Impact of Spinopelvic sagittal alignment on the surgical outcomes of dropped head syndrome: a multi-center study

Dropped head syndrome (DHS) is characterized by severe neck extensor weakness resulting in chin-on-chest deformity [1‐3]. Various types of neurological or medical conditions can cause DHS, including neurodegenerative diseases, myopathies, sarcopenia associated with aging, and iatrogenic causes [4‐8]. However, DHS can also occur without specific underlining neurological/muscular conditions [9, 10].

Patients with DHS experience various disabilities, including horizontal gaze difficulty and dysphagia, and these symptoms lead to deterioration of activity of daily living. Because DHS is a relatively rare condition, its treatment strategy has not yet been established. For severe deformity cases, surgical treatments are commonly indicated; however, studies regarding surgical treatment are mainly limited to small case series and focused on cervical alignment improvements [11‐13]. Several studies have demonstrated that patients with DHS have characteristic patterns of global spinal sagittal alignment. One study reported that there was appositive correlation between C2–7SVA and upper thoracic kyphotic angle (T1-4TK) [14]. Another study reported that DHS patients can be classified into two distinct types: SVA+ and SVA- types, based on the global alignment [15]. Currently, knowledge about the influence of pre/postoperative global sagittal alignment on the outcomes of surgically treated DHS is limited.

The present study investigated the clinical outcomes, including correction of cervical and global spinal sagittal alignment, in patients with surgically treated DHS.

Our results demonstrated that pre- and postoperative SVA and PI-LL were associated with surgical outcomes of patients with DHS, whereas the preoperative cervical alignment parameters and the corrections of these parameters were not significantly different between the patients with and without treatment failure. Regarding preoperative alignments, negative SVA and normal PI-LL were associated with favorable outcomes. To the best of our knowledge, this is the largest series with clinical outcomes of patients who underwent surgical treatment for DHS to date. In addition, we believe that this is the first study to report the associations between surgical outcomes and global spinal alignments in DHS patients.

Previous studies on surgical treatment for DHS have mostly been single case reports or small case series [11‐13, 19]. Even in the recently published systematic review of DHS, only 16 surgically treated cases reported in 15 articles were included [20]. The majority of these reports mainly focused on surgical techniques for the correction and changes in cervical alignment [21, 22], and only a few studies assessed the changes in global spinal alignment in detail [15]. Koda et al. have reported two DHS cases showing an improvement in lower back pain caused by hyperlordosis in the lumbar spine as compensation for head dropping after cervical corrective surgery [23]. Mizutani et al. have described the relationship between cervical spine kyphosis deformities, including DHS, and the sagittal alignment of the global spine and suggested the importance of considering the pathology based on SVA and PI-LL [24], similar to our study. They also reported postoperative cervical and global alignment changes [25]. However, their study did not exclude deformities due to neuromuscular disorders or iatrogenic causes, whereas our study exclusively targeted severe DHS with chin-on-chest deformity and carefully excluded any secondary causes of cervical deformity. Moreover, they did not clearly mention the longitudinal clinical outcomes except alignment changes and seemingly short-term complications/symptoms. Therefore, the impact of these alignment parameters on the hard outcomes of surgical treatment, such as revision surgery, remained unclear.

In our study, patients with horizontal gaze difficulty caused solely by thoracolumbar deformity were carefully excluded. However, the results showed that preoperative PI-LL was still a significant factor for additional surgery. Moreover, postoperative PI-LL was significantly worse in the failure group. Among the patients with abnormal preoperative PI-LL (> 10), the prevalent additional surgeries were thoracolumbar corrective surgeries. To compensate for chin-on-chest deformity in the distal spinal levels, the lumbar spine should be hyperlordotic and PI-LL tends to be smaller or negative. Patients with DHS with high PI-LL are likely to have a dysfunctional compensation in the distal spinal levels. These results suggest that the preoperative PI-LL mismatch is indicative of an independent issue in the lumbar spinal levels and cannot be corrected with cervical corrective surgeries alone. In other words, a significant proportion of patients with DHS, a seemingly cervical issue, have masked clinically significant thoracolumbar deformities as well, which might require corrective surgery. Based on these findings, we believe that the assessment of thoracolumbar alignment parameters should be warranted for all surgical candidates of DHS.

Our results also demonstrated that pre- and postoperative SVA was significantly greater in the failure group. Recently, Hashimoto et al. have reported details on the global sagittal alignment in 20 patients with DHS and discussed changes in alignment for 9 surgical cases. They proposed that DHS could be classified into two groups: SVA+ and SVA− [15]. In the SVA− group, patients maintain compensatory function, including making the lumbar spine hyperlordortic, and can shift the load axis backward. In the SVA+ group, compensatory functions in the thoracolumbar spine and pelvis to drop head deformity are compromised. The results of their study, which highlighted the importance of global sagittal balance and compensatory function in DHS, were compatible to our results. However, the major limitation of their study is that SVA+ patients are heterogeneous and the underlying pathologies, which might affect the surgical outcome, cannot be differentiated only by SVA. We believe that using another sagittal balance parameter (PI-LL) in combination with SVA would be beneficial for patient stratification. Among our patients with normal PI-LL, 100% (2/2) of SVA+ patients in their definitions required multiple revision surgery due to distal junctional failure. Those patients cannot maintain appropriate global spinal alignment and are likely to have postoperative junctional failure due to stress concentration on the implant even after seemingly successful cervical corrective surgeries, which achieved horizontal gaze at least temporarily after surgery.

