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In This Article

  • Summary
  • Abstract
  • Introduction
  • Protocol
  • Results
  • Discussion
  • Disclosures
  • Acknowledgements
  • Materials
  • References
  • Reprints and Permissions

Summary

This study investigates the efficacy of combining separation surgery with radiofrequency ablation and radiotherapy in treating thoracolumbar metastatic tumors.

Abstract

The spine is a common site for metastatic tumors, with 5%-10% of patients developing epidural spinal cord compression (ESCC), which significantly reduces their quality of life and accelerates the process of death. When total en-bloc spondylectomy (TES) radical surgery does not achieve the desired tumor control, palliative care remains the primary treatment option. Traditional laminar decompression or partial tumor resection can only relieve local compression. Although the surgical trauma and complications are less, these methods cannot effectively address tumor recurrence and secondary compression. Therefore, separation surgery combined with radiofrequency ablation and bone cement strengthening was used to treat thoracolumbar metastatic tumors, aiming to achieve good clinical results. In this protocol, the steps and key points of separation surgery combined with radiofrequency ablation and bone cement reinforcement for thoracolumbar metastatic tumors are introduced in detail. Meanwhile, the clinical data of 67 cases of thoracolumbar metastatic tumors in our hospital meeting the inclusion criteria were retrospectively analyzed. Different treatment methods divided the patients into two groups: separation surgery combined with radiofrequency ablation and bone cement strengthening (group A, 33 cases) and the radiotherapy group (group B, 34 cases). All patients were evaluated using improved Tokuhashi, Tomita, SINS, and ESCC scores before treatment. VAS score, Frankel grading, and Karnofsky scores during different periods of the two treatments were compared to assess the clinical outcomes. Studies have shown that separation surgery combined with radiofrequency ablation and bone cement strengthening can significantly reduce pain, promote neurological function recovery, enhance mobility, and improve quality of life in treating thoracolumbar metastatic tumors.

Introduction

With the development of precision medicine, the survival rate of patients with malignant tumors has gradually increased, and the incidence of bone metastasis has also risen significantly. Spinal metastasis is the most common occurrence in patients with malignant tumors, accounting for approximately 60%-70%. Among these, 5%-10% of patients will suffer from epidural spinal cord compression (ESCC)1,2, which can result in bone-related events, such as localized pain, hypercalcemia, spinal instability, pathological fractures, spinal cord and nerve root compression, and other clinical symptoms. About 50% of patients will suffer from neurological dysfunction3, which dramatically reduces their quality of life and accelerates death.

The diagnosis and treatment of spinal metastases require multidisciplinary collaboration. Treatment of the primary tumor is fundamental, and surgical intervention plays a vital role in managing spinal metastases. The objectives of surgical treatment are to relieve pain, rebuild spinal stability, improve neurological function, control local tumor lesions, enhance the patient's quality of life, provide conditions for further treatments such as radiotherapy, chemotherapy, and immunotherapy, and even prolong life4. Conventional laminectomy or partial tumor resection only relieves local compression. Although the surgical trauma is minor and the incidence of surgical complications is low, these methods cannot effectively address tumor recurrence and secondary compression5.

Separation surgery involves performing a 360° annular decompression around the compressed spinal dura mater to ensure a safe gap of about 5-8 mm between the spinal dura mater and the tumor tissue for radiotherapy. Bone cement is used to separate the anterior affected vertebra, tumor body, and dura mater. Several clinical studies have shown6,7,8,9 that separation surgery combined with stereotactic radiotherapy has achieved satisfactory clinical efficacy in treating spinal metastatic tumors. However, there are issues such as significant surgical trauma, excessive bleeding, and re-progression of vertebral tumors after resection, which affect its therapeutic efficacy.

In clinical practice, our team observed that during separation surgery for spinal metastases, patients were prone to local progression of vertebral tumors and recurrent nerve compression symptoms while waiting for the incision to heal for subsequent radiotherapy. Radiofrequency ablation (RFA) is a minimally invasive treatment method widely used in clinical tumor hyperthermia. It uses biological heat generated during friction and ion collision to kill local tumor cells and coagulate the surrounding vascular tissues to form a reaction zone, thus destroying their blood supply10.

Therefore, separation surgery combined with radiofrequency ablation and bone cement reinforcement was used to treat thoracolumbar metastatic tumors. In this technical report, the steps and key points of separation surgery combined with radiofrequency ablation and bone cement reinforcement for thoracolumbar metastatic tumors are described in detail. Additionally, the clinical data of 67 patients with thoracolumbar metastases who met the inclusion criteria and were admitted to the General Hospital of Ningxia Medical University from January 2019 to January 2023 were retrospectively analyzed. These patients were categorized into two groups based on the different treatment approaches. The clinical efficacy of separation surgery combined with radiofrequency ablation and bone cement strengthening (group A, 33 cases) and the radiation therapy group (group B, 34 cases) in thoracolumbar metastatic tumors was evaluated using various observation indicators. This analysis provides a basis for selecting clinical treatment methods for spinal metastatic tumors.

