Kinematics of the thoracic spine in trunk lateral bending: in vivo three-dimensional analysis |
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| Authors: | Takahito Fujimori Motoki Iwasaki Yukitaka Nagamoto Yohei Matsuo Takahiro Ishii Tsuyoshi Sugiura Masafumi Kashii Tsuyoshi Murase Kazuomi Sugamoto Hideki Yoshikawa |
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| Affiliation: | 1. Laboratory of Anatomy, Biomechanics and Organogenesis, Université Libre de Bruxelles, Bruxelles, Belgium;2. Laboratory of Functional Anatomy, Université Libre de Bruxelles, Bruxelles, Belgium;3. Laboratory of Manual Therapy, Université Libre de Bruxelles, Bruxelles, Belgium;4. Department of Applied Mathematics, State Polytechnical University (SPbSPU), Saint Petersburg, Russia;1. Student, Institute of Medical Engineering & Medical Physics, Cardiff School of Engineering, Cardiff University, Cardiff, UK;2. Physiotherapy Specialist, Ministry of Health, Riyadh, Kingdom of Saudi Arabia;3. Senior Lecturer, Cardiff University, Institute of Medical Engineering & Medical Physics, Cardiff School of Engineering, Cardiff University, Cardiff, UK;4. Lecturer, Cardiff University, Institute of Medical Engineering & Medical Physics, Cardiff School of Engineering, Cardiff University, Cardiff, UK;5. Senior Lecturer, Faculty of Health and Social Sciences, Bournemouth University, Dorset, UK;1. Yangzhi Rehabilitation Hospital, Sunshine Rehabilitation Centre, Tongji University School of Medicine, Shanghai 201619, China;2. Department of Rehabilitation Sciences, Tongji University School of Medicine, Shanghai 200092, China;3. Sport and Health Research Center, Physical Education Department, Tongji University, Shanghai 200092, China;4. Baoshan Branch, Shuguang Hospital Affiliated to Shanghai University of TCM, Shanghai, China;5. Department of Biomedical Engineering, The Hong Kong Polytechnic University, Hong Kong, China |
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| Abstract: | Background contextIn vivo three-dimensional kinematics of the thoracic spine in trunk lateral bending with an intact rib cage and soft tissues has not been well documented. There is no quantitative data in the literature for lateral bending in consecutive thoracic spinal segments, and there has not been consensus on the patterns of coupled motion with lateral bending.PurposeTo demonstrate segmental ranges of motion (ROMs) in lateral bending and coupled motions of the thoracic spine.Study designIn vivo three-dimensional biomechanics study of the thoracic spine.Patient sampleFifteen healthy male volunteers.Outcome measuresComputed analysis by using voxel-based registration.MethodsParticipants underwent computed tomography of the thoracic spine in three supine positions: neutral, right maximum lateral bending, and left maximum lateral bending. The relative motions of vertebrae were calculated by automatically superimposing an image of vertebrae in a neutral position over images in bending positions, using voxel-based registration. Mean values of lateral bending were compared among the upper (T1–T2 to T3–T4), the middle-upper (T4–T5 to T6–T7), the middle-lower (T7–T8 to T9–T10), and the lower (T10–T11 to T12–L1) parts of the spine.ResultsAt lateral bending, the mean ROM (±standard deviation) of T1 with respect to L1 was 15.6°±6.3° for lateral bending and 6.2°±4.8° for coupled axial rotation in the same direction as lateral bending. The mean lateral bending of each spinal segment with respect to the inferior adjacent vertebra was 1.4°±1.3° at T1–T2, 1.3°±1.2° at T2–T3, 1.4°±1.3° at T3–T4, 0.9°±0.9° at T4–T5, 0.8°±1.0° at T5–T6, 1.1°±1.1° at T6–T7, 1.7°±1.2° at T7–T8, 1.3°±1.2° at T8–T9, 1.6°±0.7° at T9–T10, 1.8°±0.8° at T10–T11, 2.3°±1.0° at T11–T12, and 2.2°±0.8° at T12–L1. The smallest and the largest amounts of lateral bending were observed in the middle-upper and the lower parts, respectively. There was no significant difference in lateral bending between the upper and the middle-lower parts. Coupled axial rotation of each segment was generally observed in the same direction as lateral bending. However, high variability was found at the T2–T3 to T5–T6 segments. Coupled flexion was observed at the upper and middle parts, and coupled extension was observed at the lower part.ConclusionsThis study revealed in vivo three-dimensional motions of consecutive thoracic spinal segments in trunk lateral bending. The thoracolumbar segments significantly contributed to lateral bending. Coupled axial rotation generally occurred in the same direction with lateral bending. However, more variability was observed in the direction of coupled axial rotation at T2–T3 to T5–T6 segments in the supine position. These results are useful for understanding normal kinematics of the thoracic spine. |
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| Keywords: | Thoracic spine Biomechanics Scoliosis Lateral bending Coupled motion In vivo three-dimensional |
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