Biomechanical study of the C5–C8 cervical extraforaminal ligaments

• Main Authors: Qinghao Zhao, Yemei Yang, Penghuan Wu, Chengyan Huang, Rusen Zhang, Qingchu Li, Benchao Shi
• Format: Article
• Language: English
• Published: BMC 2020-10-01
• Series: Journal of Orthopaedic Surgery and Research
• Subjects: Cervical; Intervertebral foramina; Clinical anatomy; Extraforaminal ligaments; Biomechanical; Abduction injury
• Online Access: http://link.springer.com/article/10.1186/s13018-020-02006-9

Abstract Background The anatomical distribution of the extraforaminal ligaments in the cervical intervertebral foramina has been well studied. However, detailed descriptions of the biomechanical characteristics of these ligaments are lacking. Methods The paravertebral muscles were dissected, and the extraforaminal ligaments and nerve roots were identified. The C5 and C7 or C6 and C8 cervical nerve roots on both sides were randomly selected, and a window was opened on the vertebral lamina to expose the posterior spinal nerve root segments. Five needles were placed on the nerve root and the bone structure around the intervertebral foramen; the distal end of the nerve root was then tied with silk thread, and the weights were connected across the pulley. A weight load was gradually applied to the nerve root (50 g/time, 60 times in total). At the end of the experiment, segments of the extraforaminal ligaments were selectively cut off to compare the changes in nerve root displacement. Results The displacement of the C5, C6, C7, and C8 nerve roots increases with an increasing traction load, and the rate of change of nerve root displacement in the intervertebral foramen is smaller than that in the nerve root on the outside area (p < 0.05). Extraforaminal ligaments can absorb part of the pulling load of the nerve root; the C5 nerve root has the largest load range. Conclusions Cervical extraforaminal ligaments can disperse the tension load on the nerve root and play a role in protecting the nerve root. The protective effect of the C5 nerve root was the strongest, and this may anatomically explain why the C5 nerve roots are less prone to simple avulsion.