A biomechanical analysis of four anterior cervical techniques to treating multilevel cervical spondylotic myelopathy: a finite element study

Multilevel cervical spondylotic myelopathy (MCSM) refers to cervical spondylosis diagnosed by imaging with three or more levels of contiguous or noncontiguous cervical intervertebral disc degeneration and secondary changes, which causes compression on the dural sac and spinal cord, and which results in corresponding clinical manifestations. Owing to severe spinal cord compression in most cases, MCSM often requires surgery to relieve the compression. Consensus has currently been reached on the surgical management of CSM involving one or two mobile segments; however, controversy remains regarding the selection of surgical procedures for treatment of MCSM [1‐3].

An anterior, posterior, or combined anterior-posterior approach can be employed according to the clinical situation and the experience of surgeons, and each approach has its unique advantages and disadvantages [3‐12]. The anterior techniques such as multilevel anterior cervical discectomy and fusion (mACDF), anterior cervical corpectomy and fusion (ACCF), and hybrid decompression and fusion (HDF) have been proved to be reliable and effective in spinal cord decompression, and sagittal alignment restoration and maintenance thus achieved a good clinical outcome. To increase the stability of cervical vertebrae and the fusion rate of bone graft after surgery, anterior cervical titanium plate fixation is widely used. Nevertheless, the anterior titanium plate protrudes from the anterior margin of the cervical vertebral body, causing relatively strong friction with soft tissue in the anterior cervical region. As a result, complications such as foreign body sensation in the anterior cervical region, dysphagia, and esophageal injury have been found after long-term follow-up [13‐15]. Meanwhile, some researchers argue that the use of anterior cervical titanium plate increases the incidence of adjacent segment degeneration (ASD) [16‐18].

To prevent complications associated with anterior cervical titanium plates and maintain the benefits of interbody cages with anterior plating system, a new zero-profile, stand-alone device (Fidji cervical cage, Abbott Spine, Bordeaux, France) has been designed and used clinically [19]. In recent years, we performed mACDF using Fidji cervical cages alone (mACDF-CA) for the treatment of MCSM. In these studies, we found that mACDF-CA was associated with shorter operation time, less blood loss and cost of index surgery, and lower dysphagia incidence, and satisfactory results were achieved in preliminary clinical applications [8, 9, 20]. Despite these findings, biomechanical studies assessing anterior techniques for the treatment of MCSM appear only rarely in the literature, and no one compares mACDF-CA to other anterior techniques in multilevel constructs. A biomechanical study using finite element (FE) analysis can help to elucidate the complex biomechanical properties of the cervical spine, including stresses, strains, and loads under different conditions [21‐23]. This study was a biomechanical comparative analysis of four anterior cervical techniques based on FE model. The biomechanical characteristics of the intervertebral discs at the adjacent segments and internal fixation were analyzed to provide scientific experimental evidence for surgical treatment of MCSM.

2Cervical spondylosis is a common disease in middle-aged and older people, for which surgery is a major treatment. Anterior cervical decompression and bone graft fusion is considered the standard surgical procedure for one- or two-level cervical spondylosis. However, for multilevel (three or more level) cervical spondylosis, controversy remains over the surgical approach [3‐10]. As the etiological factors of MCSM usually arise from anterior degenerated intervertebral discs and osteophytes, it is challenging to remove the anterior compressive material through a simple posterior surgery, which cannot achieve effective decompression. Furthermore, posterior surgery cannot fully restore the physiological curvature of the cervical spine. Therefore, many researchers choose anterior surgery rather than posterior surgery [34]. More often than not, multiple levels are involved and complicate the surgical management. Anterior, posterior, and circumferential procedures have all been advocated. Even when the discussion is limited to anterior procedures, there is no agreement as to which reconstruction technique is best after multilevel anterior cervical decompression [1, 3, 4, 8, 9, 11, 16, 34‐40].

