Abstract
BackgroundLumbar facet joints (LFJs) are usually related to the pathogenesis of the spine. The purpose of this paper is to study the effects of lifting load on the motion of lower lumbar facet joints in vivo.MethodsTen healthy volunteers aged 25 ≤ 39 years, 5 males and 5 females, were recruited. Using a dual fluoroscopy imaging system (DFIS) combined with CT, firstly, the L3-S1 segment image scanned by CT was converted into a three-dimensional model. Then, the lumbar motion images of L3-S1 vertebrae taken by the DFIS under different loads (0 kg, 5 kg, 10 kg) and different body postures (maximum flexion and extension, maximum left and right bending, and maximum left and right torsion) were captured. Finally, in the Rhino software, the instantaneous motion state of the lumbar spine is reproduced by translation and rotation according to the anatomical structure of the lumbar spine and the previous images. With the help of computer software, a Cartesian coordinate system was placed in the center of each articular surface to measure the kinematics of the articular process and to obtain 6DOF data under different loads (0 kg, 5 kg, 10 kg) in the lumbar facet joints. ResultsIn the flexion and extension of the trunk, weight bearing reduced the translational range in the mid-lateral direction. In the L3/4 segment, the lateral translational range of the left and right facet joints gradually decreased with increasing load, and the translational range at 0 kg was significantly greater than that at 10 kg (left side: 0 kg, 0.86° ± 0.57°, 10 kg, 0.24° ± 0.26°, p = 0.01; right side: 0 kg, 0.86° ± 0.59°, 10 kg, 0.26° ± 0.27°, p = 0.01). In the L5/S1 segment, the translation range of the LFJ at 0 kg was significantly greater than that at 10 kg (p = 0.02). Other bending and rotation movements were not found to cause differential changes in the 6DOF of the LFJ. In bending, the rotation range was the largest in the L3/4 segment (p < 0.05) and gradually decreased from top to bottom. At the same level, there were significant differences in the translation range of the left and right facets in the anterior posterior and craniocaudal directions (p < 0.05).ConclusionIncreasing the load has a significant impact on the coupled translational movement of lumbar facet joints. The asymmetric translational movement of the left and right facet joints may be a factor that accelerates the degeneration of facet joints.
Highlights
Facet joints play an important role in the stability and movement of the entire spine [1]
A literature review shows that data reports on the motion patterns of lumbar facet joints are mainly based on cadaver models [3], animal models [9, 10], computed tomography (CT) [11,12,13] and magnetic resonance imaging (MRI) [14] had been gradually applied to describe the morphology of the lumbar spine and the classification of osteoarthritis
The average rotation ranges of L3/4, L4/5 and L5/ S1 levels under load were 2.72° ± 2.45° to 3.58° ± 2.73°, 2.58° ± 1.81° to 3.59° ± 2.68°, and 2.16° ± 1.63° to 2.72° ± 2.45°, respectively
Summary
Facet joints play an important role in the stability and movement of the entire spine [1]. Wen et al Journal of Orthopaedic Surgery and Research (2022) 17:114 facet joint osteoarthritis is considered the main cause of chronic low back pain in 15–45% of patients [4,5,6]. A literature review shows that data reports on the motion patterns of lumbar facet joints are mainly based on cadaver models [3], animal models [9, 10], computed tomography (CT) [11,12,13] and magnetic resonance imaging (MRI) [14] had been gradually applied to describe the morphology of the lumbar spine and the classification of osteoarthritis. The purpose of this paper is to study the effects of lifting load on the motion of lower lumbar facet joints in vivo
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