Abstract
Study Design
A retrospective cohort study.
Purpose
This study aimed to investigate the relationship among osteopenia, bone density, and subsidence following anterior cervical discectomy and fusion (ACDF).
Overview of Literature
Subsidence following ACDF procedures can lead to worse clinical outcomes. Although studies have linked osteopenia to cage subsidence, no consensus has been established on the relationship between bone density and subsidence.
Methods
Patients undergoing ACDF between 2016 and 2021 were included and assigned to the osteopenia cohort based on chart review and dual-energy X-ray absorptiometry scan results. Bone density at each vertebral level of the cervical fusion was assessed by measuring Hounsfield units from preoperative computed tomography (CT) scans, and disk height changes were assessed using immediate postoperative (<6 weeks) and final follow-up (>5 months) radiographs. Subsidence was quantified by the difference between the long-term and immediate postoperative anterior and posterior disk heights. A t-test was performed to evaluate the effect of prior osteopenia diagnosis on segmental subsidence. Multivariable analysis, accounting for age, sex, smoking status, and cage type, further investigated the relationship between Hounsfield units and subsidence.
Results
Among the 131 patients (244 levels fused), no significant associations were found between osteopenia diagnosis and anterior (p=0.926) or posterior (p=0.918) subsidence. Preoperative CT measurements for 28 patients (54 fused levels) revealed no correlations between subsidence and Hounsfield units at the vertebral levels above and below the fusion. Of the 54 levels with preoperative CT scans, 22 patients (41%) were diagnosed with osteopenia. Osteopenia did not correlate with Hounsfield units using the endplate (superior, p=0.735; inferior, p=0.693), full vertebrae (superior, p=0.686; inferior, p=0.735), or elliptical (superior, p=0.501; inferior, p=0.465) methods.
Conclusions
The results did not reveal the relationship between either the prior diagnosis of osteopenia or Hounsfield units and subsidence. These results highlight the multifactorial nature of postoperative subsidence, and osteopenia or Hounsfield units cannot be used alone to determine the subsidence risk.
Keywords: Pathologic bone demineralization, Osteoporosis, Bone density, Diskectomy, Spinal fusion, Spinal fusion/adverse effects
GRAPHICAL ABSTRACT
Introduction
Anterior cervical discectomy and fusion (ACDF) commonly results in subsidence, which is reported in 19.3%–42.5% of cases and is characterized by graft or cage sinking into a vertebral body, affecting disk height, sagittal alignment, and clinical outcomes [1–5]. The aging population raises concerns about osteopenia-related complications in ACDF, as studies have suggested an increased risk of revision surgery and instrumentation failure in patients with osteopenia [6–9]. However, the literature lacks a unanimous stance on the osteopenia–subsidence link, with conflicting findings on cage subsidence rates in patients with osteoporosis [10].
Inconsistent data also surround the relationship between bone density and subsidence, with some studies linking lower preoperative Hounsfield units (HUs) to subsidence, whereas others report the lack of correlation [1,11–13]. Osteopenia, defined by bone density measurements, is diagnosed by dual-energy X-ray absorptiometry (DEXA), highlighting variations in trabecular bone density and mechanical bone strength across spinal regions [14–17]. This prompts further exploration of osteopenia diagnoses and bone density differences in the cervical spine.
Given the disparity in the current literature, this study aimed to investigate the correlation between preoperative computed tomography (CT)-derived HUs as a measure of bone density and subsidence following ACDF. Furthermore, osteopenia diagnosis and its correlation with CT-derived HUs and subsidence were analyzed. Lastly, whether a history of osteopenia corresponds to lower HU measurements in the cervical spine was explored.
Materials and Methods
Ethics statement
This retrospective institutional study was approved by the Icahn School of Medicine at Mount Sinai institutional review board (STUDY-21-01028). The need for informed consent was waived owing to the retrospective study design.
Study design
The study included patients undergoing ACDF (Current Procedural Terminology [CPT] 22551, CPT 22552, and CPT 22554) between 2016 and 2021 for the treatment of degenerative cervical spine disease resulting in cervical radiculopathy or cervical myelopathy in patients who have failed conservative treatment. Those with a posterior approach, age <18 years, revision surgeries, trauma surgeries, corpectomy, and poor-quality radiographs were excluded. Patients with immediate postoperative radiographs within 6 weeks and final postoperative radiographs at least 5 months postoperatively were included.
Variables
All data for the study were collected via chart and radiographic review of institutional electronic medical records. Patient data, including age, sex, smoking history, and osteopenia history, were collected through chart and radiographic reviews. Smoking status was identified from the medical records, and osteopenia was diagnosed based on a prior diagnosis within the medical chart and DEXA scan results (T-scores <−1) [18]. Patients with a prior diagnosis of osteoporosis (DEXA T-scores <−2.5) were also included in the category of osteopenia to consider all patients with reduced bone density.
