; Effect of measurements ; Model prediction ; Range of motions ; Upright position ; Load testing ; Adult ; Article ; Biomechanical model ; Controlled study ; Full forward flexion ; General medical device ; Human ; Human experiment ; In vivo study ; Inertial tracking device ; Lower thoracic range of motion ; Lumbar range of motion ; Lumbopelvic ratio ; Male ; Mathematical model ; Measurement accuracy ; Measurement error ; Normal human ; Pelvis range of motion ; Prediction ; Priority journal ; Sagittal range of motion ; Spinal load ; Standing ; Trunk flexion ; Trunk flexion angle ; Trunk range of motion ; Uncertainty ; Upper thoracic range of motion ; Upright standing ; Young adult
  8. Source: Journal of Biomechanics ; Volume 49, Issue 6 , 2016 , Pages 913-918 ; 00219290 (ISSN)
  9. URL: http://www.sciencedirect.com/science/article/pii/S0021929015004790