A retrospective analysis was performed on 67 patients with thoracolumbar metastases who met the inclusion criteria and were admitted to our hospital from January 2019 to January 2023. The patients were divided into two groups based on different treatment methods: separation surgery combined with radiofrequency ablation and bone cement strengthening (group A, 33 cases) and the radiotherapy group (group B, 34 cases). The two groups were evaluated for age, gender, primary tumor, time of primary tumor occurrence, affected vertebral body, ESCC score, SINS score, Tomita score, and Tokuhashi score4. There was no statistical significance (P > 0.05) in these variables, indicating that the clinical baseline data were consistent between the two groups (Table 1).

Protocol

This study was conducted in accordance with the principles of the Declaration of Helsinki, and the study protocol was approved by the Institutional Review Board (IRB). All patients and guardians provided written informed consent. Inclusion criteria: (1) Thoracolumbar metastatic tumor confirmed by preoperative imaging and puncture biopsy; (2) ESCC classification of spinal cord compression greater than 1a; (3) Expected survival time of the patients ≥3 months as assessed by the modified Tokuhashi score and Tomita score4. Exclusion criteria: (1) Primary spinal tumors; (2) Patients with poor general condition or severe medical diseases who could not tolerate general anesthesia and surgery; (3) Patients with poor adherence and incomplete clinical data. The reagents and equipment used are listed in the Table of Materials.

1. Preoperative preparation

  1. Perform the diagnosis of thoracolumbar metastasis through preoperative imaging, H&E staining, and immunohistochemical staining11, as shown in Figure 1.
    NOTE: H&E staining and immunohistochemical staining for CK7, TTF-1, Ki67, CKpan, and P40 were carried out according to the standard operating procedure11.
  2. Use preoperative X-ray, CT, and MRI to evaluate the lesion site and fully understand the anatomy of local spinal lesions and adjacent segments, as shown in Figure 2.
  3. Before surgery, perform an electrocardiogram, SPECT/CT, and chest CT (Figure 3), and exclude patients with contraindications for surgery and anesthesia.
    NOTE: Patients and their families should be fully informed of surgery-related risks and complications before surgery, and surgery-related consent should be signed.

2. Treatment procedure

  1. Surgical process for separation surgery combined with radiofrequency ablation and bone cement strengthening
    1. Incision and exposure: Use C-arm fluoroscopy to locate the affected vertebra. Make a 10 cm longitudinal incision, cut through the subcutaneous and lumbar dorsal fascia using the posterior median incision, and push the paravertebral muscles to both sides to reveal the spinous process, lamina, articular process, and transverse process of the upper and lower vertebrae centered on the affected vertebra, as shown in Figure 4A.
    2. Pedicle screw implantation: Locate the pedicle screw insertion position of the upper and lower two vertebrae of the affected vertebrae using the transversal-midpoint method12, and screw in the pedicle screw sequentially by drilling, tapping, and probing the wall (Figure 4B).
      NOTE: The screw's position was verified satisfactorily using C-arm fluoroscopy. For osteoporosis or micro-metastatic lesions in the upper and lower vertebrae of the affected vertebrae, 1.5-2 mL of bone cement was injected through the pedicle screw channel to strengthen the vertebrae.
    3. Radiofrequency ablation: Remove the vertebral lamina and bilateral facet joints of the compression segment using an ultrasonic bone knife and establish a working pathway through the pedicle approach of the affected vertebra.
      1. Connect the radiofrequency ablation instrument and radiofrequency needle, and insert the radiofrequency needle into the lesion of the affected vertebra. Set the bare area of the electrode needle at 1-1.5 cm according to the tumor size and vertebral body size.
      2. Perform radiofrequency ablation for 10-15 min, maintaining the radiofrequency central temperature at 80-100 °C, as shown in Figure 4B.
        NOTE: The radiofrequency time was adjusted according to intraoperative conditions.
    4. Cement reinforcement of the affected vertebra: Push the bone cement into the vertebra about 3-4 mL under fluoroscopy via the established working pathway in step 3.1.3, as shown in Figure 4C,D.
      NOTE: The bone cement that did not enter the vertebral canal was satisfactory.
    5. Separation surgery: Expose the anterior part of the spinal dura mater through the pedicle approach, and carefully remove the tumor tissue attached to the dorsal and ventral sides of the dura mater.
      1. Remove the adjacent intervertebral disc and posterior longitudinal ligament above and below the affected vertebra, and remove part of the vertebra using an ultrasonic bone knife to reach the filled bone cement.
      2. Perform 360° annular decompression around the spinal cord to ensure a safe gap of more than 5 mm between the dura mater and tumor tissue, as shown in Figure 4E.
  2. Radiotherapy procedure
    1. According to the location and scope of the spinal metastatic tumor, perform an enhanced CT scan to locate the tumor and map the target area with an MRI. Apply a three-dimensional planning design to ensure that the tumor receives a sufficient radiation dose while protecting the spinal cord and other vital organs.
      NOTE: The target area includes the metastatic vertebral body, bilateral pedicle, spinous process, and transverse process, and the external expansion of 0.5 cm forms a Planning Target Volume (PTV). Use Volumetric Modulated Arc Therapy (VMAT) with 6 MV-X beams12, as shown in Figure 5. 8 Gy per session can also be given to patients with a poor general condition, difficulty in mobility, in multiple rounds of radiotherapy, or with a short life expectancy. For single bone metastases with good prognoses, such as breast cancer and prostate cancer, if the primary tumor is well controlled, stereotactic radiotherapy or intensity-modulated radiotherapy technology should be used whenever possible, as it can effectively increase the local radiation dose and improve the tumor control rate.