The radiographs were analyzed using Picture Archiving and Communications System (PACS) imaging software. Subsidence measurements were obtained from lateral radiographs, and disk height measurements were taken at immediate postoperative (<6 weeks) and final follow-up (>5 months) cervical radiographs, as demonstrated by Duey et al. [19]. Subsidence was assessed as a continuous variable, characterized by a positive decrease in the disk height when comparing long-term and postoperative disk heights. This assessment was verified by trained researchers and a senior author, demonstrating high interobserver reliability. The types of intervertebral cages utilized included structural allograft, titanium, polyetheretherketone (PEEK), ceramic, and zero-profile cages. All patients received a cage and plate construct, except those who received a zero-profile implant with integrated screws.
A subgroup underwent CT with a preoperative scan inclusion criterion within 1 year before surgery. Three different methods were used to assess preoperative bone density on these preoperative sagittal CT scans: elliptical, full vertebral body, and endplate HU measurements. Three measurement methods were used to see if any of the three were more correlated with subsidence than the others, particularly considering that HU measurements on CT can vary depending on the location of the measurement within the vertebrae. HUs were measured at the superior and inferior vertebrae of each fused level. Because the cages were most likely to subside at the anterior portion of the endplate, the elliptical measurements were taken at the anterior part of the vertebrae [20]. Endplate freehand bone density measurements were made at the inferior aspect of the superior vertebrae and the superior aspect of the inferior vertebrae using the freehand tool within PACS (Fig. 1A). Full vertebral body freehand measurements of the superior and inferior vertebrae were made using the freehand tool within PACS by tracing the entire vertebral body at the sagittal midplane (Fig. 1B). Finally, using the elliptical tool within PACS, elliptical measurements were made at the anteroinferior aspect of the superior vertebrae and anterosuperior aspect of the inferior vertebrae (Fig. 1C). Measurements of the superior and inferior vertebrae at each fused level were collected by trained researchers and verified by a senior author with higher interobserver reliability.
Fig. 1.
(A) An example tracing of the above (blue) and below (yellow) fused endplates, using the freehand tool within Picture Archiving and Communications System (PACS). (B) An example tracing of the above (yellow) and below (blue) fused full vertebrae, using the freehand tool within PACS. (C) An example tracing of the above (blue) and below (yellow) fused vertebrae, using the ellipse tool within PACS. HU, Hounsfield unit.
Statistical analysis
T-tests were performed to explore the relationship between prior osteopenia diagnosis and subsidence, and multivariable logistic regression was controlled for age, sex, smoking status, and cage type. Pearson correlation tests were performed to compare HU measurements (elliptical, vertebral freehand, and endplate freehand) with anterior and posterior subsidence. Multivariable linear regression models, controlling for age, sex, cage type, and smoking status, investigated the relationships between bone density and subsidence with HUs at the superior and inferior vertebrae at each level as the main predictor variables. A t-test was performed to explore the association between osteopenia diagnosis and HU measurements. All statistical analyses were conducted in Python ver. 3.8.8 (https://www.python.org/), considering significance as alpha <0.05.
Results
This study included 131 patients with a total of 244 levels fused. The mean age for the entire cohort was 53.6±10.9 years. Patients underwent one-level (n=41; 31%), two-level (n=67; 51%), or three-level (n=23; 18%) fusions. Of the 131 patients, 27 (20.6%) had a prior diagnosis of osteopenia. Of the 27 patients included in the osteopenia group, 14 had DEXA scans, and the remaining 13 had a chart history (within the past medical history or problem list sections of EPIC) of osteopenia or osteoporosis. The mean age was higher for patients with a prior diagnosis of osteopenia (59.5 years vs. 52.1 years, p=0.001) (Table 1). The median follow-up for patients with osteopenia was 13.4 months (range, 6–37 months) and 11.9 months (range, 5–61 months) for patients without osteopenia (Table 1).
Table 1.
Demographics based on prior diagnosis of osteopenia
| Characteristic | Osteopenia (n=27) | No osteopenia (n=104) | p-value |
|---|---|---|---|
| Age (yr) | 59.5±9.0 | 52.1±10.9 | 0.001* |
| Follow-up (mo) | 16.5±9.1 | 14.5±9.8 | 0.333 |
| Male sex | 5 (18.5) | 51 (49.0) | 0.004* |
| Osteopenia | 27 (100.0) | 0 | NA |
| Smoking | 18 (66.7) | 44 (42.3) | 0.024* |
| 1-level | 4 (14.8) | 37 (35.6) | 0.038* |
| 2-level | 15 (55.6) | 52 (50.0) | 0.607 |
| 3-level | 8 (29.8) | 15 (14.4) | 0.064 |
| Allograft | 14 (51.9) | 54 (51.9) | 0.995 |
| Titanium | 7 (25.9) | 20 (19.2) | 0.444 |
| PEEK | 4 (14.8) | 18 (17.3) | 0.758 |
| Ceramic | 1 (3.7) | 10 (9.6) | 0.324 |
| Zero-profile | 1 (3.7) | 2 (1.9) | 0.582 |
Values are presented as mean±standard deviation or number (%).
NA, not available; PEEK, polyetheretherketone.
p<0.05.
