Identification of damping and stiffness parameters of cervical and lumbar spines of supine humans under vertical whole-body vibration

Qiao, Guandong; Rahmatalla, Salam

doi:10.1177/1461348419837031

Cited by 10 publications

(1 citation statement)

References 35 publications

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“…In the current research there is no existing direct way to measure biomechanical properties such as stiffness and damping of the screw inserted in a human spine in vivo. In the most cases, those parameters are inferred using pullout experiments on cadaver or animal vertebrae [25][26][27]. A few approaches that apply optimization methods are proposed in the literature to identify the stiffness and damping values for the various spinal flexible structures [28,29].…”

Section: Introductionmentioning

confidence: 99%

Can a Priori Unknown Values of Biomechanical Parameters Be Determined with Sufficient Accuracy in Mbs Using Sensitivity Analysis? Analyzing the Interaction Characteristics between Cervical Vertebra and Pedicle Screw

Kramer¹,

Bauer²

2022

Preprint

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Finite element (FE) modeling is commonly used as a method to investigate the influence of medical devices, such as implants and screws and their effects on the biomechanical behavior of the spine. Another simulation method is a multi-body simulation (MBS), where the model is composed of several non-deformable bodies. MBS solvers generally require a very short computing time for dynamic tasks compared to an FE analysis. Considering this computational advantage, in this study, we examine whether parameters whose values are not known a priory can be determined with sufficient accuracy using MBS model. Therefore, we propose a Many-at-a-time sensitivity analysis method that allows approximating these a priory unknown parameters without requiring long simulation times. This method enables a high degree of MBS model optimization to be achieved in an iterative process. The sensitivity analysis method is applied to a simplified screw-vertebra model, consisting of an anterior anchor implant screw and vertebral body of C4. An experiment described in the literature is used as a basis for developing and assessing the potential of the method for sensitivity analysis and to validate the models action. The optimal model parameters for the MBS model were determined to be c=823224N/m for stiffness and d=488Ns/m for damping. The presented method of parameter identification can be used in studies including more complex MBS spine models or to set initial parameter values that are not available as initial values for FE models.

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Section: Introductionmentioning

confidence: 99%