Logo Medical Science Monitor

Call: +1.631.470.9640
Mon - Fri 10:00 am - 02:00 pm EST

Contact Us

Logo Medical Science Monitor Logo Medical Science Monitor Logo Medical Science Monitor

07 April 2022: Clinical Research  

Risk Factors for Poor Outcomes of Thoracic Ossification of Ligamentum Flavum After Laminectomy

Jiayuan Sun1ABCE, Peiyu Du1ABCDE, Yong Shen1ABF*

DOI: 10.12659/MSM.935711

Med Sci Monit 2022; 28:e935711

0 Comments

Abstract

BACKGROUND: Thoracic ossification of ligamentum flavum (TOLF) is a common pathological change of the thoracic ligamentum flavum. Identifying the risk factors for poor prognosis is critical for choosing suitable surgical methods.

MATERIAL AND METHODS: A total of 64 patients with TOLF after laminectomy were reviewed between January 2010 and April 2018 at the Department of Spine Surgery of the Third Hospital of Hebei Medical University. The Japanese Orthopaedic Association (JOA) scale was used to evaluate the neurological function of patients. According to the average JOA improvement rate, the patients were divided into the good prognosis group (Group GP) and the poor prognosis group (Group PP). Multivariate logistic regression analysis was used to identify the risk factors for poor outcomes.

RESULTS: The average JOA improvement rate was 53.04±24.29%. Group GP comprised 33 patients, while Group PP comprised 31 patients. Duration of preoperative symptoms (P=0.005), intramedullary high signal intensity (P=0.001), dural ossification rate (P=0.002), and sagittal configuration of ossification (P=0.012) were significantly higher in Group PP than in Group GP. Multivariate logistic analysis showed that duration of preoperative symptoms (P=0.022), intramedullary high signal intensity (P=0.010), dural ossification (P=0.007) and sagittal configuration of ossification (P=0.029) were risk factors for poor outcomes of TOLF after laminectomy.

CONCLUSIONS: After surgical treatment of TOLF, the symptoms of some patients either recovered slowly or did not recover. Longer than 17 months of preoperative symptoms, intramedullary high signal intensity, dural ossification, and sagittal configuration of ossification were the risk factors for poor outcomes of TOLF after laminectomy.

Keywords: Ligamentum Flavum, Osteogenesis, Spinal Cord Injuries, Decompression, Surgical, Humans, Laminectomy, Ossification, Heterotopic, Risk Factors, Thoracic Vertebrae

Background

Thoracic ossification of the ligamentum flavum (TOLF) is a pathological change of the thoracic ligamentum flavum in which the ligament tissue is replaced by new heterotopic bone tissue, and often appears in the lower thoracic vertebra, especially T9–T12. Ossification compresses the spinal cord, causing spinal cord compression symptoms [1–5]. In addition to the above symptoms, some patients also have root compression. However, separate nerve root stimulation is rarely observed [6]. Once the spinal cord is compressed by TOLF, the conservative treatment effect is poor, and surgery is the only effective method. Miyakoshi [7] found that the duration of symptoms before surgery was closely related to surgical prognosis. Hence, early detection, diagnosis, and treatment play an important role in prognosis of the disease. Traditional open surgery includes posterior laminectomy, laminectomy and internal fixation, and laminoplasty, of which laminectomy has become one of the classic operations [8–12]. In recent years, various minimally invasive techniques have been gradually applied for the treatment of TOLF [12,13]. Although various decompression operations have been applied for the treatment of TOLF, the postoperative efficacy is occasionally unsatisfactory, and the degree of postoperative recovery is also difficult to predict. Several studies have discussed the risk factors of TOLF, but no consensus has been reached [14]. Identifying the risk factors for poor prognosis is critical for choosing suitable surgical methods. In this study, we aimed to identify the risk factors for poor prognosis of laminectomy for TOLF to provide a theoretical basis for the selection and improvement of surgery.

