Sensitivity of muscle and intervertebral disc force computations to variations in muscle attachment sites

Bayoğlu, Rıza; Güldeniz, Oğulcan; Koopman, Bart; Homminga, Jasper Johan

doi:10.1080/10255842.2019.1644502

Cited by 7 publications

(6 citation statements)

References 47 publications

(64 reference statements)

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“…The slippage force values reported in our work were significantly close to the reported physiological loads in the literature, which could explain the tether breakage in vivo. In a recent study, intervertebral disc reaction forces during a 30-degree lateral bending were reported as 453 N, 460 N, and 652 N on the T6/T7, T12/L1, and L4/L5, respectively [ 19 ]. In another study, disc compressive forces during a 30-degree lateral bending on T11/T12 and L4/L5 were reported as 100% and 130% of the body weight, respectively, which corresponds to approximately 320–750 N for a 10–20-year-old adolescent (average 32–58 kg weight) [ 33 ].…”

Section: Discussionmentioning

confidence: 99%

“…[ 15 , 17 , 18 ]. However, recent biomechanical studies investigating the loads on the spine show that the highest physiological loads reach only up to approximately 650 N on the L4/L5 level, which corresponds to only 52 MPa (assuming the loads are coinciding with the tether’s axis) [ 19 ]. Furthermore, recent studies have shown that a correction force of 150–200 N is sufficient to modify the asymmetrical compression in AIS patients [ 20 ].…”

Section: Introductionmentioning

confidence: 99%

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Biomechanics of the tether breakage: tensile behaviour of a single-unit vertebral body tethering construct

et al. 2023

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Purpose Tether breakage was reported as the most common complication of vertebral body tethering. However, as the literature suggests the physiological loads do not have the potential to cause the failure of the tether. Currently, the biomechanical reason behind the tether breakage is unknown. The current study aims to elucidate the effects of the tension forces on the failure mechanisms of the VBT and provide mechanical justification for how it can be identified radiographically. Methods Tensile tests (20%/min strain rate) were performed on single-unit VBT samples. Failure modes and mechanical characteristics were reported. Results The failure took place prematurely due to the slippage of the tether at the screw–tether junction where the tether is damaged significantly by the locking cap. Slippage was initiated at 10–13% tensile strain level where the tensile stress and tension force were 50.4 ± 1.5 MPa and 582.2 ± 30.8 N, respectively. Conclusion The failure occurs because of high-stress concentrations generated within the locking region which damages the tether surface and leads to the slippage of the tether. We observed that the loads leading to failure are within the physiological limits and may indicate the high likelihood of the tether breakage. The failure mode observed in our study is shown to be the dominant failure mode, and a design improvement on the gripping mechanism is suggested to avoid failure at the screw–tether junction. We observed that the tether elongates 10–13% prior to the breakage, which can be employed as a diagnostic criterion to screen for tether breakages radiographically.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Biomechanics of the tether breakage: tensile behaviour of a single-unit vertebral body tethering construct

et al. 2023

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“…Reported values for K vary between 10 and 100 N/cm 2 ( Daggfeldt and Thorstensson, 2003 ; Hansen et al, 2006 ). In models of the lower back, most commonly values of 46 ( Bogduk et al, 1992 ; Stokes and Gardner-Morse, 1995 ; Christophy et al, 2012 ), 60 ( Arjmand and Shirazi-Adl, 2006a ), 90 ( Arshad et al, 2016 ), or 100 N/cm 2 ( Bruno et al, 2015 ; Bayoglu et al, 2019 ; Favier et al, 2021a ; Lerchl et al, 2022 ; Malakoutian et al, 2022 ) were assumed. Thus, we tested values of 46, 73, and 100 N/cm 2 for K , expected

≤ 1.0°, and that no muscle was fully activated by the TC.…”