No significant associations were found between a diagnosis of osteopenia and either anterior (p=0.633) or posterior (p=0.751) subsidence (Table 2). In multivariable linear regression model, osteopenia (β, −0.023; 95% confidence interval [CI], −0.507 to 0.461) was not significantly correlated with anterior subsidence (p=0.926). Similarly, no correlation was observed between osteopenia (β, −0.020; 95% CI, −0.397 to 0.358) and posterior subsidence (p=0.918) (Table 3).
Table 2.
T-test with segmental subsidence as the outcome variable and per-level radiographic data based on prior osteopenia diagnosis (N=244)
| Variable | Osteopenia (n=58) | No osteopenia (n=186) | p-value |
|---|---|---|---|
| Anterior | |||
| Final ADH | 6.4±1.4 | 6.9±1.4 | 0.047 |
| Anterior subsidence | 1.4±1.4 | 1.5±1.5 | 0.633 |
| Percent ADH change | −17.0±16.3 | −17.3±16.3 | 0.905 |
| Posterior | |||
| Final PDH | 5.4±1.3 | 5.4±1.2 | 0.750 |
| Posterior subsidence | 1.2±1.0 | 1.2±1.2 | 0.751 |
| Percent PDH change | −17.2±14.6 | −17.6±16.7 | 0.888 |
Values are presented as mean±standard deviation in millimeters.
ADH, anterior disc height; PDH, posterior disc height.
Table 3.
Multivariable linear regression with anterior and posterior subsidence as outcome variables and osteopenia as the independent variable (N=244)
| β (95% CI) | p-value | |
|---|---|---|
| Anterior subsidence | −0.023 (−0.507 to 0.461) | 0.926 |
| Posterior subsidence | −0.020 (−0.397 to 0.358) | 0.918 |
Subsidence is in millimeters. The model controls for age, sex, cage type, and smoking status.
CI, confidence interval.
The subgroup of patients with preoperative CT scans included 28 patients with 54 levels fused. Nine patients (32%) had a prior diagnosis of osteopenia. The average age for the subgroup was 54.1±9.8 years. Patients underwent one-level (n=8; 29%), two-level (n=14; 50%), or three-level (n=6; 21%) fusion. Patients received allograft (n=8; 29%), titanium (n=8; 29%), PEEK (n=5; 18%), and zero-profile (n=2; 7%) cages. The median follow-up was 11.6 months (range, 5.3–44.9 months) (Supplement 1).
No correlation was found between anterior subsidence and endplate HUs of the superior vertebrae at the fusion level (β, −0.273; 95% CI, −3.001 to 2.455; p=0.842) or endplate HUs of the inferior vertebrae at the fusion level (β, −0.787; 95% CI, −3.686 to 2.111; p=0.588). Anterior subsidence was not associated with the full vertebrae or ellipse HUs of the superior and inferior vertebrae. Similarly, no relationship was observed between posterior subsidence and endplate HUs of the superior vertebrae (β, −0.483; 95% CI, −2.294 to 1.328; p=0.595) or endplate HUs of the inferior vertebrae at the fusion level (β, −0.310; 95% CI, −2.242 to 1.623; p=0.749). Endplate HU, full vertebrae HU, and ellipse HU measurements were not correlated with anterior or posterior subsidence (Fig. 2, Supplements 2–4).
Fig. 2.
(A) Long-term anterior subsidence (mm) and endplate density above the fusion (Hounsfield units). (B) Long-term anterior subsidence (mm) and endplate density below the fusion (Hounsfield units).
In a multivariable linear regression, no difference was observed in the amount of anterior subsidence based on endplate HUs of the superior vertebrae at the fusion level (β, 1.807; 95% CI, −3.077 to 6.691; p=0.460), endplate HUs of the inferior vertebrae at the fusion level (β, −2.583; 95% CI, −7.658 to 2.491; p=0.311), full vertebrae HUs of the superior and inferior vertebrae, and elliptical HUs of the superior and inferior vertebrae at the fusion level. In addition, no relationship was observed between posterior subsidence and endplate HUs of the superior vertebrae (β, −1.015; 95% CI, −4.511 to 2.482; p=0.562), endplate HUs of the inferior vertebrae (β, 0.498; 95% CI, −3.135 to 4.131; p=0.784), full vertebrae HUs of the superior and inferior vertebrae, and elliptical HUs of the superior and inferior vertebrae at the fusion level (Table 4).
Table 4.
Multivariable linear regression with anterior and posterior subsidence as outcome variables and bone density as the independent variable
| Variable | β (95% CI) | p-value |
|---|---|---|
| Anterior subsidence | ||
| Endplate density (above) | 1.807 (−3.077 to 6.691) | 0.460 |
| Endplate density (below) | −2.583 (−7.658 to 2.491) | 0.311 |
| Vertebrae density (above) | −3.826 (−9.544 to 1.891) | 0.184 |
| Vertebrae density (below) | 4.685 (−1.160 to 10.530) | 0.113 |
| Ellipse density (above) | −1.313 (−4.926 to 2.299) | 0.468 |
| Ellipse density (below) | 1.251 (−2.521 to 5.024) | 0.507 |
| Posterior subsidence | ||
| Endplate density (above) | −1.015 (−4.511 to 2.482) | 0.562 |
| Endplate density (below) | 0.498 (−3.135 to 4.131) | 0.784 |
| Vertebrae density (above) | −2.552 (−6.655 to 1.550) | 0.217 |
| Vertebrae density (below) | 2.705 (−1.489 to 6.899) | 0.200 |
| Ellipse density (above) | −1.487 (−4.029 to 1.054) | 0.245 |
| Ellipse density (below) | 0.962 (−1.693 to 3.616) | 0.469 |
Subsidence is in millimeters, and the model controls for age, sex, cage type, and smoking status. N=54 levels, from 28 total patients. Units are bone density per 1,000 Hounsfield units.