Material and Methods

PATIENTS:

We retrospectively selected the patients diagnosed with TOLF who were treated by laminectomy at the Spine Surgery Department of the Third Hospital of Hebei Medical University between January 2010 and April 2018. Inclusion criteria were: 1. Patients diagnosed as TOLF and treated by laminectomy; 2. Complete clinical data available; 3. The last follow-up was ≥2 years. Exclusion criteria were: 1. Combined with anterior herniated disc that significantly compressed the spinal cord or nerve roots; 2. Combined with other spinal cord-related diseases; 3. Trauma, inflammation, infection, and tumor involvement of the spine; 4. Combined with severe cervical or lumbar nerve compression. A total of 64 patients were included in the study; the mean age was 59.31±6.79 years, with 39 males and 25 females. Among these, 44 patients underwent open laminectomy and 20 underwent open laminectomy with internal fixation. Patients with higher-than-average JOA improvement rate were assigned to the good prognosis group (Group GP), while patients with lower-than-average JOA improvement rate were assigned to the poor prognosis group (Group PP).

IMAGING AND CLINICAL EVALUATION:

Patients underwent 1.5-T thoracic I (SIEMENS MAGNETOM Symphony), 1-mm CT plain scan, and thoracic vertebrae X-rays in positive and lateral positions before the operation. During the follow-up, the patients underwent thoracic vertebrae X-rays in positive and lateral positions. The nerve function of the patients was evaluated by the Japanese Orthopaedic Association (JOA) score before the operation, at 2 weeks after operation, and at the final follow-up (Figure 1). The JOA score of thoracic nerve function (full score 11) was modified based on the JOA score of cervical spine [15] (full score 17) [16]. A score of 4 for ambidextrous dexterity and a score of 2 for both upper limbs were removed from the CERVICAL JOA score (Table 1). Evaluation of neurological function improvement rate at the last follow-up was calculated using the equation: JOA score improvement rate=(JOA score at the last follow-up–preoperative JOA score)/(11–preoperative JOA score)×100%. We recorded data on patients’ age, sex, duration of preoperative symptoms (months), follow-up duration (months), ossification segments, number of ossification segments, presence or absence of intramedullary high signal intensity in T2WI, presence or absence of dural ossification, previous basic medical history (hypertension, diabetes, heart disease, cerebrovascular disease), surgical method, and configurations of OLF in sagittal (beak or round) plane.

STATISTICAL ANALYSIS:

SPSS 22.0 (IBM, Armonk, NY, USA) statistical software was used for analysis, and the test level was α=0.05. The measurement data were compared between the 2 groups and analyzed by independent sample t test or Mann-Whitney U test according to their conformity with normal distribution and homogeneity of variance. Comparison of modified thoracic JOA scores before and during the last follow-up was performed by paired t test or Wilcoxon test. The count data were analyzed by chi-square test. Multivariate logistic regression analysis was used to identify prognostic factors associated with vertebral decompression in TOLF, and calculate relative risk (OR) and 95% confidence interval (95% CI). The factors with P<0.10 in univariate logistic regression were included in the multivariate logistic regression model. The ROC curve was used to determine the sensitivity, specificity, and cutoff value of preoperative symptom duration for poor postoperative symptom recovery.

Results

The mean preoperative symptom duration of the patients was 22.14±12.05 months, and the mean follow-up time was 31.85±7.66 months. All operations were successfully performed. In 1 patient, postoperative lower limb muscle strength was reduced from preoperative level IV to level II, which was treated with hormones and dehydration drugs. At the 24-month follow-up, the patient’s muscle strength returned to the preoperative level. The average preoperative JOA score was 5.03±1.49, and the JOA score at the last follow-up was 8.11±1.66, which was significantly higher than that before surgery (P<0.001). The average improvement rate was 53.04±24.29%. Among them, 33 patients had a higher-than-average improvement rate and were included in Group GP, while the other 31 patients had a lower-than-average improvement rate and were included in Group PP.

