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Classification systems provide a common language through which physicians and researchers can communicate. They can help create a framework for standardized treatment algorithms through which surgeons can directly and reproducibly contribute to improvements in patient outcomes. In order for these algorithms to be generalized to the population, they must be clinically relevant, reliable, and validated. If measurements are involved as part of the tool for outcome prediction, there must be a standardized way to obtain such data in an accurate way: whether that be through specific language to determine landmarks, image acquisition, imaging modalities, etc. This chapter will explore some of the more commonly used classification systems used in the subaxial cervical spine, specifically, within the domains of the traumatic, degenerative, and stenotic spine. It will also examine the literature for assessment of their reliability, validation and, if present, their clinical impact with focus on standard health-related quality of life (HRQOL) measures and surgeon expert opinion parameters thought to be relevant for evaluating and predicting outcomes.
Classification systems in the traumatic subaxial cervical spine encompass a broad spectrum of pathology. They can assist the provider in making a quick assessment of initial stability for emergency triage and ultimately, in working out a finalized treatment plan. This becomes critical for the patient when assessing initial neurologic injury, recovery potential, and surgical timing. Sadiqi et al. launched an international web-based survey to ascertain what parameters were thought to influence outcomes in patients with subaxial cervical spine trauma. They polled 279 AO Spine International and International Spinal Cord Society members and concluded that neurological status, implant failure within 3 months, and patient’s satisfaction were the most relevant parameters in the short and long term: bony fusion was the most relevant in the long term, and surgical site infection, spinal canal encroachment on advanced imaging, facet or lateral mass fracture on radiographs, and age were the most relevant in the short term. These parameters, along with HRQOL scores, will be the basis for examining clinical correlates for three of the most widely used classification systems for subaxial cervical spine trauma, the Allen and Ferguson Classification, the Subaxial Injury Classification and Severity Scale (SLICS), and the AO Spine Subaxial Cervical Spine Injury Classification System.
The Allen and Ferguson Classification, proposed in 1982, is regarded as one of the first broadly used classification systems for subaxial cervical spine trauma. It is based on the biomechanical concepts that allow the mechanism of injury to be deduced from radiographic patterns via “injury vectors.” The following injury mechanisms make up the schema and are derived from the major injury vector involved: vertical compression, compressive flexion, compressive extension, lateral flexion, distractive flexion, and distractive extension. These injury vectors have a magnitude and produce a spectrum of injury, which the authors have termed, a phylogeny. Each phylogeny is made up of stages that denote a specific type and degree of injury to a cervical motion segment, and it was noted by the authors that these stages correlated well with neurologic status. An important point to this system is that it assumes an indirect injury mechanism; the assumption is that a direct injury mechanism (i.e., blow to the neck, and penetrating projectile) is biomechanically different and often causes a much less predictable pattern of injury that cannot readily be deduced. The classification system is simplified in the following:
Vertical compression (VC): compressive loading of the entire vertebral centrum—as the severity of the vertebral body fracture increases, the incidence of vertebral arch fractures increases (16%, 25%, and 40% in stages 1, 2, and 3, respectively)
VC Stage 1: fracture of a superior or inferior endplate with a cupping deformity
VC Stage 2: fracture of both endplates with cupping. Sometimes associated with a nondisplaced or minimally displaced fracture through the centrum
VC Stage 3: fracture of both endplates with a fragmented centrum
Fragments are displaced peripherally and sometimes, into the neural canal
Compressive flexion (CF): anterior compression and burst fracture variants—the occurrence of multiple contiguous CF lesions suggests a greater magnitude of force imparted to the anterior elements
CF Stage 1: blunting of the anterior-superior vertebral margin to a rounded contour
CF Stage 2: CF 1 changes and obliquity of the anterior vertebral body with loss of height at the centrum. May see a fracture through the centrum
Resulting appearance is a “beaking” of the anterior-inferior vertebral body
CF Stage 3: CF 2 changes and a fracture line passing obliquely from the anterior surface of the vertebral body through the centrum and extending through the inferior subchondral plate