CI, confidence interval.
Of the 54 fused levels with measured HUs, 22 (40.7%) were in patients diagnosed with osteopenia. In a t-test, no correlation was found between a diagnosis of osteopenia and upper endplate HUs (p=0.735), lower endplate HUs (p=0.693), upper full vertebrae HUs (p=0.686), lower full vertebrae HUs (p=0.735), upper elliptical bone HUs (p=0.501), and lower elliptical bone HUs at the fusion level (p=0.465) (Supplement 5).
Discussion
Although previous studies have linked reduced bone density to an increased risk of revision surgery and instrumentation failure in cervical spine surgery, the relationship between prior osteopenia and subsidence remains unclear [6,21]. Some studies have indicated that cage subsidence is not related to osteopenia, whereas other studies have reported correlations between lower preoperative HU measurements and increased risk of postoperative subsidence [10–13]. The present study investigated the effect of prior osteopenia diagnosis and preoperative CT HUs on subsidence following ACDF.
The results showed no significant association between prior osteopenia diagnosis and subsidence following ACDF. Osteopenia has rarely been associated with cervical subsidence in previous studies [22]. Opsenak et al. [22] found a 56% incidence of cage subsidence in their study, and lower bone density was significantly linked with a higher incidence of subsidence. Despite these findings, some studies have indicated that osteopenia is not always associated with subsidence after ACDF. Zhang et al. [10] analyzed 42 patients who underwent single-level ACDF and found no differences in cage subsidence rates at the 3-year follow-up between patients who had osteopenia and those who did not. The present study adds to this growing body of research as our results suggest that a prior diagnosis of osteopenia is not significantly associated with subsidence in our institutional cohort of patients undergoing ACDF. Therefore, a preoperative diagnosis of osteopenia may not increase the risk of subsidence.
The present study also showed no significant association between HU measurements and subsidence following ACDF. Anderson et al. [23] demonstrated the utility of CT-derived HU as a measure of bone mineral density. Interestingly, the cervical spine literature generally points to a significant relationship between HU measurements and postoperative subsidence. Ji et al. [24] retrospectively analyzed 73 patients who underwent single-level ACDF and found a significant correlation between lower global cervical HUs in patients with cage subsidence. Lee et al. [11] retrospectively reviewed 235 patients who underwent one- or two-level ACDF procedures and found that lower HUs were associated with higher subsidence rates. Other studies have found that lower preoperative CT-derived HUs are associated with cage subsidence in ACDF [11,12]. For instance, Wang et al. [12] determined that lower preoperative CT-derived HUs were associated with cage subsidence in patients undergoing single-level ACDF. Taking together the results of these studies, measures of bone mineral density, such as HU, have predictive clinical power for determining the degree and rate of subsidence following ACDF [11–13]. However, Brenke et al. [13] did not find a correlation between bone mineral density and subsidence risk but concluded that subsidence depends on cage geometry and varies with the operative procedure [11,12]. Our results indicate that HU measurements using the endplate, vertebrae, and ellipse methods were not significant predictors of cage or allograft subsidence. Our results may differ from those of previous studies owing to the sample size and differences in the diagnostic criteria for osteopenia. Furthermore, the majority of our patients underwent ACDF of ≥2 levels, and the complexity of multilevel surgeries may introduce additional factors that either obscure or reduce the visibility of osteopenia’s effect on subsidence, contributing to our finding of the lack of correlation between HU and subsidence. Although previous studies have evaluated HU measurements or preoperative osteopenia diagnosis, the present study compares both in a single institutional dataset.
Osteopenia is diagnosed primarily based on bone mineral density measurements taken during DEXA of the lumbar spine, hip, and forearm [14,25]. A radiographic study by Ahmed et al. [26] assessed the referral letters of 3,479 women who were referred for bone mineral density screening and concluded that radiographic osteopenia is an excellent predictor of low bone mass. Jha et al. [27] reviewed the differential diagnosis of low bone density and osteoporosis and concluded that these two variables should be differentiated from one another when diagnosing patients. Several studies have reported differences in bone density within the C3–C7 vertebrae [28,29]. Moreover, Anderst et al. [30] reported significant variations in the bone density of the cervical vertebrae based purely on anatomical location, suggesting differences in the regional bone mechanical properties.