There were no statistically significant differences in age, sex, follow-up duration, ossification segments, number of ossification segments, previous history, or surgical method between Group GP and Group PP (Table 2). Two patients in Group GP had ossification in 3 vertebral bodies, 2 patients in Group PP had ossification in 3 vertebral bodies, and 2 patients had ossification in 4 vertebral bodies. The preoperative symptom duration of Group GP was 18.12±10.05 months, which was significantly lower than that of Group PP. Preoperative MRI of 29 patients in Group PP accompanied by intramedullary high signal intensity (93.55%) in T2WI was significantly higher than that of 19 patients in Group GP (57.58%) (Table 2). In the preoperative CT scan, 12 patients in Group PP were found to have dural ossification, while only 2 patients in Group GP were found to have dural ossification, and the difference between the 2 groups was statistically significant (Table 2). Sagittal configuration of ossification was also identified as a risk factor in this study, 8 (24.2%) patients had beak-type ossification in Group GP and 17 (54.8%) in Group PP, and the difference was also statistically significant.

In the univariate logistic regression analysis, 4 factors were included in the multivariate logistic model: preoperative symptom duration, intramedullary high signal intensity in T2WI, epidural ossification, and sagittal configuration of ossification. Multivariate logistic analysis found that preoperative duration of symptoms, intramedullary high signal intensity in T2WI, epidural ossification, and sagittal configuration of ossification were risk factors for poor prognosis of laminectomy for TOLF, and their OR and 95% CI were 1.078 (1.011–1.151), 16.016 (1.949–131.586), 13.999 (2.067–94.825), and 4.722 (1.168–19.088), respectively (Table 3). We also measured the sensitivity, specificity, and cutoff value of preoperative duration of symptoms. The results showed that preoperative duration of symptoms >17 months was a good predictor of poor postoperative recovery, with 74.2% sensitivity and 57.6% specificity.

Discussion

TOLF was previously thought to occur mainly in the elderly population, but with the development of imaging technology and the popularization of screening, TOLF have also been found in adolescents [17,18]. The onset of TOLF is often slow [19]; the first symptoms of most patients are lower-extremity symptoms and the patients often also have other spinal diseases, resulting in complex and variable symptoms, making it difficult to diagnose [20]. TOLF used to be thought to be mainly related to genetic and dietary factors; however, with the worldwide reports on the cases of TOLF, biomechanical factors are considered to be the most important cause of TOLF [21,22]. Once TOLF is diagnosed, conservative treatment is often ineffective and surgical laminectomy is required to relieve spinal cord compression and restore spinal function.

In this study, we included 64 patients with TOLF who underwent laminectomy. Long duration of preoperative symptoms, high signal of thoracic spinal cord, epidural ossification, and sagittal configuration of ossification were risk factors for poor prognosis. However, the prognostic factors of TOLF remain controversial. Inamasu [1] showed that sex, age, ossification degree, TOLF segment number, coexisting OPLL, CT classification, and intramedullary high signal intensity were not related to surgical prognosis, while the duration of symptoms or neurological score before surgery could not be used to predict prognosis due to inconsistent results. Ando [23] conducted a multi-center study and found that duration of preoperative symptoms, dural ossification, and type D ossification were associated with prognosis of surgery. He [24] showed that preoperative symptom duration and JOA score were important predictors of postoperative JOA score and recovery rate. Patients with gatism, patella and/or ankle clonus positive, and MRI high intramedullary signal had poor prognosis. Zhang [14] found that preoperative signal strength of thoracic spinal cord was highly predictive of poor prognosis.

Studies [25] have pointed out that long-term compression of the spinal cord leads to damage of the anterior horn of the spinal cord, interruption of the conduction pathway of the lumbosacral reflex center, preoperative incontinence, and lower JOA score. These patients have poor postoperative neurological recovery.

Our study found no significant difference in preoperative JOA score between the 2 groups, so the influence of preoperative JOA score on prognosis could not be evaluated. After laminectomy, the JOA score of the patients was significantly improved during follow-up compared with that before surgery, with an average improvement rate of 53.04±24.29%, indicating that laminectomy is an effective treatment for TOLF.

