Management of cervical spine trauma in children

One of the largest epidemiological studies of trauma in children in the USA assessed the National Pediatric Trauma Registry over a consecutive 10-year period and identified that from 75,172 injured children, only 1.5% had a cervical spine injury (1098 patients) [1]. The study found that upper cervical spine injuries were prevalent among all age groups (42% in those aged ≤ 8 years; 58%, aged > 8 years), whereas lower cervical spine injuries were more common in older children (85% occurring in those aged > 8 years) [1]. Indeed, younger children often sustain injuries in the upper portion of the cervical spine because the relative size of the head compared to the rest of the body is greater in this age group. As the child grows, this pattern evolves into that more commonly seen in adults, where injury to the lower cervical spine is far more common. Mortality was 33% in those with an upper cervical spine injury, versus 8.3% in lower cervical spine injury [1]. As with adults, males show a greater propensity to suffering cervical spine injury than females, at a ratio of 1.5–2.1:1 [2].

Blunt trauma is the commonest cause of cervical spine injury, attributing to 95% of injuries, commonly as a result of motor vehicle accidents (61%). Of these incidents, 68.9% were passengers in the motor vehicle, 22.9% were pedestrians and 8.2% were bicycling when the accident occurred [1]. Falls were a greater cause of injury in the younger group (18% in those aged ≤ 8 years; 11%, aged > 8 years) [1]. Sports related injuries were far more common in the older group (3% in those aged ≤ 8 years; 20%, aged > 8 years) [1]. The possibility of non-accidental injury should always be considered by the attending clinician, especially in the younger age group.

In neonates, it is estimated that one in 60,000 births are complicated by spinal cord injury [3]. Maternal risk factors include a small pelvis, obesity, diabetes and primiparity [4]. Risk factors related to the foetus include abnormal position of the neonate during delivery, prolonged delivery, the use of forceps to aid delivery and shoulder dystocia. Brachial plexus injury is far more common than spinal injury and can affect the upper (C5/6) or lower (C7/T1) nerves causing Erb’s or Klumpke’s palsy, respectively. Although fortunately rare, damage to the cervical spine itself can lead to respiratory compromise (due to paralysis of the respiratory musculature and/or phrenic nerve injury) and hypotonia with a flaccid paraplegia or quadriplegia [4]. Indeed, this may prove fatal [5].

One of the most important differences between the vertebral column of children and adults is its intrinsic elastic properties. This elasticity may cause immediate self-reduction following dislocation during injury. This may be partly responsible for the often-normal bony alignment when radiography and computed tomography (CT) are performed upon initial work-up. In fact, children are more likely to suffer ligamentous damage than adults and the syndrome of spinal cord injury without radiological abnormality (SCIWORA) has been coined to classify these types of non-bony injuries where no injury is found on X Ray/CT scans [6]. Indeed, spinal cord injury occurs in approximately 35% of cervical spine injury and approximately half of these cases demonstrate no radiological sign of bony injury [1].

The inherent elasticity of the cervical spine is, in part, due to the shallow and horizontally oriented facet joints which allow increased range of flexion and extension. Moreover, ligaments can stretch farther without suffering damage. Hook-shaped uncinate processes from C3 to T1 act to prevent spondylolisthesis and limit lateral flexion in the adult. However, these are underdeveloped in the child and so render the cervical spine more flexible. Supporting musculature is also underdeveloped and this may represent another important factor. The larger head in relation to the body acts to increase moment force through the upper cervical spine and increases the risk of injury at the fulcrum, which lies at C2–3 in infants. As the child grows, the fulcrum descends to the adult position at C5–6 [7].

The Advanced Trauma Life Support (ATLS®) principles apply to immediate management of a child with cervical spinal injury. Immobilisation in a neutral position should be performed at the scene of the accident and this is maintained until the child can be fully assessed in the emergency department. Immobilisation prevents the scenario in which instability is initially overlooked and neurological deficit progresses during transfer of the child as a result. Traditionally, as per adults, children with suspected cervical spine injuries have been placed on a spinal board and a rigid cervical collar applied, with sandbags or blocks either side of the head and tape to secure and immobilise the head [8]. However, rigid collars often fit children poorly, especially in the very young. Moreover, children may be agitated and in pain, making application of the collar difficult and potentially dangerous. The safest approach is a pragmatic one, allowing the child to find a comfortable position and providing manual in-line stabilisation initially. If a properly sized collar can be safely fitted, then this is appropriate at this stage; if not, then simply maintaining a neutral or comfortable position with blocks/rolled up towels placed either side of the head and tape to secure them in place is appropriate. This approach has been advocated by NICE and the advanced paediatric life support course [9, 10]. It is important to also be aware that a cervical collar may potentiate atlanto-occipital distraction and worsen neurological injury in such cases. Therefore, if this pattern of injury is suspected then sandbags and tape only should be used [11]. As the young child’s head is proportionally much larger in comparison to his/her body when compared to an adult, when lying flat on a spinal board the head is forced into a slight degree of flexion. Therefore, an occipital recess or thoracic elevation may be necessary to counteract this effect [12].

