Assessment of spinal and pelvic kinematics using inertial measurement units in clinical subgroups of persistent non-specific low back pain
Assessment of spinal and pelvic kinematics using inertial measurement units in clinical subgroups of persistent non-specific low back pain
Inertial measurement units (IMUs) offer a portable and quantitative solution for clinical movement analysis. However, their application in non-specific low back pain (NSLBP) remains underexplored. This study compared the spine and pelvis kinematics obtained from IMUs between individuals with and without NSLBP and across clinical subgroups of NSLBP. A total of 81 participants with NSLBP with flexion (FP; n = 38) and extension (EP; n = 43) motor control impairment and 26 controls (No-NSLBP) completed 10 repetitions of spine movements (flexion, extension, lateral flexion). IMUs were placed on the sacrum, fourth and second lumbar vertebrae, and seventh cervical vertebra to measure inclination at the pelvis, lower (LLx) and upper (ULx) lumbar spine, and lower cervical spine (LCx), respectively. At each location, the range of movement (ROM) was quantified as the range of IMU orientation in the primary plane of movement. The ROM was compared between NSLBP and No-NSLBP using unpaired t-tests and across FP-NSLBP, EP-NSLBP, and No-NSLBP subgroups using one-way ANOVA. Individuals with NSLBP exhibited a smaller ROM at the ULx (p = 0.005), LLx (p = 0.003) and LCx (p = 0.01) during forward flexion, smaller ROM at the LLx during extension (p = 0.03), and a smaller ROM at the pelvis during lateral flexion (p = 0.003). Those in the EP-NSLBP group had smaller ROM than those in the No-NSLBP group at LLx during forward flexion (Bonferroni-corrected p = 0.005), extension (p = 0.013), and lateral flexion (p = 0.038), and a smaller ROM at the pelvis during lateral flexion (p = 0.005). Those in the FP-NSLBP subgroup had smaller ROM than those in the No-NSLBP group at the ULx during forward flexion (p = 0.024). IMUs detected variations in kinematics at the trunk, lumbar spine, and pelvis among individuals with and without NSLBP and across clinical NSLBP subgroups during flexion, extension, and lateral flexion. These findings consistently point to reduced ROM in NSLBP. The identified subgroup differences highlight the potential of IMU for assessing spinal and pelvic kinematics in these clinically verified subgroups of NSLBP.
Sheeran, Liba
ad753e79-56c8-483f-aae5-dd992496bee2
Al-Amri, Mohammad
0b2232da-149d-49cc-8259-030cf1ad88ec
Sparkes, Valerie
7ddd0ce0-29db-4fdf-8a6c-140352979eb6
Davies, Jennifer L.
184a996c-bacc-4545-be0c-266179597d41
26 March 2024
Sheeran, Liba
ad753e79-56c8-483f-aae5-dd992496bee2
Al-Amri, Mohammad
0b2232da-149d-49cc-8259-030cf1ad88ec
Sparkes, Valerie
7ddd0ce0-29db-4fdf-8a6c-140352979eb6
Davies, Jennifer L.
184a996c-bacc-4545-be0c-266179597d41
Sheeran, Liba, Al-Amri, Mohammad, Sparkes, Valerie and Davies, Jennifer L.
(2024)
Assessment of spinal and pelvic kinematics using inertial measurement units in clinical subgroups of persistent non-specific low back pain.
Sensors, 24 (7), [2127].
(doi:10.3390/S24072127).
Abstract
Inertial measurement units (IMUs) offer a portable and quantitative solution for clinical movement analysis. However, their application in non-specific low back pain (NSLBP) remains underexplored. This study compared the spine and pelvis kinematics obtained from IMUs between individuals with and without NSLBP and across clinical subgroups of NSLBP. A total of 81 participants with NSLBP with flexion (FP; n = 38) and extension (EP; n = 43) motor control impairment and 26 controls (No-NSLBP) completed 10 repetitions of spine movements (flexion, extension, lateral flexion). IMUs were placed on the sacrum, fourth and second lumbar vertebrae, and seventh cervical vertebra to measure inclination at the pelvis, lower (LLx) and upper (ULx) lumbar spine, and lower cervical spine (LCx), respectively. At each location, the range of movement (ROM) was quantified as the range of IMU orientation in the primary plane of movement. The ROM was compared between NSLBP and No-NSLBP using unpaired t-tests and across FP-NSLBP, EP-NSLBP, and No-NSLBP subgroups using one-way ANOVA. Individuals with NSLBP exhibited a smaller ROM at the ULx (p = 0.005), LLx (p = 0.003) and LCx (p = 0.01) during forward flexion, smaller ROM at the LLx during extension (p = 0.03), and a smaller ROM at the pelvis during lateral flexion (p = 0.003). Those in the EP-NSLBP group had smaller ROM than those in the No-NSLBP group at LLx during forward flexion (Bonferroni-corrected p = 0.005), extension (p = 0.013), and lateral flexion (p = 0.038), and a smaller ROM at the pelvis during lateral flexion (p = 0.005). Those in the FP-NSLBP subgroup had smaller ROM than those in the No-NSLBP group at the ULx during forward flexion (p = 0.024). IMUs detected variations in kinematics at the trunk, lumbar spine, and pelvis among individuals with and without NSLBP and across clinical NSLBP subgroups during flexion, extension, and lateral flexion. These findings consistently point to reduced ROM in NSLBP. The identified subgroup differences highlight the potential of IMU for assessing spinal and pelvic kinematics in these clinically verified subgroups of NSLBP.
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Accepted/In Press date: 15 March 2024
Published date: 26 March 2024
Identifiers
Local EPrints ID: 501573
URI: http://eprints.soton.ac.uk/id/eprint/501573
ISSN: 1424-8220
PURE UUID: 4f86416a-a031-440b-9c44-b88e1c6f3379
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Date deposited: 03 Jun 2025 17:12
Last modified: 16 Aug 2025 02:17
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Contributors
Author:
Liba Sheeran
Author:
Mohammad Al-Amri
Author:
Valerie Sparkes
Author:
Jennifer L. Davies
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