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Citation |
Stein G, Meyer C, Ingenhoff L, Bredow J, Müller LP, Eysel P, Schiffer G. Unfallchirurg 2016; 120(7): 590-594. |
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Vernacular Title |
Biomechanik der Hyperextensionsverletzung der subaxialen Halswirbelsäule. |
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Affiliation |
Abteilung Unfallchirurgie, Handchirurgie und Orthopädie, Vinzenz-Palotti-Hospital, Bergisch-Gladbach, Deutschland. |
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Copyright |
(Copyright © 2016, Holtzbrinck Springer Nature Publishing Group) |
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DOI |
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PMID |
27220520 |
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Abstract |
Hyperextension injuries of the subaxial cervical spine are potentially hazardous due to relevant destabilization. Depending on the clinical condition, neurologic or vascular damage may occur. Therefore an exact knowledge of the factors leading to destabilization is essential. In a biomechanical investigation, 10 fresh human cadaver cervical spine specimens were tested in a spine simulator. The tested segments were C4 to 7. In the first step, physiologic motion was investigated. Afterwards, the three steps of injury were dissection of the anterior longitudinal ligament, removal of the intervertebral disc/posterior longitudinal ligament, and dissection of the interspinous ligaments/ligamentum flavum. After each step, the mobility was determined. Regarding flexion and extension, an increase in motion of 8.36 % after the first step, 90.45 % after the second step, and 121.67 % after the last step was observed. Testing of lateral bending showed an increase of mobility of 7.88 %/27.48 %/33.23 %; axial rotation increased by 2.87 %/31.16 %/45.80 %. Isolated dissection of the anterior longitudinal ligament led to minor destabilization, whereas the intervertebral disc has to be seen as a major stabilizer of the cervical spine. Few finite-element studies showed comparable results. If a transfer to clinical use is undertaken, an isolated rupture of the anterior longitudinal ligament can be treated without surgical stabilization. Language: de |