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Whiplash-related injuries

This is an excerpt from Biomechanics of Injury-3rd Edition by Ronald F. Zernicke,Steven Broglio & William C. Whiting.

Of all cervical disorders, whiplash-­related injuries are among the most common and most misunderstood, ­because the term is used to describe both an injury mechanism (i.e., cervical acceleration–­deceleration) and a clinical syndrome.

Whiplash mechanics are complex and not well understood, but the Quebec Task Force on Whiplash-Associated Disorders defined whiplash as “an acceleration–­deceleration mechanism of energy transfer to the neck which may result from rear-­end or side impact, predominately in motor vehicle accidents, and from other mis­haps. The energy transfer may result in bony or soft tissue injuries (whiplash injury), which may in turn lead to a wide variety of clinical manifestations (whiplash-­associated disorders)” (Cassidy et al. 1995, p. 22).

In recent de­cades many studies have been conducted to determine the mechanisms of whiplash, which is typically characterized as involving a hyperextension mechanism. Using a motor vehicle crash as an example, the vehicle is violently pushed forward, accelerating the occupant’s trunk and shoulders anteriorly. The head remains stable (based on Newton’s first law), effectively forcing the neck into hyperextension. Once its inertia is overcome, the head is thrown (whiplashed) forward into flexion.

Modern research efforts have shown the hyperextension model to be too simplistic, inadequately describing the complex motion of the cervical spine during whiplash. “The critical revision brought about by modern research into whiplash is that it is not a cantilever movement that is injurious; i.e., it is not an extension–­flexion movement of the head, as was commonly believed previously. Rather, within less than 150 ms ­after impact, the cervical spine is compressed. During this period the cervical spine buckles; upper cervical segments are flexed while lower segments extend around abnormally located axes of rotation” (Bogduk and Yoganandan 2001, p. 272). The simultaneous upper cervical flexion and lower cervical extension results in an S-­shaped neck curvature within 75 ms of impact (figure 8.17), then gives way to a C-­shaped hyperextension curvature (Grauer et al. 1997). ­These motions place both the lower cervical spine and upper cervical spine at risk of injury from the rear-­impact mechanism (Panjabi, Pearson et al. 2004).

FIGURE 8.17 Neck curvature resulting from simultaneous upper cervical flexion and lower cervical extension.
FIGURE 8.17 Neck curvature resulting from simultaneous upper cervical flexion and lower cervical extension.

Although usually viewed as a sagittal plane injury caused by a rear-­end impact, whiplash can also result from lateral or frontal forces with their own unique injury pattern. In addition, motion of the neck is not confined to a single plane. If a driver is looking to the side at the moment of impact, for example, the injury mechanism involves a combination of hyperextension and rotation. In this case the pre-­impact rotation enhances the effect of the impact as the cervical structures are prestretched, which may enhance the injurious effect of the impact forces.

At first glance, whiplash might appear a ­simple injury mechanism. However, “in an individual accident ­there is likely to be a complex interaction between dif­fer­ent forces depending upon the speed and direction of impact and the attitude of the head and neck” (Barnsley et al. 1994, p. 288). In addition to the cervical musculature, spinous ligaments, intervertebral discs, vertebral bodies, and facet (zygapophyseal) joints, the brain and even the temporomandibular joint can be involved (e.g., Davis 2000; Ito et al. 2004; Panjabi, Ito et al. 2004; Pearson et al. 2004). Vari­ous mechanisms and potential injury sites are shown in figure 8.18. Whiplash-­associated disorders can manifest as both clinical and psychosocial symptoms (Eck et al. 2001). Pos­si­ble symptoms are listed in ­table 8.4.

FIGURE 8.18 Potential mechanisms and injury sites for whiplash-­related injuries. Shear forces affecting a spinal motion segment. (a) Translation of the superior vertebral body anteriorly relative to the inferior body, which stresses the articular surfaces of the zygapophyseal joint (A), the anterior annulus fibrosus (B), and the zygapophyseal joint capsule (C). (b) Translation of the superior vertebral body posteriorly relative to the inferior body, which stresses the intervertebral disc (D) and the zygapophyseal joint capsules (E). (c) Common lesions affecting the cervical spine following whiplash injury. A, articular pillar fracture; B, hemarthrosis (hemorrhage into a joint) of the zygapophyseal joint; C, rupture or tear of the zygapophyseal joint capsule; D, fracture of the subchondral plate; E, contusion of the intra-­articular meniscus of the zygapophyseal joint; F, fracture involving the articular surface; G, tear of the annulus fibrosus; H, tear of the anterior longitudinal ligament; I, end-­plate avulsion fracture; J, vertebral body fracture.
FIGURE 8.18 Potential mechanisms and injury sites for whiplash-­related injuries. Shear forces affecting a spinal motion segment. (a) Translation of the superior vertebral body anteriorly relative to the inferior body, which stresses the articular surfaces of the zygapophyseal joint (A), the anterior annulus fibrosus (B), and the zygapophyseal joint capsule (C). (b) Translation of the superior vertebral body posteriorly relative to the inferior body, which stresses the intervertebral disc (D) and the zygapophyseal joint capsules (E). (c) Common lesions affecting the cervical spine following whiplash injury. A, articular pillar fracture; B, hemarthrosis (hemorrhage into a joint) of the zygapophyseal joint; C, rupture or tear of the zygapophyseal joint capsule; D, fracture of the subchondral plate; E, contusion of the intra-­articular meniscus of the zygapophyseal joint; F, fracture involving the articular surface; G, tear of the annulus fibrosus; H, tear of the anterior longitudinal ligament; I, end-­plate avulsion fracture; J, vertebral body fracture.

From the clinical perspective, whiplash is categorized into five grades (Pastakia and Kumar 2011):

  • 0: No neck pain, stiffness, or physical signs
  • 1: Complaints of neck pain with stiffness or tenderness but no physical signs noted
  • 2: Neck pain and stiffness complaints with decreased range of motion and point tenderness
  • 3: Neck pain and stiffness complaints with neurological signs
  • 4: Neck pain and stiffness complaints with fracture, dislocation, or spinal cord injury
More Excerpts From Biomechanics of Injury 3rd Edition

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