Damage to the cervical spine should be considered in the presence of suspicious injury, unconsciousness, torticollis, rigidity of the cervical musculature, significant neck pain, or neurological signs/symptoms that may be either transient or permanent (radiculopathy/myelopathy depending on pattern of injury). Children are less likely to suffer from neurological injury than adults in the presence of trauma, and incomplete spinal cord injuries (SCI) are more common (75% incomplete versus 25% complete) [1]. Complete spinal cord injury, with loss of motor and sensory function below the level of injury, is often irreversible and leads to devastating consequences.

If a spinal cord injury is present, damage is termed primary or secondary. Primary injury is sustained at the time of trauma due to mechanical insult and is irreversible. Secondary injury is sustained after the incident and one of the greatest contributors to this is cord hypoperfusion. Thus, preventing hypotension to prevent cord ischaemia is paramount during the resuscitation phase. Appropriate organ support in an intensive/high dependency care setting is mandatory in the subsequent phase of management. A detailed examination must be performed so that patients with SCI can be stratified as per the American Spinal Injury Association (ASIA) impairment scale to properly determine the extent of the injury (http://​asia-spinalinjury.​org/​wp-content/​uploads/​2016/​02/​International_​Stds_​Diagram_​Worksheet.​pdf).

Neuroprotective therapies have been sought in an attempt to prevent secondary damage in acute SCI, which is thought to be (in part) caused by cord oedema and inflammatory processes consequent to the initial injury. The use of methylprednisolone has been particularly controversial. It was popularised following the publication of the National Acute Spinal Cord Injury Surveys (NASCIS) II and III in the 1990s, which showed a beneficial effect in SCI if given within 8 h of injury [13, 14]. However, these studies only assessed patients over 13 years of age. Moreover, since publication of this data, re-analysis and other studies have demonstrated that the adverse effects of steroids may outweigh any benefit [15]. Based on this, the Congress of Neurological Surgeons changed their stance on this subject in their most recent guidelines (2013), stating that methylprednisolone should not be used routinely in spinal cord injuries [16]. Other authors have challenged this stance, stating that the current evidence available can be used neither recommend, nor to refute the use of methylprednisolone [17]. They state that the decision should be made on a case-by-case basis, and advocate that methylprednisolone may be especially effective in cervical spinal cord injuries undergoing decompression [17]. This ongoing controversy highlights the need for further high quality randomised control trials to further assess the clinical use of steroids in spinal cord injuries. GM-1 ganglioside, an anti-excitotoxic compound, was another drug that showed promise in early studies; however, a large multicentre randomised control trial showed no difference in neurological outcome and so again, current guidelines do not recommend its use [16, 18]. Hypothermia has also been used to mitigate the effects of inflammation on the spinal cord with promising improvements in neurological outcome in animal and small human studies. Nevertheless, there remains a need for high quality evidence to determine whether the benefits will outweigh the risks of this therapy [19]. Further research continues desperately to elucidate a potential therapy that might improve the long-term prognosis in spinal cord injuries.

With regard to surgical intervention, decompression attempts to reduce secondary damage following SCI that is attributable to oedema and ischaemia. Experimental studies have shown beneficial effects in outcomes of in vivo animal models of SCI. Decompression is usually performed alongside stabilisation in patients with incomplete SCIs with extrinsic compression. The timing of surgical intervention is controversial, with a paucity of level I evidence. Whilst theoretical and experimental animal studies suggest early intervention would benefit, clinical studies have yet to prove this. Current expert opinion suggests the optimal time-frame for operative intervention is 8–24 h [20]. Such early intervention allows shorter periods of hospitalisation and earlier mobilisation, which may reduce the morbidity associated with prolonged bed-rest and hastens the commencement of post-injury rehabilitation.

Normal variants in imaging of the child’s cervical spine may be confused for pathology. Moreover, there are key differences to assessment of cervical spine imaging in the adult patient. Although beyond the scope of the article to review all of these differences in detail, we highlight some of the important features. A good understanding of the embryology and paediatric cervical spine anatomy is necessary and early consultation with a specialist radiologist is a vital part of management of these children.

Prevertebral soft tissue thickening indicates injury in adults, but may occur during expiration or flexion of the neck in children and is especially prominent in the crying child [28]. If repeat radiography when the child settles is impossible then CT may be necessary.

Loss of cervical lordosis is an often-normal variant in children but may also result from cervical musculature spasm. The ossified portions of the cervical vertebrae are more spherical at birth and with age develop into their rectangular adult shape. Thus, young children may have a normal ‘wedge-appearance’ mimicking anterior wedge fractures seen in adults [29].

Moreover, measurements used for radiological diagnosis in adults are different in children due to anatomical differences described above. For example, the atlantodental interval (ADI), used to determine atlanto-occipital dislocation, is > 3 mm in adults and > 5 mm in children.

