Sacrospinous and sacrotuberous ligaments influence in pelvis kinematics

Petr Henyš; Maziar Ramezani; Daniel Schewitz; Andreas Höch; Dustin Möbius; Benjamin Ondruschka; Niels Hammer

doi:10.1111/joa.13739

Sacrospinous and sacrotuberous ligaments influence in pelvis kinematics

Petr Henyš, Maziar Ramezani, Daniel Schewitz, Andreas Höch, Dustin Möbius, Benjamin Ondruschka, Niels Hammer

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Abstract

The alteration in mechanical properties of posterior pelvis ligaments may cause a biased pelvis deformation which, in turn, may contribute to hip and spine instability and malfunction. Here, the effect of different mechanical properties of ligaments on lumbopelvic deformation is analyzed via the finite element method. First, the improved finite element model was validated using experimental data from previous studies and then used to calculate the sensitivity of lumbopelvic deformation to changes in ligament mechanical properties, load magnitude, and unilateral ligament resection. The deformation of the lumbopelvic complex relative to a given load was predominant in the medial plane. The effect of unilateral resection on deformation appeared to be counterintuitive, suggesting that ligaments have the ability to redistribute load and that they play an important role in the mechanics of the lumbopelvic complex.

Original language	English
Pages (from-to)	928-937
Number of pages	10
Journal	Journal of Anatomy
Volume	241
Issue number	4
DOIs	https://doi.org/10.1111/joa.13739
Publication status	Published - Oct 2022
Externally published	Yes

Keywords

elasticity
finite element method
hip–spine syndrome
lumbopelvic transition
pelvic ligaments
sacroiliac joint

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10.1111/joa.13739Licence: CC BY-NC-ND

Published versionFinal published version, 1.64 MBLicence: CC BY-NC-ND

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title = "Sacrospinous and sacrotuberous ligaments influence in pelvis kinematics",

abstract = "The alteration in mechanical properties of posterior pelvis ligaments may cause a biased pelvis deformation which, in turn, may contribute to hip and spine instability and malfunction. Here, the effect of different mechanical properties of ligaments on lumbopelvic deformation is analyzed via the finite element method. First, the improved finite element model was validated using experimental data from previous studies and then used to calculate the sensitivity of lumbopelvic deformation to changes in ligament mechanical properties, load magnitude, and unilateral ligament resection. The deformation of the lumbopelvic complex relative to a given load was predominant in the medial plane. The effect of unilateral resection on deformation appeared to be counterintuitive, suggesting that ligaments have the ability to redistribute load and that they play an important role in the mechanics of the lumbopelvic complex.",

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AU - Henyš, Petr

AU - Ramezani, Maziar

AU - Schewitz, Daniel

AU - Höch, Andreas

AU - Möbius, Dustin

AU - Ondruschka, Benjamin

AU - Hammer, Niels

PY - 2022/10

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AB - The alteration in mechanical properties of posterior pelvis ligaments may cause a biased pelvis deformation which, in turn, may contribute to hip and spine instability and malfunction. Here, the effect of different mechanical properties of ligaments on lumbopelvic deformation is analyzed via the finite element method. First, the improved finite element model was validated using experimental data from previous studies and then used to calculate the sensitivity of lumbopelvic deformation to changes in ligament mechanical properties, load magnitude, and unilateral ligament resection. The deformation of the lumbopelvic complex relative to a given load was predominant in the medial plane. The effect of unilateral resection on deformation appeared to be counterintuitive, suggesting that ligaments have the ability to redistribute load and that they play an important role in the mechanics of the lumbopelvic complex.

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KW - finite element method

KW - hip–spine syndrome

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KW - sacroiliac joint

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Sacrospinous and sacrotuberous ligaments influence in pelvis kinematics

Abstract

Keywords

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