3. Postoperative management

  1. Administer antibiotic prophylaxis within 24 h after surgery. Monitor the patient's vital signs, as well as the sensation and movement of both lower limbs. Follow-up with X-rays after surgery, as shown in Figure 6.
    NOTE: If the drainage volume is less than 50 mL, remove the drainage tube. One week after the operation, wear a thoracolumbar fixation brace for ground movement and focus on functional exercises during bed rest to prevent complications.

4. Statistical analysis

  1. Analyze the data using SPSS software. Describe measurement data that meet the normal distribution using means ± standard deviation.
  2. Conduct a one-way analysis of variance to compare measurement data between groups. Use the Kruskal-Wallis H non-parametric test for data that do not meet the normal distribution.
  3. Express counting data as rates (%) and compare them between groups using the Chi-square test. Consider a p-value of <0.05 as statistically significant.

Results

This study aimed to investigate the efficacy of combining separation surgery with radiofrequency ablation and radiotherapy in treating thoracolumbar metastatic tumors. The representative images of the treatment procedure, as well as pre- and postoperative evaluation, are presented in Figure 1, Figure 2, Figure 3, Figure 4, Figure 5, and Figure 6

Discussion

Although the Tokuhashi score, Tomita score, SINS score, and ESCC score provide a solid evidence-based medical basis for selecting surgical treatment for patients with spinal metastatic tumors, developing an individualized and accurate treatment plan for patients remains a complex problem. Multidisciplinary comprehensive treatment methods are used, including traditional open surgery, minimally invasive surgery, radiotherapy, chemotherapy, and immunotherapy. Roy A. Patchell et al.14 designed a rando...

Disclosures

The authors have nothing to disclose.

Acknowledgements

None.

Materials

NameCompanyCatalog NumberComments
Bone cementTecres S.P.A1230
CArm Xmedical equipmentSiemens HealthcareCios Spin
CT machineSiemens HealthcareSOMATOM Force
MRI machineSiemens HealthcareMAGNETOM Terra
Pedicle screwsShandong Weigao Medical Equipment Co., LTDPremier-6.6mm*45mm
Radio-frequency ablation instrumentMianyang Leading Electronic Technology Co.,ltd.LDRF-120S
Radiofrequency ablation needleMianyang Leading Electronic Technology Co.,ltd.RFDJ03
Radiofrequency Ablation NeedleVarian ClinacIX
Ultrasonic Osteotome SystemMisonix INCMXB-10
X-ray machinePhilips Investment Co., LTD. Medical systemXR/a