Different studies have drawn different conclusions about the effect of duration of symptoms before surgery. He et al [24] reported that early surgical intervention had a positive effect on prognosis, which was refuted by Hur Hyuk [26]. In this study, preoperative symptom duration was found to have a significant effect on prognosis, which was same as He et al. Moreover, our study found that the threshold for preoperative duration of symptoms was 17 months, which was similar to Chang et al [27]. This suggests that preoperative symptoms lasting longer than 17 months lead to poor postoperative prognosis, so early surgical intervention is the key to improve the prognosis of patients.

MRI is the most commonly used method for spinal cord evaluation, and it can clearly display the anatomical conditions of thoracal cord, compression, and signal changes. Studies [28] have shown that the incidence of intramedullary high signal intensity of patients with thoracic stenosis due to TOLF is 41–79%. In terms of the effect of T2-weighted intramedullary signal on surgical prognosis, it is generally believed that when the spinal cord at the affected segment is subjected to long-term compression and ischemia, it can show high signals in the MRI T2WI. Inamasu [1] believedthat the degree of spinal cord compression was significantly correlated with the intramedullary signal in T2WI. Our study also found a significant difference between the good and poor outcome groups (P=0.001).

Dural ossification is a common complication of TOLF. The ossified dura and ligamentum flavum form an integral whole, which significantly increases the risk of dural tear, cerebrospinal fluid leakage, and nerve root injury [12,29], and is one of the risk factors for poor prognosis. Wang et al [11] found that the volume of the thoracic spinal canal was smaller than that of cervical and lumbar canals, and the thoracal cord blood supply was less due to its fewer anastomosis branches, and the ability of collateral circulation to supply blood was poor, so the tolerance to ossification compression was poor. Even if there is no dural ossification, the dura is often associated with ossification and should be carefully explored while removing ossification. If adhesion occurs, the dura should be carefully and gently separated to reduce the incidence of epidural tear.

We also found that the sagittal configuration of ossification had a significant effect on the operative prognosis, and the beak-type patients had poor postoperative neurological recovery. We hypothesized that this may be because beak-type ossification acts like an awl on the spinal cord, which increases the difficulty of surgery and generally puts more pressure on the spinal cord, which is the same as Sung UkKuh’s view [30]. However, Li et al [31] found that the sagittal configuration of patients’ ossification had no effect on postoperative prognosis, and Kang et al [10] suggested that patients with beaks have a better prognosis. These differences may be due to the insufficient sample size and the difference among surgeons, which leads to different results. Hence, further study is needed.

This study had some limitations. 1. This was a retrospective and single-center study with a small sample size, especially in the minimally invasive group. Hence, a multi-center study with a large sample size is needed to confirm our findings. 2. The longest duration of neurological function recovery after TOLF is unclear, so the minimum follow-up time of 2 years in our study may be insufficient.

Conclusions

In conclusion, some of the patients did not experience the expected effect, and our study found that longer than 17 months of preoperative symptoms, intramedullary high signal intensity, dural ossification, and sagittal configuration of ossification were the risk factors for poor outcomes of TOLF after laminectomy. According to the results, we need more complete evaluation of patients’ preoperative status and radiologic features to predict the surgical outcome for TOLF.

References

1. Inamasu J, Guiot BH, A review of factors predictive of surgical outcome for ossification of the ligamentum flavum of the thoracic spine: J Neurosurg Spine, 2006; 5(2); 133-39

2. Huo X, Zhou J, Liu S, Clinical efficacy of single intraoperative 500 mg methylprednisolone management therapy for thoracic myelopathy caused by ossification of the ligamentum flavum: BMC Musculoskel Disord, 2020; 21(1); 177

3. Kawaguchi Y, Yasuda T, Seki S, Variables affecting postsurgical prognosis of thoracic myelopathy caused by ossification of the ligamentum flavum: Spine J, 2013; 13(9); 1095-107

4. Yayama T, Uchida K, Kobayashi S, Thoracic ossification of the human ligamentum flavum: histopathological and immunohistochemical findings around the ossified lesion: J Neurosurg Spine, 2007; 7(2); 184-93