Section: Methodsmentioning

confidence: 99%

“…Most validated and extensively used biomechanical spine models belong to either the musculoskeletal multibody (MB) ( de Zee et al, 2007 ; Christophy et al, 2012 ; Bruno et al, 2015 ; Senteler et al, 2016 ; Malakoutian et al, 2018 ; Bayoglu et al, 2019 ; Lerchl et al, 2022 ; Meszaros-Beller et al, 2023 ) or implicit finite element (FE) method ( Schmidt et al, 2006 ; Ayturk and Puttlitz, 2011 ; Dreischarf et al, 2014 ; Naserkhaki et al, 2018 ; Turbucz et al, 2022 ). Musculoskeletal MB models are used to analyze mechanisms consisting of rigid bodies subject to mechanically simplifying joints and constraints.…”

Section: Introductionmentioning

confidence: 99%

“…Studies thus examined interindividual muscle activation patterns, joint reaction forces, or vertebral movements in varying postures during different activities. Resulting muscle redundancy problems are commonly solved inverse dynamically ( de Zee et al, 2007 ; Erdemir et al, 2007 ; Bayoglu et al, 2019 ). New approaches omit the specification of accurate kinematic data for the spine by forward dynamics simulation of a fully articulated spine ( Rupp et al, 2015 ; Malakoutian et al, 2018 ; Meszaros-Beller et al, 2023 ) and including stiffening effects caused by compressive loads ( Wang et al, 2020 ).…”

Section: Introductionmentioning

confidence: 99%

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Muscle-driven forward dynamic active hybrid model of the lumbosacral spine: combined FEM and multibody simulation

Remus,

Selkmann,

Lipphaus

et al. 2023

Front. Bioeng. Biotechnol.

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Most spine models belong to either the musculoskeletal multibody (MB) or finite element (FE) method. Recently, coupling of MB and FE models has increasingly been used to combine advantages of both methods. Active hybrid FE-MB models, still rarely used in spine research, avoid the interface and convergence problems associated with model coupling. They provide the inherent ability to account for the full interplay of passive and active mechanisms for spinal stability. In this paper, we developed and validated a novel muscle-driven forward dynamic active hybrid FE-MB model of the lumbosacral spine (LSS) in ArtiSynth to simultaneously calculate muscle activation patterns, vertebral movements, and internal mechanical loads. The model consisted of the rigid vertebrae L1-S1 interconnected with hyperelastic fiber-reinforced FE intervertebral discs, ligaments, facet joints, and force actuators representing the muscles. Morphological muscle data were implemented via a semi-automated registration procedure. Four auxiliary bodies were utilized to describe non-linear muscle paths by wrapping and attaching the anterior abdominal muscles. This included an abdominal plate whose kinematics was optimized using motion capture data from upper body movements. Intra-abdominal pressure was calculated from the forces of the abdominal muscles compressing the abdominal cavity. For the muscle-driven approach, forward dynamics assisted data tracking was used to predict muscle activation patterns that generate spinal postures and balance the spine without prescribing accurate spinal kinematics. During calibration, the maximum specific muscle tension and spinal rhythms resulting from the model dynamics were evaluated. To validate the model, load cases were simulated from −10° extension to +30° flexion with weights up to 20 kg in both hands. The biomechanical model responses were compared with in vivo literature data of intradiscal pressures, intra-abdominal pressures, and muscle activities. The results demonstrated high agreement with this data and highlight the advantages of active hybrid modeling for the LSS. Overall, this new self-contained tool provides a robust and efficient estimation of LSS biomechanical responses under in vivo similar loads, for example, to improve pain treatment by spinal stabilization therapies.

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Development of a multiscale model of the human lumbar spine for investigation of tissue loads in people with and without a transtibial amputation during sit-to-stand

Honegger

Actis

Gates

et al. 2020

Biomech Model Mechanobiol

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Sensitivity of muscle and intervertebral disc force computations to variations in muscle attachment sites

Cited by 7 publications

References 47 publications

Biomechanics of the tether breakage: tensile behaviour of a single-unit vertebral body tethering construct

Biomechanics of the tether breakage: tensile behaviour of a single-unit vertebral body tethering construct

Muscle-driven forward dynamic active hybrid model of the lumbosacral spine: combined FEM and multibody simulation

Development of a multiscale model of the human lumbar spine for investigation of tissue loads in people with and without a transtibial amputation during sit-to-stand

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