Improvement and validation of a female finite element model of the cervical spine

Although the cervical spine supports and controls the kinematics of the head, it is vulnerable to injuries during mechanical loading. Severe injuries often result in damage to the spinal cord, leading to significant ramifications. The role of gender in determining the outcome of such injuries has been established as significant. In order to better understand the essential mechanics and develop treatments or preventative measures, various forms of research have been conducted. Computational modelling is one of the most useful and extensively utilised methods, as it provides information that would otherwise be difficult to obtain. As such, the primary goal of this research is to create a new finite element of the female cervical spine that will more accurately represent the group most affected by such injuries. This work is a continuation of a previous study where a model was created from the computer tomography scans of a 46-year-old female. A functioning spinal unit consisting of the C6-C7 segment was simulated as a validation procedure. The experimental data obtained from cadaveric specimens, that assessed the range of motion of different cervical segments in flexion-extension, axial rotation, and lateral bending, was used to validate the reduced model.

Automated summary

The aim of this research is to create a finite element model that accurately represents the female cervical spine in order to better understand its mechanics and develop treatments or preventative measures. This study builds upon a previous research where a model was created from CT scans of a 46-year-old female and simulated a functioning spinal unit for validation. The reduced model was validated using experimental data from cadaveric specimens assessing the range of motion of different cervical segments in various movements.