5. Ono K, Yonenobu K, Miyamoto S, Pathology of ossification of the posterior longitudinal ligament and ligamentum flavum: Clin Orthop Relat Res, 1999(359); 18-26

6. Renjith KR, Shetty AP, Kanna PR, Spinal melorheostosis: A rare cause for thoracic radiculopathy: Int J Spine Surg, 2020; 14(2); 209-12

7. Miyakoshi N, Shimada Y, Suzuki T, Factors related to long-term outcome after decompressive surgery for ossification of the ligamentum flavum of the thoracic spine: J Neurosurg, 2003; 99(3 Suppl); 251-56

8. Zhao Y, Xue Y, Shi N, The CT and intraoperative observation of pedicel-ossification tunnel in 151 cases of thoracic spinal stenosis from ossification of ligamentum flavum: Eur Spine J, 2014; 23(6); 1325-31

9. Chen HJ, Liu ZQ, Hu JSurgical treatment of thoracic ossification of ligamentum flavum and therapeutic effects analysis: Zhongguo Gu Shang, 2010; 23(9); 701-3 [in Chinese]

10. Kang KC, Lee CS, Shin SK, Ossification of the ligamentum flavum of the thoracic spine in the Korean population: J Neurosurg Spine, 2011; 14(4); 513-19

11. Wang H, Wei F, Long H, Surgical outcome of thoracic myelopathy caused by ossification of ligamentum flavum: J Clin Neurosci, 2017; 45; 83-88

12. Wang H, Ma L, Xue R, The incidence and risk factors of postoperative neurological deterioration after posterior decompression with or without instrumented fusion for thoracic myelopathy: Medicine, 2016; 95(49); e5519

13. Baba S, Oshima Y, Iwahori T, Microendoscopic posterior decompression for the treatment of thoracic myelopathy caused by ossification of the ligamentum flavum: A technical report: Eur Spine J, 2016; 25(6); 1912-19

14. Zhang J, Wang L, Li J, Predictors of surgical outcome in thoracic ossification of the ligamentum flavum: Focusing on the quantitative signal intensity: Sci Rep, 2016; 6; 23019

15. Yukawa Y, Kato F, Ito K, Postoperative changes in spinal cord signal intensity in patients with cervical compression myelopathy: Comparison between preoperative and postoperative magnetic resonance images: J Neurosurg Spine, 2008; 8(6); 524-28

16. Sato T, Kokubun S, Tanaka Y, Thoracic myelopathy in the Japanese: Epidemiological and clinical observations on the cases in Miyagi Prefecture: Tohoku J Exp Med, 1998; 184(1); 1-11

17. Lang N, Yuan HS, Wang HL, Epidemiological survey of ossification of the ligamentum flavum in thoracic spine: CT imaging observation of 993 cases: Eur Spine J, 2013; 22(4); 857-62

18. Moon BJ, Kuh SU, Kim S, Prevalence, distribution, and significance of incidental thoracic ossification of the ligamentum flavum in Korean patients with back or leg pain: mr-based cross sectional study: J Korean Neurosurg Soc, 2015; 58(2); 112-18

19. Shiokawa K, Hanakita J, Suwa H, Clinical analysis and prognostic study of ossified ligamentum flavum of the thoracic spine: J Neurosurg, 2001; 94(2 Suppl); 221-26

20. Fujimoto K, Kanchiku T, Imajo Y, Neurologic findings caused by ossification of ligamentum flavum at the thoracolumbar junction: J Spinal Cord Med, 2017; 40(3); 316-20

21. Fukuyama S, Nakamura T, Ikeda T, The effect of mechanical stress on hypertrophy of the lumbar ligamentum flavum: J Spinal Disord, 1995; 8(2); 126-30

22. Wang ZL, Yuan HF, Ding HQThe clinical causes of the thoracic ossification of ligamentum flavum: Zhonghua Wai Ke Za Zhi, 2006; 44(20); 1376-80 [in Chinese]

23. Ando K, Imagama S, Ito Z, Predictive factors for a poor surgical outcome with thoracic ossification of the ligamentum flavum by multivariate analysis: A multicenter study: Spine, 2013; 38(12); E748-54

