Abstract
Background context High-energy impacts are commonly encountered during sports such as rugby union. Although catastrophic injuries resulting from such impacts are rare, the consequences can be devastating for all those involved. A greater level of understanding of cervical spine injury mechanisms is required, with the ultimate aim of minimizing such injuries. Purpose The present study aimed to provide a greater understanding of cervical spine injury mechanisms, by subjecting porcine spinal specimens to impact conditions based on those measured in vivo. The impacts were investigated using high-speed digital image correlation (DIC), a method not previously adopted for spinal impact research. Study design This was an in vitro biomechanical study. Methods Eight porcine specimens were impacted using a custom-made rig. The cranial and caudal axial loads were measured at 1 MHz. Video data were captured with two cameras at 4 kHz, providing measurements of the three-dimensional deformation and surface strain field of the specimens using DIC. Results The injuries induced on the specimens were similar to those observed clinically. The mean±standard deviation peak caudal load was 6.0±2.1 kN, which occurred 5.6±1.1 ms after impact. Damage observable with the video data occurred in six specimens, 5.4±1.1 ms after impact, and the peak surface strain at fracture initiation was 4.6±0.5%. Conclusions This study has provided an unprecedented insight into the injury mechanisms of the cervical spine during impact loading. The posture represents a key factor in injury initiation, with lordosis of the spine increasing the likelihood of injury.
Original language | English |
---|---|
Pages (from-to) | 1856-1863 |
Number of pages | 8 |
Journal | Spine Journal |
Volume | 15 |
Issue number | 8 |
DOIs | |
Publication status | Published - 1 Aug 2015 |
Externally published | Yes |
Bibliographical note
Funding Information:The authors would like to thank the Rugby Football Union and the Injured Players Foundation for their ongoing support with this research.
Funding Information:
Author disclosures: TPH: Grant: RFU Injured Players Foundation (D), Technology Strategy Board and Concept Spine Limited (D). DC: Grant: RFU Injured Players Foundation (D). EP: Grant: RFU Injured Players Foundation (Nonfinancial). GT: Grant: RFU Injured Players Foundation (Nonfinancial), Rugby Football Union (F), International Rugby Board (G), Private Physiotherapy Education Fund (D). AWM: Grant: RFU Injured Players Foundation (Nonfinancial), Technology Strategy Board and Concept Spine Limited (B). HSG: Grant: RFU Injured Players Foundation (Nonfinancial). SG: Grant: RFU Injured Players Foundation (Nonfinancial).
Funding Information:
The study was funded through an institutional grant from the Rugby Football Union Injured Players Foundation .
Publisher Copyright:
© 2015 Elsevier Inc. All rights reserved.