Anterior surgical approaches mainly include ACCF, ACDF, and HDF. Among the several anterior surgical approaches for MCSM, each has advantages and disadvantages [1‐4, 8, 9, 11, 16, 34‐45]. In conventional ACDF surgery, osteophytes and degenerated intervertebral discs are removed from the posterior upper and lower margins of the vertebral body through an intervertebral space approach. This approach effectively removes the direct compression factors and provides good stability as well as multipoint expansion for better recovery and preservation of the physiological curvature of the cervical spine. Therefore, this approach is especially suitable for patients with straight or kyphotic curvature of the cervical spine [11, 35, 46]. However, this surgery involves a long operation time, has a limited field of view, and requires high surgical skills, making it difficult to ensure complete decompression in most cases [13‐15].

ACCF involves long-segment decompression with slotting followed by long titanium mesh or autogenous bone grafting. The advantage of this approach is that it can be performed under direct vision, with a wider intraoperative view and larger operative field, and that it allows more extensive and thorough decompression [10, 37, 39, 41‐43, 47, 48]. The resected vertebral body can be used as a bone autograft, thus preventing the risk associated with bone allografts and complications, such as pain in the bone removal area. Moreover, the size of the graft–host bone interface requiring postoperative healing is reduced compared with that in ACDF, which is beneficial to improve the fusion rate after surgery. The disadvantage of ACCF is that it results in considerable damage to the structural stability of the anterior and middle columns [1, 4, 8, 16, 35, 49]. Furthermore, iliac bone autografts collapse easily, and may become displaced or form a false joint. Long titanium mesh or fibular autografts are not conducive to restoring physiological lordosis of the cervical spine. In addition, owing to the multiple fixed segments and long moment arm, the monocortically-fixed screws at both ends of the titanium plate bear considerable stress, which may lead to postoperative complications, such as loosening and displacement. If the implanted bone is too long, surgical difficulty increases. Moreover, the fusion rate of long-segment bone grafting is substantially reduced, and the complication rate increases. ACCF surgery is mainly suitable for cases with lesions extending to the posterior vertebral body, extensive and severe osteophyte formation and vertebral body deformity in the anterior spinal cord, and contiguous stenosis of adjacent intervertebral spaces causing spinal cord compression.

Another anterior surgical approach is HDF, namely ACCF combined with ACDF [3, 12]. Generally, the most severely compressed vertebral body is removed in HDF, and discectomy is performed only at the less compressed sites, which reduces the number of resected vertebral bodies. While achieving full decompression, this approach also reduces damage to the anterior vertebral column, which shortens the length of the bone graft, reduces the graft–host bone interface, and theoretically, lowers the probability of upper false joint formation. However, this approach is also associated with loss of cervical lordosis and bone graft–titanium plant-related complications.

Anterior titanium plating is required with conventional mACDF, ACCF, and HDF to treat MCSM. The application of an anterior locking titanium plate can effectively improve the stability and firmness of the fused cervical spine and greatly increase the fusion rate. In addition, using a plate prevents loss of intervertebral height, while the physiological curvature of the cervical spine is maintained, to some extent. However, with increasing plate length, stress at the plate–screw interface increases correspondingly, which increases the risk of implant loosening, displacement, and fracture. Moreover, following the application of a long-segment titanium plate, patients are prone to foreign body sensation, dysphagia, and even esophageal fistula, while the incidence of ASD is also increased [13‐18]. In the present study, our biomechanical results showed that among the three surgical models involving titanium plate fixation (mACDF, ACCF, and HDF groups), the ACCF group had the highest stress at the plate–screw interface, the HDF group had higher stress than the mACDF group, and the mACDF group had the lowest stress. These results revealed that the risk of titanium plate or screw loosening, displacement, and fracture was the highest following ACCF, which is similar to clinical results. Furthermore, we found that stress in the intervertebral fusion cage also differed substantially between the mACDF and mACDF-CA groups. The mACDF-CA group showed markedly higher stress than the mACDF group, which may indicate a higher risk of fusion cage subsidence in the mACDF-CA group compared with the mACDF group. However, this speculation must be verified with long-term follow-up results from controlled clinical trials with large sample sizes.