24. He S, Hussain N, Li S, Clinical and prognostic analysis of ossified ligamentum flavum in a Chinese population: J Neurosurg Spine, 2005; 3(5); 348-54

25. Sanghvi AV, Chhabra HS, Mascarenhas AA, Thoracic myelopathy due to ossification of ligamentum flavum: A retrospective analysis of predictors of surgical outcome and factors affecting preoperative neurological status: Eur Spine J, 2011; 20(2); 205-15

26. Hur H, Lee JK, Lee JH, Thoracic myelopathy caused by ossification of the ligamentum flavum: J Korean Neurosurg Soc, 2009; 46(3); 189-94

27. Chang UK, Choe WJ, Chung CK, Surgical treatment for thoracic spinal stenosis: Spinal Cord, 2001; 39(7); 362-69

28. Kägi S, Ciurea A, Micheroli R, Ossification of the ligamentum flavum: Rheumatology (Oxford, England), 2020; 59(7); 1616

29. Sun XZ, Chen ZQ, Qi Q, Diagnosis and treatment of ossification of the ligamentum flavum associated with dural ossification: Clinical article: J Neurosurg Spine, 2011; 15(4); 386-92

30. Kuh SU, Kim YS, Cho YE, Contributing factors affecting the prognosis surgical outcome for thoracic OLF: Eur Spine J, 2006; 15(4); 485-91

31. Li Z, Ren D, Zhao Y, Clinical characteristics and surgical outcome of thoracic myelopathy caused by ossification of the ligamentum flavum: A retrospective analysis of 85 cases: Spinal Cord, 2016; 54(3); 188-96

In Press

18 Mar 2024 : Clinical Research  

Sexual Dysfunction in Women After Tibial Fracture: A Retrospective Comparative Study

Med Sci Monit In Press; DOI: 10.12659/MSM.944136  

0:00

21 Feb 2024 : Clinical Research  

Potential Value of HSP90α in Prognosis of Triple-Negative Breast Cancer

Med Sci Monit In Press; DOI: 10.12659/MSM.943049  

22 Feb 2024 : Review article  

Differentiation of Native Vertebral Osteomyelitis: A Comprehensive Review of Imaging Techniques and Future ...

Med Sci Monit In Press; DOI: 10.12659/MSM.943168  

23 Feb 2024 : Clinical Research  

A Study of 60 Patients with Low Back Pain to Compare Outcomes Following Magnetotherapy, Ultrasound, Laser, ...

Med Sci Monit In Press; DOI: 10.12659/MSM.943732  

Most Viewed Current Articles

16 May 2023 : Clinical Research  

Electrophysiological Testing for an Auditory Processing Disorder and Reading Performance in 54 School Stude...

DOI :10.12659/MSM.940387

Med Sci Monit 2023; 29:e940387

0:00

17 Jan 2024 : Review article  

Vaccination Guidelines for Pregnant Women: Addressing COVID-19 and the Omicron Variant

DOI :10.12659/MSM.942799

Med Sci Monit 2024; 30:e942799

0:00

14 Dec 2022 : Clinical Research  

Prevalence and Variability of Allergen-Specific Immunoglobulin E in Patients with Elevated Tryptase Levels

DOI :10.12659/MSM.937990

Med Sci Monit 2022; 28:e937990

0:00

01 Jan 2022 : Editorial  

Editorial: Current Status of Oral Antiviral Drug Treatments for SARS-CoV-2 Infection in Non-Hospitalized Pa...

DOI :10.12659/MSM.935952

Med Sci Monit 2022; 28:e935952

0:00

Your Privacy

We use cookies to ensure the functionality of our website, to personalize content and advertising, to provide social media features, and to analyze our traffic. If you allow us to do so, we also inform our social media, advertising and analysis partners about your use of our website, You can decise for yourself which categories you you want to deny or allow. Please note that based on your settings not all functionalities of the site are available. View our privacy policy.

Medical Science Monitor eISSN: 1643-3750
Medical Science Monitor eISSN: 1643-3750