The “beak” in CF 2 is fractured
CF Stage 4: CF 3 changes and less than 3 mm of displacement of the inferior-posterior vertebral margin into the neural canal
CF Stage 5: CF 3 and gross displacement of the posterior portion of the vertebral body into the canal with signs of ligamentous failure
Separation of the articular facets and increased distance between the spinous processes at the injury level indicating failure of at least the posterior portion of the anterior ligamentous complex and entirety of the posterior ligamentous complex
Compressive extension (CE): posterior compression/vertebral arch injuries—the severity of anatomic damage does not correlate well with the severity of the spinal cord lesion
CE Stage 1: unilateral vertebral arch fracture with or without anterorotary vertebral body displacement
Linear fracture through the articular process, compression of the articular process, pedicle or lamina fracture, or a combination of the two
Rotary listhesis of the centrum may occur
CE Stage 2: Bilaminar fractures
Typically, at contiguous multiple levels
CE Stage 3: Bilateral vertebral arch fractures without displacement of the vertebral body
CE Stage 4: CE Stage 3 with partial vertebral body displacement anteriorly
CE Stage 3 and 4 are theoretical and were actually not encountered in this study
CE Stage 5: CE stage 3 with full vertebral body width displacement anteriorly
Ligamentous failure occurs posteriorly between the above and fractured vertebra and anteriorly between the fractured and lower vertebra
The anterior-superior portion of the centrum is characteristically sheared off by the anteriorly displaced centrum
Lateral flexion (LF): asymmetric lateral compression injury of the centrum and ipsilateral vertebral arch with distraction of the contralateral vertebral arch—sometimes associated with occult “kissing compressive lesions” of the uncovertebral joint
LF Stage 1: compression fracture on the centrum plus vertebral arch fracture on the ipsilateral side without displacement of the arch on the AP view
LF Stage 2: LF Stage 1 with displacement of the arch on the AP view or ligamentous failure on the contralateral side with separation of the articular processes
Both can occur simultaneously
Distractive flexion (DF): spectrum of facet-displacing injury patterns—the degree of ligamentous failure is sequentially greater in each subsequent stage and this correlates well with neurologic status
DF Stage 1: failure of the PLC as evidenced by subluxation of the facet in flexion with abnormally great divergence of the spinous processes at the injury level
Can see blunting of the anterior-superior margin of the vertebra similar to CF 1
DF Stage 2: unilateral facet dislocation
The range of ligamentous injury is variable and may require dynamic studies for full assessment
Facet subluxation on the opposite side of the dislocation would suggest severe ligamentous injury
DF Stage 3: Bilateral facet dislocation with approximately 50% anterior displacement of the vertebral body
DF Stage 4: DF Stage 3 with full vertebral body width displacement anteriorly or grossly unstable motion segment
Distractive extension (DE): anterior ligamentous failure with posterior vertebral displacement—frequently resulting from a fall and occurred more commonly in older age groups as compared to the other fractures and dislocations
DE Stage 1: failure of the anterior ligamentous complex or a transverse nondeforming fracture of the centrum
Abnormal widening of the disc space is a radiographic hint
DE Stage 2: DE Stage 1 with failure of the posterior ligamentous complex with displacement of the upper vertebral body posteriorly into the canal
This type of displacement tends to reduce when the head is in neutral so radiographic hints may be subtle (often less than 3 mm).
Reliability of the classification system was not discussed in the initial manuscript by Allen and Ferguson but was explored separately in the literature. In the landmark manuscript by Vaccaro et al., reliability was assessed, along with the SLICS and Harris Scores, via surveys after 2 rounds of case presentations given to 20 members of the Spine Trauma Study Group (STSG). Because the Allen and Ferguson Classification system is nonordinal, it could not be assessed with intraclass correlation coefficient (ICC)—instead, it was assessed with Cohen’s kappa coefficient (compares qualitative items). As compared to the SLICS and Harris classification systems, the interrater and intrarater reliability scores were highest in the Allen and Ferguson system (Intrarater reliability: AF [0.63], SLICS [0.60], and Harris [0.53]; Interrater reliability: AF [0.53], SLICS [0.51], and Harris [0.41]). Validation efforts were also made in the SLICS manuscript whereby the SLIC score and its recommendation to the participant’s management recommendation were compared; raters agreed with the SLIC score algorithm in 91.8% of cases. They also compared the SLIC morphology domain and the Ferguson and Allen description of morphology with 71.5% agreement between the two systems.