The results of this study suggest the lack of correlation between an osteopenia diagnosis and HUs within the cervical spine. This lack of correlation between osteopenia and cervical spine bone density may be linked to the fact that osteopenia is diagnosed using DEXA throughout the body. The World Health Organization defines osteoporosis according to the following guidelines: a T-score within 1 standard deviation of the young adult mean indicates normal bone density, a T-score of 1–2.5 standard deviations below the young adult mean indicates osteopenia, and T-score of ≥2.5 standard deviations below the young adult mean indicates osteoporosis [14,25]. DEXA may not be the best measure of localized cervical spine bone quality. Furthermore, bone mineral density scores taken at the lumbar spine, hip, and forearm are not necessarily reflective of the cervical spine bone quality. Although this study reports on a small sample of patients with preoperative CT, the use of HUs allows for bone density assessment across different cervical vertebral levels. This provides an improved assessment of the cervical spine bone density compared with DEXA, which reports a single value at the lumbar spine level. Our results support this theory as we found that a prior diagnosis of osteopenia was not significantly associated with HUs within the cervical spine, indicating that surgeons should not assume that a patient with osteopenia will have reduced HUs in their cervical spine. This study represents a real-world analysis of osteopenia diagnosis as DEXA scans are not always available preoperatively. Given that many patients do not present for surgery with DEXA results and the increasing role of preoperative planning using CT, understanding the correlation between HU and subsidence is significant.
Subsidence following ACDF is a common radiographic finding; however, its clinical implications, particularly regarding patient-reported outcomes, are nuanced. Several studies have investigated the correlation between subsidence and clinical outcomes. Lee et al. found that subsidence occurred in 46.8% of patients 12 months after ACDF; however, no significant difference was found in clinical outcomes, such as neck and arm pain, between patients with and without subsidence. This suggests that subsidence does not adversely affect short-term clinical outcomes [31]. Milczynska et al. [32] reported a subsidence rate of 23% with the use of a novel titanium cage and similarly found no significant effect on health-related quality of life outcomes, including the Visual Analog Scale (VAS) for neck and arm pain, EuroQol-five dimension five-level, EuroQol VAS, and Neck Disability Index scores. This further supports the notion that subsidence does not necessarily correlate with worse patient-reported outcomes [32]. In a long-term follow-up study, Ryu et al. [33] found that subsidence occurred in 45.2% of patients; however, it did not significantly influence radiological or clinical outcomes, provided that adequate foramen decompression was achieved. This indicates that a proper surgical technique may mitigate the potential negative effects of subsidence [33]. According to Wu et al. [34], although subsidence was common (19.1%), it did not significantly affect long-term clinical outcomes, emphasizing the importance of cervical lordosis improvement over subsidence in determining patient outcomes. Although subsidence is a frequent occurrence following ACDF, current evidence suggests that it does not significantly affect patient-reported outcomes, provided that other surgical goals, such as maintaining cervical alignment and adequate decompression, are achieved.
In addition to patient-specific factors, accurate cage placement during ACDF is essential for minimizing the risk of subsidence. Ensuring proper alignment and choosing an appropriate surgical technique, as well as utilizing fixation materials that complement the patient’s pathology, are critical steps to achieving optimal outcomes. Studies have demonstrated that precise cage positioning and the use of suitable surgical techniques can significantly reduce subsidence [3,35]. Although our analysis did not identify a strong association between reduced bone density and subsidence, factors such as surgical technique and the quality of the bone–implant interface as well as patient anatomy may be critical in determining the long-term success of ACDF. In addition to the alignment and surgical technique, the advancement of biomaterials for ACDF implants may have affected ACDF subsidence in patients with osteopenia. Recent advancements, particularly with PEEK and titanium-coated PEEK cages, have shown promise in reducing subsidence, particularly in patients with osteopenia [13]. These materials, with their elastic modulus closer to the bone, enhance stability and osseointegration. In addition, novel porous implant designs such as gyroid structures help distribute mechanical loads more evenly, further minimizing subsidence [36]. Coating technologies, such as bioceramic, also improve the implant–bone interaction, enhancing the overall outcomes for patients with compromised bone quality [37]. This study did not evaluate the effect of the surgical technique or patient anatomy on subsidence. However, we did control for cage material in our regression analyses using a heterogeneous cohort of patients with PEEK, titanium, ceramic, and allograft spacers.
Several limitations must be considered when interpreting this study. As a single-institution retrospective study, our results may not be generalizable to other institutions and patient cohorts in other geographic locations. Second, differences in patient positions during radiographic collection may be attributed to some measurement variations. Furthermore, changes in disk height measurements may be due to causes other than subsidence, such as cage settling, bone resorption at the surgical site, or graft collapse [38]. Other potential causes of low bone density, such as osteomalacia and chronic kidney disease, can further contribute to subsidence [27]. In addition, because our bone density analysis subgroup was significantly smaller than the osteopenia analysis group we began with, our bone density data may be underpowered. To that same point, although we controlled for variables including age, sex, smoking status, and cage type, the study does not have adequate statistical power to control for all variables of clinical interest. Although our regression analysis is limited by the sample size, a strength of this study is the measurement of subsidence as a continuous variable rather than a binary variable, which decreases the sample size necessary to produce meaningful results. Owing to the limited sample size, patients with osteoporosis were categorized as osteopenic rather than subcategorized in their own group. Finally, although this study primarily focused on the analysis of HU and its correlation with subsidence, osteopenia diagnosis was determined via chart review of physician notes and DEXA results, which introduces variability and likely underrepresents the prevalence of osteopenia.
