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Effect of changes in the lumbar posture in lifting on trunk muscle and spinal loads: A combined in vivo, musculoskeletal, and finite element model study

Khoddam Khorasani, P ; Sharif University of Technology | 2020

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  1. Type of Document: Article
  2. DOI: 10.1016/j.jbiomech.2020.109728
  3. Publisher: Elsevier Ltd , 2020
  4. Abstract:
  5. Irrespective of the lifting technique (squat or stoop), the lumbar spine posture (more kyphotic versus more lordotic) adopted during lifting activities is an important parameter affecting the active-passive spinal load distribution. The advantages in either posture while lifting remains, however, a matter of debate. To comprehensively investigate the role on the trunk biomechanics of changes in the lumbar posture (lordotic, free or kyphotic) during forward trunk flexion, validated musculoskeletal and finite element models, driven by in vivo kinematics data, were used to estimate detailed internal tissue stresses-forces in and load-sharing among various joint active-passive tissues. Findings indicated that the lordotic posture, as compared to the kyphotic one, resulted in marked increases in back global muscle activities (~14–19%), overall segmental compression (~7.5–46.1%) and shear (~5.4–47.5%) forces, and L5-S1 facet joint forces (by up to 80 N). At the L5-S1 level, the lordotic lumbar posture caused considerable decreases in the moment resisted by passive structures (spine and musculature, ~14–27%), negligible reductions in the maximum disc fiber strains (by ~0.4–4.7%) and small increases in intradiscal pressure (~1.8–3.4%). Collectively and with due consideration of the risk of fatigue and viscoelastic creep especially under repetitive lifts, current results support a free posture (in between the extreme kyphotic and lordotic postures) with moderate contributions from both active and passive structures during lifting activities involving trunk forward flexion. © 2020 Elsevier Ltd
  6. Keywords:
  7. Spine ; Data Sharing ; Models ; Muscle ; Kyphotic ; Lifting ; Lordotic ; Lumbar posture ; Finite element method ; Adult ; Biomechanics ; Body position ; Fatigue ; Finite element analysis ; Human experiment ; In vivo study ; Intervertebral disk ; Kinematics ; Lumbar spine ; Male ; Muscle contraction ; Musculoskeletal system ; Normal human ; Shear strength ; Skeletal muscle ; Trunk ; Viscoelasticity
  8. Source: Journal of Biomechanics ; Volume 104 , February , 2020
  9. URL: https://europepmc.org/article/med/32147242