Based on our results and discussion, patients with DHS could be classified into three categories (Types 1–3, Fig. 3) using two reference points of global spinal sagittal parameters: 1) SVA > 0 mm as proposed by Hashimoto et al. and 2) well-established reference of spinopelvic harmony as PI-LL > 10° [26]. Type 1 is defined as patients with PI-LL of ≤10° and SVA of ≤0 mm (9 patients: Cases 1, 4, 5, 6, 7, 9, 10, 14, and 15, Fig. 4). The compensatory function works well in this type and patients can increase lumbar lordosis enough to shift to SVA−. In our study, the outcomes of this type were favorable except for 1 patient who required an additional surgery, extending the fusion to T4, because of loosening of pedicle screws and delayed-onset minor surgical site infection. All the patients were successfully treated with limited fusions between the cervical and upper thoracic spine. Type 2 is defined as patients with PI-LL of ≤10° and SVA of > 0 mm (2 patients: Cases 2 and 8, Fig. 5). In this group, compensatory function of the spine does not work sufficiently because of concomitant thoracic deformities, including hyperkyphosis, and patients are unable to shift the vertical axis backward. In our study, 2 patients experienced implant failures repeatedly and ultimately required fixation to the lumbar spine. Lastly, Type 3 is defined as patients with PI-LL of > 10° (4 patients: Cases 3, 11, 12, and 13, Fig. 6). These patients have clinically significant thoracolumbar deformity masked by cervical deformity. Even if horizontal gaze is achieved once after cervical surgery, lumbar corrective surgeries are likely to be required for recurrence of horizontal gaze difficulty and/or lumbar spine symptoms.

Regarding the range of fused levels, Sharan et al. have recommended fixation from C2 to the upper thoracic spine T3–5 [1]. However, it is impossible to apply a unified criterion for all patients. In our study, most of the Type 1 patients obtained horizontal gaze and favorable outcomes with fixation extended to the upper thoracic vertebrae, whereas 2 patients in Type 2 eventually required extent of fixation down to the lumbar spine. Among these patients, fixation above the upper thoracic levels appears not enough to shift SVA backward. PI-LL in these patients is normal; therefore, a longer range of fused levels should be considered for correction at thoracic spine level at the first surgery. (Fig. 7) For Type 3 patients, it is difficult to determine the optimal fused range solely by the cervical factors, and the surgical decision-making should be based on both cervical and lumbar pathology assessments.

There are no clear target values of correction of chin-on-chest deformities, similar to PI-LL of < 10° proposed by SRS classification for lumbar kyphosis. In this study, no significant difference was detected in C2–7A, C-SVA, and T1S between the failure and nonfailure groups, suggesting that the cervical spine alignment parameter alone is not enough to predict favorable outcomes. It also depends on the thoracolumbar spinal alignment and compensatory function whether the correction of the cervical spine is sufficient to shift SVA backward. To determine the target values for DHS correction surgery, thoracolumbar spine alignment should be taken into account along with cervical spine alignment to improve outcomes. With our current data, we could not provide definitive values and this point should be addressed in future studies.

Because of the rarity of DHS, our study has several limitations. The first and main limitation is the small sample size. Although our study comprised the largest sample size as an outcome evaluation of surgically treated DHS, the number of patients was not enough to conduct robust statistical analyses. Moreover, the mean follow-up period in this study was approximately 2 years, and the long-term outcomes are yet to be determined. Furthermore, to manage the potentially heterogeneous nature of DHS, surgical techniques were not standardized. Lastly, the main outcome measure of this study was the requirement of revision surgery. Other patient reported outcomes such as pain or ADL scores were not included. We proposed a classification system in this study and we believe that this can be a basis of future study. However, since our study contains several limitations, this classification system should be refined as the evidence grows.

The comparative analyses between the failure and nonfailure groups showed significant differences in pre- and postoperative PI-LL and SVA. Although chin-on-chest deformity in the cervical spine is a defining feature of DHS, our results suggest that global sagittal alignment parameters, including PI-LL and SVA that likely represent the compensatory function of the thoracic–lumbosacral spine and the displacement in the load axis might have notable impacts on surgical outcomes. Surgeons should pay attention to and consider PI-LL and C7SVA while evaluating each patient’s compensatory function to determine surgical plans for patients with DHS.