Stone et al. assessed the reliability of the Cervical Spine Injury Severity Score (CSISS), SLICS, and Allen and Ferguson Classifications and found mixed results compared to some of the previous literature. Their team found that ICC values for CSISS and SLICS suggested excellent interobserver reliability. The kappa coefficient for Allen-Ferguson, however, suggested moderate to poor reliability, particularly when assessing the 6 main groups and all 21 groups, respectively. Urrutia et al. showed similarly poor interobserver reliability but substantial intraobserver reliability.
There are no studies in the literature prospectively implementing the Allen and Ferguson Classification to assess patient outcomes. Instead, these concepts served as a steppingstone for the generation of subsequent subaxial cervical spine classification systems. Harris et al. would expand on these ideas to produce their own classification system in 1986 that was followed by the Magerl classification in 1994. These classification systems, while providing significant contributions to the language associated with classifying spine fractures, were unable to be reliably used or clinically validated in the literature.
The Subaxial Injury Classification Scale (SLICS, Fig. 1 ) is one of the most readily used classification systems in the traumatic subaxial cervical spine. Its development consisted of expert opinions of a subgroup within the Spine Trauma Study Group (STSG) and the amalgamation of a thorough literature review for cervical trauma with previously obtained surveys used to establish what was believed to be the most important characteristics for defining these injuries. These surveys, previously used for thoracolumbar injuries, were thus adapted based on the literature search and developed into the current subaxial classification system. It was developed for the purpose of categorizing injuries in a standardized way and, at the time of its development, was the only classification attempting to predict treatment.
This system uses three previously generated critical characteristics for clinical decision making that were also found to be appropriate for the subaxial cervical spine—injury morphology (based on column disruption), integrity of the disco-ligamentous complex (DLC), and patient’s neurologic status. These characteristics can all be determined by traditional radiographic studies such as X-ray, CT, and MRI imaging. Each component within the three domains is given a numerical value (with 0 being normal) in an ascending manner based on presumed severity of outcome and/or necessity for requiring surgery. The point totals in the three domains are added such that higher point totals assume a more severe injury. A score of less than 4 would recommend for nonoperative treatment while a score greater than 4 would recommend for surgical intervention. The classification system is simplified in the following:
Injury morphology
Compression (1 point): includes compression, burst, flexion/compression (teardrop), and nondisplaced/minimally displaced lateral mass and facet fractures. The latter two only included if there is no visible translation between vertebral levels noted
Burst patterns (2 points) are considered higher energy and therefore scored higher than traditional compression fractures
Distraction (3 points): includes anatomic dissociations in the vertical axis; hyperextension/hyperflexion injuries
Signifies a more severe injury pattern due to the force required to overcome the protective forces (i.e., facet capsule in flexion, anterior longitudinal ligament in extension)
Commonly involves ligamentous disruption traversing the disc space and facet joints, and therefore, MRI is useful for assessment
Translation/rotation (4 points): includes anatomic dissociations in the horizontal axis; unilateral/bilateral facet fracture-dislocations, fracture separation of the lateral mass, and bilateral pedicle fractures
A relative angulation of ≥ 11 degrees implies displacement exceeding physiologic ranges
DLC integrity
Components include the intervertebral disc, anterior/posterior longitudinal ligaments, ligamentum flavum, interspinous/supraspinous ligaments, and facet capsules
Indeterminant (1 point)
T2 MRI imaging showing only hyperintense signal
Isolated interspinous ligament widening
Indications of instability (2 points)
Abnormal facet alignment (articular apposition < 50% or diastasis > 2 mm through facet joint)
Abnormal widening of the disc space on either neutral or extension radiographs
Horizontal signal intensity on T2 sagittal MRI through a disc involving the nucleus and annulus
Subluxation of the vertebral bodies (i.e., translational/rotational abnormalities)
Neurologic status
Root (1 point) injury: implies lower energy mechanism and less likelihood for catastrophic neurologic disability
Incomplete (3 points) vs complete (2 points): thought to warrant surgical intervention in the setting of ongoing compressive phenomenon in order to provide the patient’s highest likelihood of improvement and therefore receives the highest score
Reliability was assessed via surveys after 2 rounds of case presentations given to 20 members of the STSG. Interrater and intrarater agreement were assessed by ICC scores of the morphology, DLC, and neurologic status, and compared with the same cases using the Allen and Ferguson and the Harris classifications. The interrater and intrarater reliability were variables among the three domains of the classification system; however, the overall reliability of the SLIC score was substantial with an interrater ICC of 0.71 and an intrarater ICC of 0.83. The interrater and intrarater reliability ICC for the SLIC management recommendations were moderate and substantial, respectively (ICC of 0.58 and 0.77). As compared to the other two aforementioned systems, the SLIC interrater and intrarater reliability scores were higher than the Harris system, but lower than the Ferguson and Allen system.