References

  1. Yang, T., et al. Clinical guidelines for microwave ablation of spinal metastases. J Cancer Res Ther. 18 (7), 1845-1854 (2022).
  2. Shah, S., et al. Management of metastatic spinal cord compression in secondary care: A practice reflection from Medway Maritime Hospital, Kent, UK. J Pers Med. 11 (2), 110 (2021).
  3. Wänman, J., et al. Metastatic spinal cord compression as the first sign of malignancy. Acta Orthop. 88 (4), 457-462 (2017).
  4. Sullivan, P. Z., et al. Evolution of surgical treatment of metastatic spine tumors. J Neurooncol. 157 (2), 277-283 (2022).
  5. Jones, M., et al. En Bloc resection of tumors of the lumbar spine: A systematic review of outcomes and complications. Int J Spine Surg. 15 (6), 1223-1233 (2021).
  6. Lockney, D. T., et al. Spinal stereotactic body radiotherapy following intralesional curettage with separation surgery for initial or salvage chordoma treatment. Neurosurgical Focus. 42 (1), 4 (2017).
  7. Barzilai, O., et al. Hybrid therapy for metastatic Epidural spinal cord compression: Technique for separation surgery and spine radiosurgery. Operative Neurosurg. 16 (3), 310-318 (2019).
  8. Kang, D. H., Chang, B. S., Kim, H., Hong, S. H., Chang, S. Y. Separation surgery followed by stereotactic ablative radiotherapy for metastatic epidural spinal cord compression: A systematic review and meta-analysis for local progression rate. J Bone Oncol. 36, 100450 (2022).
  9. Bate, B. G., Khan, N. R., Kimball, B. Y., Gabrick, K., Weaver, J. Stereotactic radiosurgery for spinal metastases with or without separation surgery. J Neurosurg-Spine. 22 (4), 409-415 (2015).
  10. Wallace, A. N., Greenwood, T. J., Jennings, J. W. Radiofrequency ablation and vertebral augmentation for palliation of painful spinal metastases. J Neurooncol. 124 (1), 111-118 (2015).
  11. Dave, B. R., Nanda, A., Anandjiwala, J. V. Transpedicular percutaneous biopsy of vertebral body lesions: A series of 71 cases. Spinal Cord. 47 (5), 384-389 (2009).
  12. Verma, K., Boniello, A., Rihn, J. Emerging techniques for posterior fixation of the lumbar spine. J Am Acad Orthop Surg. 24 (6), 357-364 (2016).
  13. Barzilai, O., et al. Integrating evidence-based medicine for treatment of spinal metastases into a decision framework: Neurologic, oncologic, mechanicals stability, and systemic disease. J Clin Oncol. 35 (21), 2419-2427 (2017).
  14. Patchell, R. A., et al. Direct decompressive surgical resection in the treatment of spinal cord compression caused by metastatic cancer: A randomised trial. Lancet. 366 (9486), 643-648 (2005).
  15. Hansen-Algenstaedt, N., et al. Comparison between minimally invasive surgery and conventional open surgery for patients with spinal metastasis: A prospective propensity score-matched study. Spine. 42 (10), 789-797 (2017).
  16. Lutz, S., et al. Palliative radiotherapy for bone metastases: An ASTRO evidence-based guideline. Int J Radiat Oncol Biol Phys. 79 (4), 965-976 (2011).
  17. Kam, N. M., et al. Combined vertebral augmentation and radiofrequency ablation in the management of spinal metastases: An update. Curr Treat Options Oncol. 18 (12), 74 (2017).
  18. Sandri, A., et al. Combined radiofrequency and kyphoplasty in painful osteolytic metastases to vertebral bodies. Radiol Med. 115 (2), 261-271 (2010).
  19. Shawky Abdelgawaad, A., Ezzati, A., Krajnovic, B., Seyed-Emadaldin, S., Abdelrahman, H. Radiofrequency ablation and balloon kyphoplasty for palliation of painful spinal metastases. Eur Spine J. 30 (10), 2874-2880 (2021).
  20. Clausen, C., et al. Preoperative embolization in surgical treatment of spinal metastases: Single-blind, randomized controlled clinical trial of efficacy in decreasing intraoperative blood loss. J Vasc Interv Radiol. 26 (3), 402-412 (2015).
  21. Sayed, D., Jacobs, D., Sowder, T., Haines, D., Orr, W. Spinal radiofrequency ablation combined with cement augmentation for painful spinal vertebral metastasis: A single-center prospective study. Pain Physician. 22 (5), E441-E449 (2019).
  22. Lee, B. H., et al. Perioperative complication and surgical outcome in patients with spine metastases: retrospective 200-case series in a single institute. Clin Neurol Neurosurg. 122, 80-86 (2014).
  23. Gal, R., et al. Pre-treatment expectations of patients with spinal metastases: What do we know and what can we learn from other disciplines? A systematic review of qualitative studies. BMC Cancer. 20 (1), 1212 (2020).

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Separation SurgeryRadiofrequency AblationBone Cement StrengtheningThoracolumbar MetastasisEpidural Spinal Cord Compression ESCCTotal En bloc Spondylectomy TESPalliative CareTumor RecurrenceClinical OutcomesTokuhashi ScoreTomita ScoreSINS ScoreVAS ScoreFrankel GradingKarnofsky Score

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