Conclusions
This study suggests that a prior diagnosis of osteopenia does not increase the risk of subsidence following ACDF. Further, no relationship was observed between bone density as measured by HU in preoperative CT scans and subsidence risk. This lack of relationship could reflect the diagnostic methods for osteopenia, which rely on bone density measurements in skeletal regions that do not include the cervical spine, and differences in surgical technique and patient anatomy play a larger role in subsidence development. These results highlight the multifactorial nature of subsidence, and osteopenia and HU may not independently predict subsidence following ACDF.
Key Points
The study found no significant relationship between an osteopenia diagnosis and the degree of subsidence in patients who underwent anterior cervical discectomy and fusion.
Hounsfield unit measurements taken from the vertebrae above and below the fusion site did not correlate with subsidence.
Osteopenia was not associated with Hounsfield unit measurements using the endplate, full vertebrae, or elliptical methods.
The risk of postoperative subsidence appears to be influenced by multiple factors, and neither an osteopenia diagnosis nor Hounsfield units alone can predict this risk.
Footnotes
Conflict of Interest
The author(s) declare the following potential conflicts of interest with respect to the research, authorship, and/or publication of this article: Jun S. Kim: Stryker (paid consultant). Samuel Kang-Wook Cho: FAAOS-AAOS (board or committee member), American Orthopaedic Association (board or committee member), AOSpine North America (board or committee member), Cervical Spine Research Society (board or committee member), Globus Medical (IP royalties), North American Spine Society (board or committee member), Scoliosis Research Society (board or committee member), and Stryker (paid consultant). Except for that, no potential conflict of interest relevant to this article was reported.
Author Contributions
Conceptualization: WA, AHD, JSK, SKC. Data curation: WA, AHD, CG, PJF. Investigation: WA, AHD. Methodology: WA, AHD. Project administration: WA. Supervision: WA. Visualization: WA. Writing–original draft: WA, RR, TH, BZ, ZPM, JP. Writing–review & editing: WA, AHD, RR, TH, BZ, ZPM, JP, JS, JSK, SKC. Formal analysis: AHD. Software: AHD. Validation: AHD. Resources: JSK, SKC. Final approval of the manuscript: all authors.
Supplementary Materials
Supplementary materials can be available from https://doi.org/10.31616/2024.0214.
Supplement 1. Demographics of subgroup of patients with preoperative CT scans.
Supplement 2. Univariable linear regression with anterior and posterior subsidence as outcome variables and bone density as the independent variable.
Supplement 3. Long-term anterior segmental subsidence and vertebrae bone density measurements.
Supplement 4. Long-term anterior segmental subsidence and ellipse density measurements.
Supplement 5. T-test comparing upper and lower vertebrae bone density for all three measurement methods in patients with and without prior osteopenia diagnosis.
References
- 1.Lee JS, Son DW, Lee SH, et al. The Effect of Hounsfield unit value with conventional computed tomography and intraoperative distraction on postoperative intervertebral height reduction in patients following stand-alone anterior cervical discectomy and fusion. J Korean Neurosurg Soc. 2022;65:96–106. doi: 10.3340/jkns.2021.0131. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 2.Igarashi H, Hoshino M, Omori K, et al. Factors influencing interbody cage subsidence following anterior cervical discectomy and fusion. Clin Spine Surg. 2019;32:297–302. doi: 10.1097/BSD.0000000000000843. [DOI] [PubMed] [Google Scholar]
- 3.Noordhoek I, Koning MT, Jacobs WC, Vleggeert-Lankamp CL. Incidence and clinical relevance of cage subsidence in anterior cervical discectomy and fusion: a systematic review. Acta Neurochir (Wien) 2018;160:873–80. doi: 10.1007/s00701-018-3490-3. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 4.Kast E, Derakhshani S, Bothmann M, Oberle J. Subsidence after anterior cervical inter-body fusion: a randomized prospective clinical trial. Neurosurg Rev. 2009;32:207–14. doi: 10.1007/s10143-008-0168-y. [DOI] [PubMed] [Google Scholar]
- 5.Lee YS, Kim YB, Park SW. Risk factors for postoperative subsidence of single-level anterior cervical discectomy and fusion: the significance of the preoperative cervical alignment. Spine (Phila Pa 1976) 2014;39:1280–7. doi: 10.1097/BRS.0000000000000400. [DOI] [PubMed] [Google Scholar]
- 6.Guzman JZ, Feldman ZM, McAnany S, Hecht AC, Qureshi SA, Cho SK. Osteoporosis in cervical spine surgery. Spine (Phila Pa 1976) 2016;41:662–8. doi: 10.1097/BRS.0000000000001347. [DOI] [PubMed] [Google Scholar]
