Biomechanical modelling of impact-related fracture characteristics and injury patterns of the cervical spine associated with riding accidents

S Y Jauch; S Wallstabe; K Sellenschloh; D Rundt; K Püschel; M M Morlock; N M Meenen; G Huber

doi:10.1016/j.clinbiomech.2015.06.011

Biomechanical modelling of impact-related fracture characteristics and injury patterns of the cervical spine associated with riding accidents

Standard

Biomechanical modelling of impact-related fracture characteristics and injury patterns of the cervical spine associated with riding accidents. / Jauch, S Y; Wallstabe, S; Sellenschloh, K; Rundt, D; Püschel, K; Morlock, M M; Meenen, N M; Huber, G.

in: CLIN BIOMECH, Jahrgang 30, Nr. 8, 10.2015, S. 795-801.

Publikationen: SCORING: Beitrag in Fachzeitschrift/Zeitung › SCORING: Zeitschriftenaufsatz › Forschung › Begutachtung

Harvard

Jauch, SY, Wallstabe, S, Sellenschloh, K, Rundt, D, Püschel, K, Morlock, MM, Meenen, NM & Huber, G 2015, 'Biomechanical modelling of impact-related fracture characteristics and injury patterns of the cervical spine associated with riding accidents', CLIN BIOMECH, Jg. 30, Nr. 8, S. 795-801. https://doi.org/10.1016/j.clinbiomech.2015.06.011

APA

Jauch, S. Y., Wallstabe, S., Sellenschloh, K., Rundt, D., Püschel, K., Morlock, M. M., Meenen, N. M., & Huber, G. (2015). Biomechanical modelling of impact-related fracture characteristics and injury patterns of the cervical spine associated with riding accidents. CLIN BIOMECH, 30(8), 795-801. https://doi.org/10.1016/j.clinbiomech.2015.06.011

Vancouver

Jauch SY, Wallstabe S, Sellenschloh K, Rundt D, Püschel K, Morlock MM et al. Biomechanical modelling of impact-related fracture characteristics and injury patterns of the cervical spine associated with riding accidents. CLIN BIOMECH. 2015 Okt;30(8):795-801. https://doi.org/10.1016/j.clinbiomech.2015.06.011

Bibtex

@article{174492ddfff94cef98e7ab3fce76be56,

title = "Biomechanical modelling of impact-related fracture characteristics and injury patterns of the cervical spine associated with riding accidents",

abstract = "BACKGROUND: Horse-related injuries are manifold and can involve the upper and lower limbs, the trunk, spine or head. Cervical spine injuries are not among the most common injuries. However, they can be fatal and often result in neurological symptoms. This study investigated the influence of the posture of the cervical spine on the ultimate strength and the pattern of vertebrae failure with the aim to provide some guidance for protective clothing design.METHODS: Eighteen human cervical spines, each divided into two specimens (three vertebrae each), were subjected to a simulator test designed to mimic a spinal trauma in different postures of the specimen (neutral, flexion, extension). The stress-to-failure, the deformation at the time of fracture and the fracture patterns assessed based on CT scans were analysed.FINDINGS: Stress-to-failure of the superior specimens was lower for the flexion group compared to the others (P=0.027). The superior specimens demonstrated higher stress-to-failure in comparison to the inferior specimens (P<0.001). Compression in a neutral or flexed position generated mild or moderate fracture patterns. On the contrary, the placement of the spine in extension resulted in severe fractures mostly associated with narrowing of the spinal canal.INTERPRETATION: The results imply that a neutral cervical spine position during an impaction can be beneficial. In this position, the failure loads are high, and even if a vertebral fracture occurs, the generated injury patterns are expected to be mild or moderate.",

author = "Jauch, {S Y} and S Wallstabe and K Sellenschloh and D Rundt and K P{\"u}schel and Morlock, {M M} and Meenen, {N M} and G Huber",

year = "2015",

month = oct,

doi = "10.1016/j.clinbiomech.2015.06.011",

language = "English",

volume = "30",

pages = "795--801",

journal = "CLIN BIOMECH",

issn = "0268-0033",

publisher = "Elsevier Limited",

number = "8",

}

RIS

TY - JOUR

T1 - Biomechanical modelling of impact-related fracture characteristics and injury patterns of the cervical spine associated with riding accidents

AU - Jauch, S Y

AU - Wallstabe, S

AU - Sellenschloh, K

AU - Rundt, D

AU - Püschel, K

AU - Morlock, M M

AU - Meenen, N M

AU - Huber, G

PY - 2015/10

Y1 - 2015/10

N2 - BACKGROUND: Horse-related injuries are manifold and can involve the upper and lower limbs, the trunk, spine or head. Cervical spine injuries are not among the most common injuries. However, they can be fatal and often result in neurological symptoms. This study investigated the influence of the posture of the cervical spine on the ultimate strength and the pattern of vertebrae failure with the aim to provide some guidance for protective clothing design.METHODS: Eighteen human cervical spines, each divided into two specimens (three vertebrae each), were subjected to a simulator test designed to mimic a spinal trauma in different postures of the specimen (neutral, flexion, extension). The stress-to-failure, the deformation at the time of fracture and the fracture patterns assessed based on CT scans were analysed.FINDINGS: Stress-to-failure of the superior specimens was lower for the flexion group compared to the others (P=0.027). The superior specimens demonstrated higher stress-to-failure in comparison to the inferior specimens (P<0.001). Compression in a neutral or flexed position generated mild or moderate fracture patterns. On the contrary, the placement of the spine in extension resulted in severe fractures mostly associated with narrowing of the spinal canal.INTERPRETATION: The results imply that a neutral cervical spine position during an impaction can be beneficial. In this position, the failure loads are high, and even if a vertebral fracture occurs, the generated injury patterns are expected to be mild or moderate.

AB - BACKGROUND: Horse-related injuries are manifold and can involve the upper and lower limbs, the trunk, spine or head. Cervical spine injuries are not among the most common injuries. However, they can be fatal and often result in neurological symptoms. This study investigated the influence of the posture of the cervical spine on the ultimate strength and the pattern of vertebrae failure with the aim to provide some guidance for protective clothing design.METHODS: Eighteen human cervical spines, each divided into two specimens (three vertebrae each), were subjected to a simulator test designed to mimic a spinal trauma in different postures of the specimen (neutral, flexion, extension). The stress-to-failure, the deformation at the time of fracture and the fracture patterns assessed based on CT scans were analysed.FINDINGS: Stress-to-failure of the superior specimens was lower for the flexion group compared to the others (P=0.027). The superior specimens demonstrated higher stress-to-failure in comparison to the inferior specimens (P<0.001). Compression in a neutral or flexed position generated mild or moderate fracture patterns. On the contrary, the placement of the spine in extension resulted in severe fractures mostly associated with narrowing of the spinal canal.INTERPRETATION: The results imply that a neutral cervical spine position during an impaction can be beneficial. In this position, the failure loads are high, and even if a vertebral fracture occurs, the generated injury patterns are expected to be mild or moderate.

U2 - 10.1016/j.clinbiomech.2015.06.011

DO - 10.1016/j.clinbiomech.2015.06.011

M3 - SCORING: Journal article

C2 - 26160273

VL - 30

SP - 795

EP - 801

JO - CLIN BIOMECH

JF - CLIN BIOMECH

SN - 0268-0033

IS - 8

ER -