Pseudosubluxation (especially at C2–3) may be noted on imaging due to the elasticity of the cervical spine (Fig. 1). The amount of subluxation is usually < 2 mm. The spinolaminar line should not be disrupted. Also the Swischuk line (drawn from the anterior aspect of the posterior arches of C1 down to C3) should be assessed. The line is usually < 1 mm anterior to the posterior arch of C2 and if the line is > 2 mm from that anterior aspect of the arch of C2 then pseudosubluxation is unlikely and assessment for dislocation should be performed (MRI is particularly useful here in determining ligamentous injury) [26].

Synchondroses (the temporary epiphyseal growth plates that allow development of bony structures between ossification centres) may be mistaken for fractures on imaging (Fig. 2a–c). The location and appearance of synchondroses are predictable, and in most cases are symmetrical. It can be helpful to review imaging from a patient of a similar age to help determine normal anatomy. However, fractures may occur through synchondroses. When they do, they tend to fuse well and reduction and external immobilisation is the recommended treatment. Internal surgical fixation is attempted only if the fracture persists despite conservative treatment.

This syndrome was first described by Pang et al. in [6] as “objective signs of myelopathy resulting from trauma, with no evidence of ligamentous injury or fractures on plain radiographs or tomographic studies”. Advances in radiology have since found that upon performing MRI, soft tissue injuries are identified, including: ligamentous damage, disc herniation, small end-plate fractures and splitting of the hypervascular growth zone from the vertebral end-plate. Some patients with features of SCIWORA have very subtle findings on MRI and indeed the extent of injury on MRI often correlates with prognosis (Fig. 6).

SCIWORA is more common in younger children and tends to occur in the upper cervical spine. After the age of 9 it is rarely noted in the upper cervical spine but remains a cause of injury in the lower cervical spinal cord up to the age of 16 [5]. Prognosis is better in the older children with lower cervical spine involvement [5].

The mechanism involved in this injury pattern is flexion–extension. Flexion can rupture the anterior longitudinal ligament which allows intervertebral displacement that reduces spontaneously due to the elasticity of the structures in children. As such, no abnormality is initially picked up on radiography or computed tomography. Extension causes buckling of the ligamentum flavum, which in turn compresses the spinal cord. The pattern of subsequent spinal cord injury may be complete transection, a partial cord syndrome, a central cord syndrome or a Brown–Séquard syndrome. One systematic review of all paediatric cases of SCIWORA found that of 433 reported cases, 87.2% affected the cervical region [7]. Of these, 263 had sufficient information to determine presenting ASIA score; 69.6% were ASIA D, 7.6% ASIA C, 5.3% ASIA B and 17.5% ASIA A. Those presenting with ASIA A showed no recovery. Those presenting with ASIA B had a 21.4% rate of complete recovery, those presenting with ASIA C had a 35% rate of complete recovery and those presenting with ASIA D had a 97.3% rate of complete recovery [7].

SCIWORA is traditionally treated by external immobilisation for up to 3 months, to allow the tissues to heal. Some authors advocate a shorter period of external immobilisation in cases of SCIWORA that do not involve neural tissue damage on MRI [5]. Children should be encouraged to refrain from activities that may predispose to further trauma to the cervical spine for at least 6 months [46]. On follow-up, repeat imaging should be performed at 3 months or prior to the removal of the cervical collar, This is done by trained practitioners using flexion–extension radiographs to ensure that there are no features of late instability. Repeat magnetic resonance imaging is only necessary in the event of a novel or evolving neurological deficit during flexion/extension imaging or the following removal of the collar.

Owing to its intrinsic elasticity, the cervical spine of a child is more difficult to immobilise than that of an adult. External fixation may be achieved to some degree with a rigid collar. However, some rotation still occurs and full stability, especially in the upper and middle cervical spines, is not achieved. The halo device for external fixation is useful in adults, but in children, the same approach is often problematic. The shallower nature of the child’s skull may make pin fixation more prone to complications (e.g. pin site infection, pin loosening, dural penetration, supra-orbital nerve injury and scarring) [47]. Furthermore, the biopsychosocial effect of being confined within the halo system cannot be underestimated. Importantly, the device impairs the child’s ability to recover physically and mentally from the injury. The Minerva body jacket obviates the use of pins, negating these potential complications. It has been shown to be as effective as the halo in stabilisation of the mid to lower portion of the cervical spine but is not as effective in stabilising upper cervical spine injuries [48].

Internal (surgical) fixation is necessary in some cases to provide stability and to protect the spinal cord from damage. Indications include non-reducible deformities, unstable injuries requiring stabilisation, progressive deformity, and decompression of neural structures [5]. Whilst the principles of internal fixation remain the same in adults as in children, there are specific considerations. The potential growth of the spine needs to be taken into consideration as instrumentation can inhibit future growth and affect the curvature of the spine. Growth is driven at the vertebral body endplates in the anterior column of the cervical spine. By 10 years, the cervical vertebrae are near adult size and surgical intervention is less likely to have a significant impact on children as they continue to grow. Post-operatively, children must be carefully followed up to assess for any complications. Long-term follow-up is vital in the younger patients whose spine continues to grow as instrumentation may lead to deformity and hinder normal development.