A rig for in vitro testing of the lumbar spine and pelvis simulating posterior, anterior and oblique trunk muscles

Georg Matziolis¹, Leah Bergner², Harun Hawi², Leandra Bauer³, Matthias Woiczinski³, Patrick Strube², Sophia Vogt²

Affiliations

¹ Orthopaedic Department, University Hospital Jena, Friedrich-Schiller-University Jena, Campus Eisenberg, Klosterlausnitzer Straße 81, 07607, Eisenberg, Germany. g.matziolis@waldkliniken-eisenberg.de.
² Orthopaedic Department, University Hospital Jena, Friedrich-Schiller-University Jena, Campus Eisenberg, Klosterlausnitzer Straße 81, 07607, Eisenberg, Germany.
³ Experimental Orthopaedics, University Hospital Jena, Friedrich-Schiller-University Jena, Campus Eisenberg, Eisenberg, Germany.

PMID: 40102515
PMCID: PMC11920589
DOI: 10.1038/s41598-025-93599-w

A rig for in vitro testing of the lumbar spine and pelvis simulating posterior, anterior and oblique trunk muscles

Georg Matziolis et al. Sci Rep. 2025.

. 2025 Mar 18;15(1):9377.

doi: 10.1038/s41598-025-93599-w.

Authors

Georg Matziolis¹, Leah Bergner², Harun Hawi², Leandra Bauer³, Matthias Woiczinski³, Patrick Strube², Sophia Vogt²

Affiliations

¹ Orthopaedic Department, University Hospital Jena, Friedrich-Schiller-University Jena, Campus Eisenberg, Klosterlausnitzer Straße 81, 07607, Eisenberg, Germany. g.matziolis@waldkliniken-eisenberg.de.
² Orthopaedic Department, University Hospital Jena, Friedrich-Schiller-University Jena, Campus Eisenberg, Klosterlausnitzer Straße 81, 07607, Eisenberg, Germany.
³ Experimental Orthopaedics, University Hospital Jena, Friedrich-Schiller-University Jena, Campus Eisenberg, Eisenberg, Germany.

PMID: 40102515
PMCID: PMC11920589
DOI: 10.1038/s41598-025-93599-w

Abstract

Numerous research questions require in vitro testing on lumbar spine and pelvis specimens. The majority of test setups apply forces and torques via the uppermost vertebral body with the lowermost vertebral body fixed and have been validated for kinematics and intradiscal pressure. Models without simulation of muscle traction may produce valid data only for testing conditions for which they have been validated. In vitro test setups with simulation of muscle traction would appear to be useful for conditions beyond such conditions. The aim of the present study was to describe and validate a test rig for the lumbar spine that applies the forces directly to the vertebral bodies via artificial muscle attachments and thus includes the stabilising effects of the muscles known from the literature. The artificial muscle attachments were chosen to get a stable fixation of the pulleys on the cadaver. The location of force application was as close as possible to the physiological footprint of the muscle on the bone. Three paired muscles were combined by individual linear actuators and simulated under force control (posterior, anterior and oblique trunk muscles). An optical 3D motion capture system (GOM, Zeiss, Germany) was used to measure the reposition of the entire lumbar spine and the sacrum against the ilium. At the same time, the force applied to all simulated muscles was recorded. All muscle attachments could be loaded up to a maximum force of 1 kN without failure. The following reposition of the lumbar spine could be generated by the simulated muscle traction keeping the force below each muscle's individual strength: extension 18°, flexion 27°, lateral bending 33°, axial rotation 11°. The effects on lumbar spine reposition of the individual trunk muscles differed depending on the direction of movement. The anterior trunk muscles were the most acting for flexion/extension, at 0.16 ± 0.06°/N, while the oblique trunk muscles were the most acting for lateral bending (0.17 ± 0.16°/N) and axial rotation (0.10 ± 0.14°/N). The maximum nutation of the sacroiliac joint (SIJ) was on average 1,2° ± 0,2°. The artificial muscle attachments to the vertebral bodies proved to be withstand physiologically occurring forces. The range of motion generated in the test rig was physiological. The SIJ nutation determined and the direction of action of the muscle groups correspond to literature data. The order of the individual muscle effects on lumbar spine reposition corresponds to the distance between the muscle insertions and the physiological centre of rotation. In conclusion, taking into account the limitations, the lumbar spine test rig presented here allows the analysis of movements of the lumbar spine and pelvis resulting directly from simulated muscle tractions and thus enables a test environment close to in vivo conditions.