To overcome the problems associated with anterior cervical titanium plating, a novel intervertebral fusion system that integrates support, fixation, and fusion; does not protrude from the anterior margin of the vertebral body; and effectively reduces surgical complications has been designed and applied clinically. This system can be independently applied in ACDF surgery without requiring anterior titanium plate fixation. The system highlights establishing cervical stability while minimizing interference with adjacent tissues by the implant, and considerably reduces the incidence and severity of associated complications after surgery. The system has achieved satisfactory results in its preliminary clinical applications [9, 19, 20, 50‐54]. The currently available self-stabilizing zero-profile anterior cervical interbody fusion and internal fixation systems are the Zero-P system (Synthes, Switzerland) and the Fidji cage system (Zimmer, France). Strong evidence from basic research and clinical use have demonstrated the effectiveness of these systems [9, 19, 20, 50‐55].

ASD has always been a potential long-term complication following anterior cervical fusion, and the incidence of ASD is even higher following long-segment fusion, which has attracted increasing attention. The incidence of ASD within 10 years after primary anterior cervical surgery is 25%, and more than 15% of patients require secondary surgery owing to ASD [16‐18, 56‐59]. The mechanisms underpinning the development of ASD are still unclear, and the widely accepted mechanisms are local biomechanical changes in the cervical spine and natural degeneration of adjacent segments. Other risk factors are advanced age, multilevel fusion, postoperative cervical alignment change, an excessively long titanium plate, surgical injury to the adjacent intervertebral discs, and preoperative degeneration of adjacent segments. Controversy continues regarding whether differences exist in the impact of anterior cervical fusion on adjacent segments. Based on a 2-year follow-up of 218 patients undergoing single- or two-level ACCF, Park et al. [56] found that the incidence of ASD in the upper adjacent segment was markedly higher than that in the lower adjacent segment following ACCF (58% vs. 28%, respectively). In addition, Yang et al. [57] conducted a 5-year follow-up of 370 patients who underwent anterior cervical fusion without titanium plate implantation, and found that the incidence of ASD in the upper adjacent segment was considerably higher than that in the lower adjacent segment (5% vs. 1%, respectively). However, in a 5.6-year follow-up study, Koller et al. [58] found no significant difference in the incidence of ASD between the upper and lower segments adjacent to the fused segment following anterior cervical fusion (41.2% vs. 50.0%, respectively). Similarly, Goffin et al. [59] followed 25 patients for an average of 7 years and found that 24% of the patients had ASD in the upper adjacent segment, while 28% had ASD in the lower adjacent segment; the difference between the two groups was not significant. In the present study, we found that with all four anterior cervical approaches, stress on the intervertebral discs at the adjacent segments was always higher for the upper disc compared with the lower disc under different conditions (flexion, extension, lateral bending, and rotation). This result suggests that after fusion, the upper adjacent segment was subjected to higher stress, which may accelerate dehydration and degeneration of the adjacent intervertebral disc, leading easily to ASD at this segment. A plausible reason for this difference is that the lower segment has greater mobility, which is conducive to stress load sharing; however, this hypothesis requires further clinical verification. Furthermore, we found that stress on the intervertebral discs at the adjacent segments was lowest in the mACDF-CA group and highest in the ACCF group. Biomechanically, this result revealed that mACDF-CA had the least impact on the adjacent segments compared with mACDF, HDF, and ACCF. However, whether mACDF-CA effectively prevents ASD remains to be clinically verified.

In summary, our biomechanical analysis indicated that among the four surgical approaches to anterior cervical fusion and internal fixation to treat MCSM, mACDF-CA had the least impact on the biomechanics of adjacent segments, and theoretically could reduce the incidence of ASD. However, this approach is associated with increased risk of fusion cage subsidence. In addition, stress at the titanium plate–screw interface was highest in the ACCF group and lowest in the mACDF group, which indicates the highest risk of titanium plate screw loosening, displacement, and fracture after ACCF. This study presented biomechanical evidence for the surgical treatment of MCSM and also provided strategies for preventing or reducing associated complications. However, further experiments and prospective clinical trials must be conducted to verify our findings.