Validation of the system was determined by testing the assumption that SLICS would be able to morphologically characterize injuries and predict treatments and that the expert panel would gain consensus on treatment. This was done via internal testing by comparing the SLIC score and its recommendation to the participant’s management recommendation for the aforementioned cases. Raters agreed with the SLIC score management in 91.8% of cases. A comparison was also made between the SLIC morphology domain and the Ferguson and Allen description of morphology with 71.5% agreement between the two systems. The authors describe the reliability of this system as moderate and the validity as sufficient.
Separate external validation studies in the literature confer mostly positive results; however, there have been disagreements on the morphology domain of the system. Urrutia et al. published a study independently evaluating the reliability of the SLIC scale. They observed that the interobserver agreement was substantial when considering the main types and moderate when considering subtypes and the intraobserver agreement was substantial for both main and subtypes. Stone et al. and Lee et al., in separate studies, observed excellent and significant reliability, respectively. More recently, in a study published by van Middendorp et al., poor agreement on morphologic injury characteristics and no improvement in agreement among surgeons with the SLICS treatment algorithm were seen.
There is a paucity of literature attempting to ascertain outcomes based on the prospective application of the SLICS system. The first and only to do so was Joaquim et al. —in their study, they assessed neurologic status as the primary outcome of successful treatment; 48 patients were included. In the 23 patients treated nonoperatively (SLIC < 4), there was no neurological deterioration. There were 25 treated surgically (SLIC > 4); of those with incomplete deficits, 72% showed improvement in their American Spinal Injury Association (ASIA) score and no patient showed neurological worsening. As previously mentioned, neurologic status is one of the more relevant parameters in regard to short- and long-term outcome estimations. With these data in mind, the authors concluded that SLICS was both safe and efficacious in guiding surgical treatment for the parameter of neurologic status.
The information generated from the SLICS study was the spark for a plethora of new manuscripts with important clinical correlates. In one such study, Dvorak et al., using the SLICS scale as their basis, undertook a systematic review of the literature to create an evidence-based algorithm for subaxial cervical spine injury surgical approach; their approach algorithm was based on the three morphological domains of the SLICS study. The systematic review verified that for the burst morphology, an anterior approach w/ vertebral body resection and stabilization provides mechanical reconstitution of the motion segment, optimal decompression of the neural elements, and ample bone graft to reinforce the fusion. For distraction injuries, the surgical approach tends to be denoted by the pattern of DLC disruption—hyperextension injuries tend to be anterior and thus will require an anterior approach, hyperflexion injuries tend to be posterior, along with cases of severe spondylosis, DISH, or ankylosing spondylitis (these entities create long lever arms) and are thus best approached posteriorly. The exception to this rule is for facet subluxation, where the approach is determined based on disc herniation—posteriorly displaced disc herniation is preferentially treated anteriorly, if there is no disc herniation, the case can be approached via surgeon preference. Translational/rotational injuries are further subcategorized based on the presence of vertebral body fracture along with the presence and severity of neural compression. Facet-fracture dislocations associated with endplate fractures necessitate posterior fusion; if there is a concern for progressive kyphosis, significant discoligamentous injury on MRI, or severe comminuted fracture, then a combined approach is warranted. If there is no vertebral body fracture, the approach is determined by the presence of disc herniation, similarly to cases of facet subluxation (after attempted reduction).
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