Keywords: Biomechanics; Lumbar spine; Rig; Trunk muscles.

PubMed Disclaimer

Conflict of interest statement

Declarations. Competing interests: The authors declare no competing interests.

Figures

**Fig. 1**
Reversed setup of the pelvis and lumbar spine with the anatomical inferior part being superior and vice versa. T12 was moulded in resin and fixed to a solid base.

**Fig. 2**
The anterior trunk actors were attached through a hollow cylinder in the anterior part of the vertebra, the posterior trunk actors were attached through eyelets at pedicle screws [(A) draft, (B) photograph with sawbone].

**Fig. 3**
The aponeurosis of the oblique trunk muscles at the anterior vertebrae was simulated by passing a through all vertebral bodies in eight tours. A flexible wire was attached to the centre of this construction [(A) draft]. The pulley simulating the posterior trunk actors was placed through eylets that were fixated to pedicle screws [(B) photograph with sawbone].

**Fig. 4**
Anterior view of the setup [(A) draft, (B) photograph]. The femoral attachment of the m. psoas major was simulated by the sleeve of the Bowden cable that was fixed to the right and left acetabulum at the level of the lesser trochanter.

**Fig. 5**
Side view of the setup [(A) draft, (B) photograph]. The anterior trunk muscles were simulated by a flexible wire cable, which was guided via pulleys at the level of the costal arch. In the pelvic region, the wire cables were attached at the level of the pubic bone.

**Fig. 6**
Direction of motion of the sacroiliac joint (SIJ).

See this image and copyright information in PMC

References

1. Beckmann, A. et al. A new in vitro spine test rig to track multiple vertebral motions under physiological conditions. Biomed. Eng. Biomed. Tech.63, 341–347 (2018). - PubMed
1. Beckmann, A. et al. Biomechanical testing of a polycarbonate-urethane-based dynamic instrumentation system under physiological conditions. Clin. Biomech.61, 112–119 (2019). - PubMed
1. Herren, C. et al. Biomechanical testing of a PEEK-based dynamic instrumentation device in a lumbar spine model. Clin. Biomech.44, 67–74 (2017). - PubMed
1. Yamamoto, I., Panjabi, M. M., Oxland, T. R. & Crisco, J. J. The role of the iliolumbar ligament in the lumbosacral junction. Spine15, 1138–1141 (1990). - PubMed
1. Oakland, R. J., Furtado, N. R., Wilcox, R. K., Timothy, J. & Hall, R. M. The biomechanical effectiveness of prophylactic vertebroplasty: a dynamic cadaveric study: Laboratory investigation. J. Neurosurg. Spine8, 442–449 (2008). - PubMed

MeSH terms

Actions
Actions
Actions
Actions
Actions
Actions

LinkOut - more resources

Full Text Sources
- Nature Publishing Group
- PubMed Central

Save citation to file

Email citation

Add to Collections

Add to My Bibliography

Your saved search

Create a file for external citation management software

Your RSS Feed

A rig for in vitro testing of the lumbar spine and pelvis simulating posterior, anterior and oblique trunk muscles

Affiliations

A rig for in vitro testing of the lumbar spine and pelvis simulating posterior, anterior and oblique trunk muscles

Authors

Affiliations

Abstract

Conflict of interest statement

Figures

References

MeSH terms

LinkOut - more resources

Full Text Sources