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BACKGROUND CONTEXT: The loss of spinal mobility remains one of the most debilitating consequences of axial spondyloarthritis (axSpA). Despite therapeutic advancements, many patients still have limited mobility. Structural damage is a recognized contributor, but the role of paraspinal muscle properties in determining spinal mobility is less studied. PURPOSE: To evaluate the relative contribution of structural damage and paraspinal muscle mechanical properties to cervical and lumbar spinal mobility in axSpA patients. STUDY DESIGN/SETTING: Cross-sectional observational study. PATIENT SAMPLE: A total of 98 axSpA patients from the Córdoba axSpA Task Force Registry and Outcomes (CASTRO) who met ASAS criteria. OUTCOME MEASURES: Cervical and lumbar range of motion; paraspinal muscle stiffness and elasticity parameters. METHODS: Spinal mobility in the cervical and lumbar regions was measured in three planes using inertial measurement units. Paraspinal muscle stiffness and muscle elasticity (logarithmic decrement) were quantified with the MyotonPRO device. Structural damage was assessed with the modified Stoke Ankylosing Spondylitis Spinal Score (mSASSS). Associations between structural damage, muscle properties, and mobility were explored using generalized linear models adjusted for age, sex, body mass index, and C-reactive protein. A sensitivity exploratory analysis was conducted using Gradient Boosting Machine models. RESULTS: Structural damage, as quantified by mSASSS, was significantly associated with impaired spinal mobility. In adjusted generalized linear models, both structural damage and paraspinal muscle properties, including muscle stiffness and reduced elasticity (higher decrement), were independently associated with decreased range of motion, most notably in the cervical spine. Gradient Boosting Machine models supported these findings, with Shapley additive explanations values consistently identifying mSASSS, stiffness, and elasticity among the top predictors of mobility outcomes. CONCLUSIONS: Structural damage and paraspinal muscle properties were independently associated with reduced spinal mobility in axSpA. Digital tools such as inertial measurement units and MyotonPRO may support objective functional assessment and targeted rehabilitation strategies. However, the cross-sectional design limits conclusions regarding temporal relationships.
Moldovan et al. (Wed,) studied this question.