Coordination Between Trunk Muscles, Thoracolumbar Fascia, and Intra-Abdominal Pressure Toward Static Spine Stability

Study Design. Numerical in-silico human spine stability finite element analysis. Objective. The purpose of this study was to investigate the contribution of major torso tissues toward static spine stability, mainly the thoracolumbar fascia (TLF), abdominal wall with its intra-abdominal pressure (IAP), and spinal muscles inclusive of their intramuscular pressure. Summary of Background Data. Given the numerous redundancies involved in the spine, current methodologies for assessing static spinal stability are limited to specific tissues and could lead to inconclusive results. A three-dimensional finite element model of the spine, with structured analysis of major torso tissues, allows for objective investigation of static spine stability. Methods. A novel previously fully validated spine model was employed. Major torso tissues, mainly the muscles, TLF, and IAP were individually, and in combinations, activated under a 350N external spine perturbation. The stability contribution exerted by these tissues, or their ability to restore the spine to the unperturbed position, was assessed in different case-scenarios. Results. Individual activations recorded significantly different stability contributions, with the highest being the TLF at 75%. Combined or synergistic activations showed an increase of up to 93% stability contribution when all tissues were simultaneously activated with a corresponding decrease in the tensile load exerted by the tissues themselves. Conclusion. This investigation demonstrated torso tissues exhibiting different roles toward static spine stability. The TLF appeared able to dissipate and absorb excessive loads, the muscles acted as antagonistic to external perturbations, and the IAP played a role limiting movement. Furthermore, the different combinations explored suggested an optimized engagement and coordination between different tissues to achieve a specific task, while minimizing individual work.

Automated summary

This study investigated the contribution of major torso tissues, including the thoracolumbar fascia, abdominal wall, and spinal muscles, to static spine stability using numerical in-silico analysis. The results showed that the different tissues exhibited different roles in spine stability, with the thoracolumbar fascia dissipating excessive loads, the muscles acting antagonistically to external perturbations, and the intra-abdominal pressure limiting movement. Different combinations of tissue activations were also explored, showing the importance of optimized engagement and coordination between different tissues to achieve a specific task while minimizing individual work.