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Adjacent Segment Pathology: Much to Do About How Much Is Due to What We Do

Published online by Cambridge University Press:  09 September 2016

Daryl R. Fourney*
Affiliation:
Division of NeurosurgeryUniversity of SaskatchewanSaskatoon, Saskatchewan, Canada
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Abstract

Type
Editorial
Copyright
Copyright © The Canadian Journal of Neurological Sciences Inc. 2016 

A few years ago, I was part of a study group on adjacent segment degeneration in the cervical spine. We suggested a change in terminology from “adjacent segment degeneration” to “adjacent segment pathology” (ASP) to reflect the fact that it was unclear how much of the changes seen in regions of the spine adjacent to surgical fusion are “iatrogenic” versus “degenerative” in nature.Reference Anderson, Andersson and Arnold 1 Are these findings a normal occurrence with age, or are they due to mechanical factors at play at the proximal and distal ends of a fusion? If it is the latter, how do we modify our interventions to decrease its incidence? This debate has been intensified in the past decade as long-term studies suggest lower rates of ASP and secondary procedures after cervical disc arthroplasty (CDA) versus traditional anterior cervical discectomy and fusion (ACDF).Reference Hu, Lv, Ren and Johansen 2 The following are my thoughts on the subject, with some reflections on the interesting work reported by Jack et alReference Jack, Hardy St-Pierre and Nataraj 3 in this issue of The Journal.

There are three types of ASP: radiographic ASP (RASP), clinical ASP (CASP), and reoperation ASP (ReopASP). Just because you have radiographic evidence of ASP does not mean you necessarily have symptoms, and just because you have symptoms doesn’t necessarily mean you need surgery. On the surface, this seems like a straightforward set of definitions. Unfortunately, there is substantial heterogeneity among studies because of variance in terms and their precise application. There are at least seven classification systems for ASP, but none is universally agreed upon, and they have not been tested for reliability or validity.Reference Kraemer, Fehlings and Hashimoto 4

As a result, a recent meta-analysis found the prevalence of RASP ranged from 4.74% to 92.22% across 35 studies and the prevalence of CASP ranged between 0% and 54.55% across 24 studies.Reference Kong, Cao, Wang and Shen 5 You would think that a concept as clear as “reoperation” would provide more precise comparisons. However, there was still significant heterogeneity across 52 reports included in the meta-analysis, with ReopASP ranging from 0% to 16.90%.Reference Kong, Cao, Wang and Shen 5

The length of follow-up certainly affects the prevalence of ASP, but not enough to account for this degree of variation. The development of RASP, CASP, and ReopASP is estimated to increase by 2.79%, 1.43%, and 0.24% per year, respectively.Reference Kong, Cao, Wang and Shen 5

Another confounding element in the analysis of ASP in the cervical spine is that it occurs most often at C5/6 or C6/7. As a result, patients who undergo a single-level procedure adjacent to these levels are at higher risk. This explains the paradoxically lower prevalence of ASP after multilevel cervical fusion that includes these levels in comparison to single-level fusion.Reference Kong, Cao, Wang and Shen 5 - Reference Lawrence, Hilibrand, Brodt, Dettori and Brodke 7

With this background in mind, I would like to comment on the study by Jack et al.Reference Jack, Hardy St-Pierre and Nataraj 3 It is important to point out that, in this study, ReopASP was used as a surrogate for CASP, which is a limitation of many retrospective studies.

Although most cervical fusion is performed in older patients with degenerative conditions, some occurs in other clinical settings. The hypothesis is that if ASP is largely secondary to natural age-related degeneration and is not the biomechanical effect of fusion, we should observe a lower rate of ASP in populations where these is a lesser degree of preexisting degeneration. Jack et alReference Jack, Hardy St-Pierre and Nataraj 3 and othersReference Song, Choi, Kim and Song 8 - Reference Goffin, van Loon, Van Calenbergh and Plets 10 used a trauma cohort, and cervical ASP has also been studied in Klippel-Feil syndrome.Reference Lee, Dettori, Standaert, Ely and Chapman 11

The prevalence of RASP in the trauma cohort studied by Jack et al was only 1/32 (3.1%). This is remarkably low compared with other published trauma cohorts, which range from 5.2% at 2.5 yearsReference Song, Choi, Kim and Song 8 to 60.0% at 7 years,Reference Goffin, van Loon, Van Calenbergh and Plets 10 but may be at least partially explained by the fact that radiologic follow-up was only 13 months.Reference Jack, Hardy St-Pierre and Nataraj 3

Jack et alReference Jack, Hardy St-Pierre and Nataraj 3 compared a trauma cohort to a degenerative cohort at their center, thus hopefully eliminating many of the problems with between-study comparisons. Unfortunately, there were still major differences between groups that likely introduced significant bias. The trauma group was overwhelmingly male and slightly younger than the degenerative group. Furthermore, the trauma group included some multilevel, posterior, and circumferential fusions, whereas the degenerative group was strictly single-level ACDF. There is evidence that posterior fusion significantly increases adjacent segment stress in comparison to anterior fusions.Reference Lee and Langrana 12 All patients in the degenerative group had imaging performed at a median 33 months postoperatively to evaluate for RASP, whereas only 70% of the trauma group had imaging done at a much shorter median 13 months postoperatively. Although the clinical follow-up (to assess ReopASP, which Jack et al call CSAP) was similar between groups (6.4 for trauma and 7.1 for degenerative), the difference did achieve statistical significance. Finally, patients in the trauma cohort but not the degenerative cohort were contacted by phone to see if they had undergone reoperation elsewhere. How much each of these factors may have biased the results one way or the other is debatable.

