Spinous process plate fixation for cervical spinal fusion after spinal trauma: two case reports

Posterior cervical fixation with various forms of instrumentation has been used for reconstruction in cases of traumatic disorders and degenerative or tumor-related dysfunction of the cervical spine. Recently, posterior plate and rod techniques using lateral mass screws or pedicle screws have been reported to show excellent fusion rates (Xu et al., 2010). Nevertheless, because such cervical spinal instrumentation requires screw anchorage, which may expose the vertebral artery or neural structures and cause neighboring lateral mass damage, they are not used by some surgeons (Mihara et al., 2001; Xu et al., 2010). A spinous process plate system, S-plate (Kisco Co., Ltd., Kobe, Japan), has been developed for short in situ fusions in selected patients. In this fixation procedure, the spinous processes are securely sandwiched between a pair of spiked plates, which are pressed together by tightening screws that extend through the plates (Neo et al., 2006). To our knowledge, only one report has described this cervical fixation technique, specifically as a salvage operation for failed anterior cervical fusion (Neo et al., 2006). In this letter, we report our experience applying spinous process plate systems as primary fixation devices for cervical spine trauma. An 86-year-old man showing a displaced left C6 facet fracture with dislocation and a C6 laminar fracture underwent posterior fusion and bone grafting using spinous process plates from C5 to C7. A 67-year-old man showing displacement of the C5 vertebral body with right facet fracture underwent posterior fusion and bone grafting using a spinous process plates from C5 to C6. Their postoperative courses were uneventful and follow-up computed tomography (CT) scans showed posterior bony fusion. This posterior fixation technique is safe and easy to perform for primary cervical fusion. Case 1: An 86-year-old man was admitted with neck pain and left arm numbness after falling from a tree. Neurological examination revealed no sensory or motor disturbance. A plain radiograph and computed tomography (CT) scan of the cervical spine showed a displaced C6 facet fracture with dislocation (Fig. ​(Fig.1a)1a) and a C6 laminar fracture. Magnetic resonance imaging (MRI) studies demonstrated no damage to the spinal cord or C5–6 vertebral discs. Surgery was performed two days after the fall. Posterior fusion using an S-plate was performed with local bone grafting. The screws of the S-plate were inserted through the spinous processes of C5, C6, and C7 (Fig. ​(Fig.1b).1b). The postoperative course was uneventful and no cervical brace was applied after surgery. Six months after the surgery, the patient had no symptoms and a CT scan showed posterior bony fusion (Fig. ​(Fig.1c1c). Fig. 1 CT scans and plain X-ray images of Case 1 Case 2: A 67-year-old man was admitted with neck pain after falling. He had no other complaints. Neurological examination revealed no sensory or motor disturbance. A CT scan and MRI of the cervical spine showed a displaced C5 vertebral body with a right facet fracture (Fig. ​(Fig.2a).2a). MRI studies indicated displacement of the C5 vertebral body with hematoma at the C5–6 level, which compressed the spinal cord (Fig. ​(Fig.2b).2b). Posterior fusion using an S-plate was performed with a local bone graft. The screws of the S-plate were inserted through the spinous processes of C5 and C6 (Fig. ​(Fig.2c).2c). The postoperative course was uneventful and no cervical brace was required after surgery. Nine months after surgery, the patient had no symptoms and a CT scan showed posterior bony fusion (Fig. ​(Fig.2d2d). Fig. 2 CT scans, magnetic resonance images, and plain X-ray images of Case 2 Both spinal instrumentation and surgical techniques have provided surgeons with expanding capabilities in spinal reconstruction and fixation. Traditionally, the Rogers technique (Camille et al., 1992), a simple wiring procedure involving the adjacent spinous process, has been widely used in trauma cases. This technique depends on spinous process bone strength for wire cutout resistance. More recently, posterior plating or rod techniques using lateral mass screws or pedicle screws have been reported with excellent fusion rates (Levine et al., 1992; Abumi et al., 1994; Abumi and Kaneda, 1997). However, there are potential risks associated with the screw misplacement, such as nerve root injury, vertebral artery injury, and neighboring lateral mass damage (Xu et al., 2010). An S-plate is simple to implant and there are no known risks of neurovascular injury. Furthermore, damage to the posterior soft tissue is reduced, compared with the lateral mass screw fixation (Neo et al., 2006). Mihara et al. (2001) compared the biomechanical properties of four posterior cervical fixation techniques: the Wavy Rod system, Rogers posterior wiring, Bohlman triple wiring, and lateral mass plate fixation. They concluded that the Wavy Rod system was the most effective of these techniques for stabilizing a cervical motion segment. Wang et al. (2006) biomechanically compared the SPIRE spinous process lumbar spinal stabilization plate with other posterior lumbar fixation methods. They concluded that the SPIRE plate effectively stabilized the lumbar spine, and the test results compared favorably with other fixation techniques. The Wavy Rod system and the SPIRE plate system are based on the same concept as the S-plate system, providing an alternative to the clinical use of traditional interspinous fixation techniques. The S-plate provides an attractive alternative to pedicle screws or lateral mass screws for selected patients requiring instrumentation-augmented fixation, while decreasing the common risk associated with screw misplacement in posterior plating or rod techniques. To our knowledge, only Neo et al. (2006) have described this fixation technique, used as a salvage operation for failed anterior cervical fusion. We believe that this technique is also a practical option for use in primary operations for cervical spinal trauma. In summary, we demonstrated the utilization of an S-plate for treating cervical spinal trauma for the first time. We believe that this posterior fixation technique is safe to perform. Furthermore, it may be applicable to primary cervical fusion as well as salvage operations.