- 7.Lehman RA, Jr, Kang DG, Wagner SC. Management of osteoporosis in spine surgery. J Am Acad Orthop Surg. 2015;23:253–63. doi: 10.5435/JAAOS-D-14-00042. [DOI] [PubMed] [Google Scholar]
- 8.Wang KF, Duan S, Zhu ZQ, Liu HY, Liu CJ, Xu S. Clinical and radiologic features of 3 reconstructive procedures for the surgical management of patients with bilevel cervical degenerative disc disease at a minimum follow-up period of 5 years: a comparative study. World Neurosurg. 2018;113:e70–6. doi: 10.1016/j.wneu.2018.01.157. [DOI] [PubMed] [Google Scholar]
- 9.Park SB, Chung CK. Strategies of spinal fusion on osteoporotic spine. J Korean Neurosurg Soc. 2011;49:317–22. doi: 10.3340/jkns.2011.49.6.317. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 10.Zhang L, Wang J, Feng X, et al. Outcome evaluation of zero-profile device used for single-level anterior cervical discectomy and fusion with osteoporosis compared without osteoporosis: a minimum three-year follow-up study. World Neurosurg. 2019;124:e1–9. doi: 10.1016/j.wneu.2018.10.024. [DOI] [PubMed] [Google Scholar]
- 11.Lee HJ, You ST, Kim JH, Kim IS, Sung JH, Hong JT. Significance of cervical spine computed tomography Hounsfield units to predict bone mineral density and the subsidence after anterior cervical discectomy and fusion. Clin Spine Surg. 2021;34:E450–7. doi: 10.1097/BSD.0000000000001218. [DOI] [PubMed] [Google Scholar]
- 12.Wang M, Mummaneni PV, Xi Z, et al. Lower Hounsfield units on CT are associated with cage subsidence after anterior cervical discectomy and fusion. J Neurosurg Spine. 2020;33:425–32. doi: 10.3171/2020.3.SPINE2035. [DOI] [PubMed] [Google Scholar]
- 13.Brenke C, Dostal M, Scharf J, Weiß C, Schmieder K, Barth M. Influence of cervical bone mineral density on cage subsidence in patients following stand-alone anterior cervical discectomy and fusion. Eur Spine J. 2015;24:2832–40. doi: 10.1007/s00586-014-3725-9. [DOI] [PubMed] [Google Scholar]
- 14.Sawicki P, Talalaj M, Zycinska K, Zgliczynski WS, Wierzba W. Current applications and selected technical details of dual-energy X-ray absorptiometry. Med Sci Monit. 2021;27:e930839. doi: 10.12659/MSM.930839. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 15.Eckstein F, Lochmuller EM, Lill CA, et al. Bone strength at clinically relevant sites displays substantial heterogeneity and is best predicted from site-specific bone densitometry. J Bone Miner Res. 2002;17:162–71. doi: 10.1359/jbmr.2002.17.1.162. [DOI] [PubMed] [Google Scholar]
- 16.Yoganandan N, Pintar FA, Stemper BD, et al. Trabecular bone density of male human cervical and lumbar vertebrae. Bone. 2006;39:336–44. doi: 10.1016/j.bone.2006.01.160. [DOI] [PubMed] [Google Scholar]
- 17.Weishaupt D, Schweitzer ME, DiCuccio MN, Whitley PE. Relationships of cervical, thoracic, and lumbar bone mineral density by quantitative CT. J Comput Assist Tomogr. 2001;25:146–50. doi: 10.1097/00004728-200101000-00027. [DOI] [PubMed] [Google Scholar]
- 18.Raisz LG. Clinical practice: screening for osteoporosis. N Engl J Med. 2005;353:164–71. doi: 10.1056/NEJMcp042092. [DOI] [PubMed] [Google Scholar]
- 19.Duey AH, Gonzalez C, Geng EA, et al. The effect of subsidence on segmental and global lordosis at long-term follow-up after anterior cervical discectomy and fusion. Neurospine. 2022;19:927–34. doi: 10.14245/ns.2244750.375. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 20.Karikari IO, Jain D, Owens TR, et al. Impact of subsidence on clinical outcomes and radiographic fusion rates in anterior cervical discectomy and fusion: a systematic review. J Spinal Disord Tech. 2014;27:1–10. doi: 10.1097/BSD.0b013e31825bd26d. [DOI] [PubMed] [Google Scholar]
- 21.Diebo BG, Scheer R, Rompala A, et al. The impact of osteoporosis on 2-year outcomes in patients undergoing long cervical fusion. J Am Acad Orthop Surg. 2023;31:e44–50. doi: 10.5435/JAAOS-D-22-00361. [DOI] [PubMed] [Google Scholar]
- 22.Opsenak R, Hanko M, Snopko P, Varga K, Kolarovszki B. Subsidence of anchored cage after anterior cervical discectomy. Bratisl Lek Listy. 2019;120:356–61. doi: 10.4149/BLL_2019_058. [DOI] [PubMed] [Google Scholar]
- 23.Anderson PA, Polly DW, Binkley NC, Pickhardt PJ. Clinical use of opportunistic computed tomography screening for osteoporosis. J Bone Joint Surg Am. 2018;100:2073–81. doi: 10.2106/JBJS.17.01376. [DOI] [PubMed] [Google Scholar]