These differences between groups are only those that were obvious, based on the stated methods. Given the difference in the actual disease etiology (i.e. trauma vs. degenerative), there are likely to be other dissimilarities that are not measured or are frankly unknown. This is the sort of existential crisis a study starts to suffer from when you try to compare apples with oranges.

The most often cited clinical evidence for ASP not being a “fusion disease” does not wander out of the degenerative sphere. GoreReference Gore 13 assessed the natural history of cervical spondylosis in 159 asymptomatic patients and found that 12% developed symptoms over 10 years. HerkowitzReference Herkowitz 14 evaluated patients with cervical radiculopathy after ACDF or posterior foraminotomy without fusion. At a mean of 4.2 years, the rate of RASP was 39% after ACDF and 50% after foraminotomy at the operated or adjacent level.

In summary, the debate rages on. But despite the findings of Jack et al,Reference Jack, Hardy St-Pierre and Nataraj 3 the pendulum these days seems to be swinging in favor of the “iatrogenic” camp,Reference Lee, Dettori, Standaert, Brodt and Chapman 15 as evidenced by the growing use of CDA. I think that this is somewhat misguided because ASP can complicate either ACDF or CDA. A recent meta-analysis by Shriver et alReference Shriver, Lubelski, Sharma, Steinmetz, Benzel and Mroz 16 reported that more than 2 years after CDA, the rate of RASP was 16.6% (range, 5.8%-27.4%) and CASP±ReopASP was 2.6% (1.0%-4.2%).

To my mind, until the etiology and natural history of ASP is better understood, decision-making around the type of surgery (e.g. decompression, fusion, instrumentation, “motion-sparing device”) should be largely dependent on factors other than ASP.

Disclosures

The author has nothing to disclose.

References

1. Anderson, PA, Andersson, GB, Arnold, PM, et al. Terminology. Spine. 2012;37:S8-S9.Google Scholar
2. Hu, Y, Lv, G, Ren, S, Johansen, D. Mid- to long-term outcomes of cervical disc arthroplasty versus anterior cervical discectomy and fusion for treatment of symptomatic cervical disc disease: a systematic review and meta-analysis of eight prospective randomized controlled trials. PloS One. 2016;11:e0149312.Google Scholar
3. Jack, A, Hardy St-Pierre, G, Nataraj, A. Adjacent segment pathology: progressive disease course or a product of iatrogenic fusion? Can J Neurol Sci. 2016. doi:dx.doi.org/10.1017/cjn.2016.293.CrossRefGoogle Scholar
4. Kraemer, P, Fehlings, MG, Hashimoto, R, et al. A systematic review of definitions and classification systems of adjacent segment pathology. Spine. 2012;37:S31-S39.Google Scholar
5. Kong, L, Cao, J, Wang, L, Shen, Y. Prevalence of adjacent segment disease following cervical spine surgery: a PRISMA-compliant systematic review and meta-analysis. Medicine. 2016;95:e4171.Google Scholar
6. Hilibrand, AS, Carlson, GD, Palumbo, MA, Jones, PK, Bohlman, HH. Radiculopathy and myelopathy at segments adjacent to the site of a previous anterior cervical arthrodesis. J Bone Jt Surg Am. 1999;81:519-528.Google Scholar
7. Lawrence, BD, Hilibrand, AS, Brodt, ED, Dettori, JR, Brodke, DS. Predicting the risk of adjacent segment pathology in the cervical spine: a systematic review. Spine. 2012;37:S52-S64.Google Scholar
8. Song, KJ, Choi, BW, Kim, GH, Song, JH. Usefulness of polyetheretherketone (PEEK) cage with plate augmentation for anterior arthrodesis in traumatic cervical spine injury. Spine J. 2010;10:50-57.Google Scholar
9. Koller, H, Reynolds, J, Zenner, J, et al. Mid- to long-term outcome of instrumented anterior cervical fusion for subaxial injuries. Eur Spine J. 2009;18:630-653.Google Scholar
10. Goffin, J, van Loon, J, Van Calenbergh, F, Plets, C. Long-term results after anterior cervical fusion and osteosynthetic stabilization for fractures and/or dislocations of the cervical spine. J Spinal Disord. 1995;8:500-508; discussion 499.Google Scholar
11. Lee, MJ, Dettori, JR, Standaert, CJ, Ely, CG, Chapman, JR. Indication for spinal fusion and the risk of adjacent segment pathology: does reason for fusion affect risk? A systematic review. Spine. 2012;37:S40-S51.CrossRefGoogle ScholarPubMed
12. Lee, CK, Langrana, NA. Lumbosacral spinal fusion. A biomechanical study. Spine. 1984;9:574-581.Google Scholar
13. Gore, DR. Roentgenographic findings in the cervical spine in asymptomatic persons: a ten-year follow-up. Spine. 2001;26:2463-2466.Google Scholar
14. Herkowitz, HN. A comparison of anterior cervical fusion, cervical laminectomy, and cervical laminoplasty for the surgical management of multiple level spondylotic radiculopathy. Spine. 1988;13:774-780.Google Scholar
15. Lee, MJ, Dettori, JR, Standaert, CJ, Brodt, ED, Chapman, JR. The natural history of degeneration of the lumbar and cervical spines: a systematic review. Spine. 2012;37:S18-S30.Google Scholar
16. Shriver, MF, Lubelski, D, Sharma, AM, Steinmetz, MP, Benzel, EC, Mroz, TE. Adjacent segment degeneration and disease following cervical arthroplasty: a systematic review and meta-analysis. Spine J. 2016;16:168-181.CrossRefGoogle ScholarPubMed