- 24.Ji C, Yu S, Yan N, et al. Risk factors for subsidence of titanium mesh cage following single-level anterior cervical corpectomy and fusion. BMC Musculoskelet Disord. 2020;21:32. doi: 10.1186/s12891-019-3036-8. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 25.Bone densitometry [Internet] Baltimore (MD): The Johns Hopkins University; date unknown. [cited 2024 May 11]. Available from: https://www.hopkinsmedicine.org/health/treatment-tests-and-therapies/bone-densitometry . [Google Scholar]
- 26.Ahmed AI, Ilic D, Blake GM, Rymer JM, Fogelman I. Review of 3,530 referrals for bone density measurements of spine and femur: evidence that radiographic osteopenia predicts low bone mass. Radiology. 1998;207:619–24. doi: 10.1148/radiology.207.3.9609882. [DOI] [PubMed] [Google Scholar]
- 27.Jha S, Chapman M, Roszko K. When low bone mineral density and fractures is not osteoporosis. Curr Osteoporos Rep. 2019;17:324–32. doi: 10.1007/s11914-019-00529-7. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 28.Ordway NR, Lu YM, Zhang X, Cheng CC, Fang H, Fayyazi AH. Correlation of cervical endplate strength with CT measured subchondral bone density. Eur Spine J. 2007;16:2104–9. doi: 10.1007/s00586-007-0482-z. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 29.Kandziora F, Pflugmacher R, Scholz M, et al. Comparison between sheep and human cervical spines: an anatomic, radiographic, bone mineral density, and biomechanical study. Spine (Phila Pa 1976) 2001;26:1028–37. doi: 10.1097/00007632-200105010-00008. [DOI] [PubMed] [Google Scholar]
- 30.Anderst WJ, Thorhauer ED, Lee JY, Donaldson WF, Kang JD. Cervical spine bone mineral density as a function of vertebral level and anatomic location. Spine J. 2011;11:659–67. doi: 10.1016/j.spinee.2011.05.007. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 31.Lee CH, Kim KJ, Hyun SJ, Yeom JS, Jahng TA, Kim HJ. Subsidence as of 12 months after single-level anterior cervical inter-body fusion: is it related to clinical outcomes? Acta Neurochir (Wien) 2015;157:1063–8. doi: 10.1007/s00701-015-2388-6. [DOI] [PubMed] [Google Scholar]
- 32.Milczynska WM, Ahmad A, Ahmed AI, et al. Does titanium cage subsidence affect clinical outcomes in ACDF surgery?: a tertiary centre experience. Ann R Coll Surg Engl. 2023;105:378–83. doi: 10.1308/rcsann.2022.0050. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 33.Ryu HS, Han MS, Lee SS, Moon BJ, Lee JK. Influence of subsidence after stand-alone anterior cervical discectomy and fusion in patients with degenerative cervical disease: a long-term follow-up study. Medicine (Baltimore) 2022;101:e30673. doi: 10.1097/MD.0000000000030673. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 34.Wu WJ, Jiang LS, Liang Y, Dai LY. Cage subsidence does not, but cervical lordosis improvement does affect the long-term results of anterior cervical fusion with stand-alone cage for degenerative cervical disc disease: a retrospective study. Eur Spine J. 2012;21:1374–82. doi: 10.1007/s00586-011-2131-9. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 35.Oliver JD, Goncalves S, Kerezoudis P, et al. Comparison of outcomes for anterior cervical discectomy and fusion with and without anterior plate fixation: a systematic review and meta-analysis. Spine (Phila Pa 1976) 2018;43:E413–22. doi: 10.1097/BRS.0000000000002441. [DOI] [PubMed] [Google Scholar]
- 36.Shang P, Ma B, Hou G, et al. A novel artificial vertebral implant with Gyroid porous structures for reducing the subsidence and mechanical failure rate after vertebral body replacement. J Orthop Surg Res. 2023;18:828. doi: 10.1186/s13018-023-04310-6. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 37.Amirtharaj Mosas KK, Chandrasekar AR, Dasan A, Pakseresht A, Galusek D. Recent advancements in materials and coatings for biomedical implants. Gels. 2022;8:323. doi: 10.3390/gels8050323. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 38.Shen S, Hu Y, Chu Z, Dong W. Bone resorption of vertebral bodies at the operative segment after prevail cervical interbody fusion: a case report. Medicine (Baltimore) 2023;102:e35231. doi: 10.1097/MD.0000000000035231. [DOI] [PMC free article] [PubMed] [Google Scholar]
Associated Data
This section collects any data citations, data availability statements, or supplementary materials included in this article.
Supplementary Materials
Supplement 1. Demographics of subgroup of patients with preoperative CT scans.
Supplement 2. Univariable linear regression with anterior and posterior subsidence as outcome variables and bone density as the independent variable.
Supplement 3. Long-term anterior segmental subsidence and vertebrae bone density measurements.
Supplement 4. Long-term anterior segmental subsidence and ellipse density measurements.
Supplement 5. T-test comparing upper and lower vertebrae bone density for all three measurement methods in patients with and without prior osteopenia diagnosis.