Biomed Pap Med Fac Univ Palacky Olomouc Czech Repub. 2020, 164(2):177-182 | DOI: 10.5507/bp.2019.027

Evaluation of spine structure stability at different locations during SBRT

Lukas Knybela, Jakub Cveka, Zuzana Cermakovaa, Jaroslav Havelkab, Michaela Pomakib, Kamila Resovaa
a Department of Oncology, University Hospital Ostrava, Ostrava, Czech Republic
b Department of Radiology, University Hospital Ostrava, Ostrava, Czech Republic

Background and Aims: Modern stereotactic body radiotherapy (SBRT) techniques and systems that use online image guidance offer frameless radiotherapy of spinal tumors and the ability to control intrafraction motion during treatment. These systems allow precise alignment of the patient during the entire treatment session and react immediately to random changes in this alignment. Online tracking data provide information about intrafractional changes, and this information can be useful for designing treatment strategies even if online tracking is not being used. The present study evaluated spine motion during SBRT treatment to assess the risk of verifying patient alignment only prior to starting treatment.

Methods: This study included 123 patients treated with spine SBRT. We analyzed different locations within the spine using system log files generated during treatment, which contain information about differences in the pretreatment reference spine positions by CT versus positions during SBRT treatment. The mean spine motion and intra/interfraction motion was evaluated. We defined and assessed the spine stability and spine significant shifts (SSHs) during treatment.

Results: We analyzed 462 fractions. For the cervical (C) spine, the greatest shifts were in the anterior-posterior (AP) direction (2.48 mm) and in pitch rotation (1.75 deg). The thoracic (Th) spine showed the biggest shift in the AP direction (3.68 mm) and in roll rotation (1.66 deg). For the lumbar-sacral (LS) spine, the biggest shift was found for left-right (LR) translation (3.81 mm) and roll rotation (3.67 deg). No C spine case exceeded 1 mm/1 deg for interfraction variability, but 7 of 54 Th spine cases exceeded 1 mm interfraction variability for translations (maximum value, 2.5 mm in the AP direction). The interfraction variability for translations exceeded 1 mm in 2 of 24 LS spine cases (maximum value, 1.7 mm in the LR direction). Only 13% of cases had no SSHs. The mean times to SSH were 6.5±3.9 min, 8.1±5.9 min, and 8.8±7.1 min for the C, Th, and LS spine, respectively, and the mean recorded SSH values were 1.6±0.66, 1.43±0.33, and 1.46±0.47 mm/deg, respectively.

Conclusion: Positional tracking during spine SBRT treatments revealed low mean translational and rotational shifts. Patient immobilization did not improve spine shifts compared with our results for the Th and LS spine without immobilization. For the most precise spine SBRT, we recommend checking the patient's position during treatment.

Keywords: spine, SBRT, intrafraction variability

Received: March 21, 2019; Accepted: May 30, 2019; Prepublished online: June 17, 2019; Published: June 18, 2020  Show citation

ACS AIP APA ASA Harvard Chicago Chicago Notes IEEE ISO690 MLA NLM Turabian Vancouver
Knybel, L., Cvek, J., Cermakova, Z., Havelka, J., Pomaki, M., & Resova, K. (2020). Evaluation of spine structure stability at different locations during SBRT. Biomedical papers164(2), 177-182. doi: 10.5507/bp.2019.027
Share...
Download citation
  • BibTeX (.bib)
  • Bookends (.ris)
  • EasyBib (.ris)
  • EndNote (.enw)
  • EndNote 8 (.xml)
  • ISI WoS (.isi)
  • Medlars (.medlars)
  • Mendeley (.ris)
  • MODS (.xml)
  • Papers (.ris)
  • RefWorks (.txt)
  • RefManager (.ris)
  • RIS (.ris)
  • MS Word (.xml)
  • Zotero (.ris)
    • Open full article

    References

    1. Gerszten PC, Burton, SA, Ozhasoglu C, Vogel WJ, Welch WC, Baar J, Friedland DF. Stereotactic radiosurgery for spinal metastases from renal cell carcinoma. J Neurosurg Spine 2005;3(4):288-95. Go to original source... Go to PubMed...
    2. Gerszten PC, Burton SA, Belani CP, Ramalingam S, Friedland DM, Ozhasoglu C, Welch WC. Radiosurgery for the treatment of spinal lung metastases. Cancer 2006;107(11):2653-61. Go to original source... Go to PubMed...
    3. Jin JY, Chen Q, Jin R, Rock J, Anderson J, Li S, Ryu S. Technical and clinical experience with spine radiosurgery: a new technology for management of localized spine metastases. Technol Cancer Res Treat 2007;6(2):127-33. Go to original source... Go to PubMed...
    4. Huo M, Sahgal A, Pryor D, Redmond K, Lo S, Foote M. Stereotactic spine radiosurgery: Review of safety and efficacy with respect to dose and fractionation. Surg Neurol Int 2017;8:30. Go to original source... Go to PubMed...
    5. Abbatucci JS, Delozier T, Quint R, Roussel A, Brune D.Radiation myelopathy of the cervical spinal cord: time, dose and volume factors. Int J Radiat Oncol Biol Phys 1978;4(3):239-48. Go to original source... Go to PubMed...
    6. Chuang C, Sahgal A, Lee L, Larson D, Huang K, Petti P, Ma L. Effects of residual target motion for image-tracked spine radiosurgery. Med Phys 2007;34(11):4484-90. Go to original source... Go to PubMed...
    7. Guckenberger M, Meyer J, Wilbert J, Baier K, Bratengeier K, Vordermar, D, Flentje M. Precision required for dose-escalated treatment of spinal metastases and implications for image-guided radiation therapy (IGRT). Radiother Oncol 2007;84(1):56-63. Go to original source... Go to PubMed...
    8. Wang H, Shiu A, Wang C, O'Daniel J, Mahajan A, Woo S, Chang EL. Dosimetric effect of translational and rotational errors for patients undergoing image-guided stereotactic body radiotherapy for spinal metastases. Int J Radiat Oncol Biol Phys 2008;71(4):1261-71. Go to original source... Go to PubMed...
    9. Chawla S, Schell MC, Milano MT. Stereotactic body radiation for the spine: a review. Am J Clin Oncol 2013;36(6):630-36. Go to original source... Go to PubMed...
    10. Fürweger C, Drexler C, Kufeld M, Muacevic A, Wowra B. Advances in fiducial-free image-guidance for spinal radiosurgery with CyberKnife-a phantom study. J Appl Clin Med Phys 2011;12(2):20-28. Go to original source... Go to PubMed...
    11. Fu D, Kuduvalli G, Maurer CR, Allision JW, Adler JR. 3D target localization using 2D local displacements of skeletal structures in orthogonal X-ray images for image-guided spinal radiosurgery. Int J Comput Assist Radiol Surg 2006;1:198-200.
    12. Muacevic A, Staehler M, Drexler C, Wowra B, Reiser M, Tonn JC. Technical description, phantom accuracy, and clinical feasibility for fiducial-free frameless real-time image-guided spinal radiosurgery. J Neurosurg Spine 2006;5(4):303-12. Go to original source... Go to PubMed...
    13. Ma L, Sahgal A, Hossain S, Chuang C, Descovich M, Huang K, Larson DA. Nonrandom intrafraction target motions and general strategy for correction of spine stereotactic body radiotherapy. Int J Radiat Oncol Biol Phys 2009;75(4):1261-65. Go to original source... Go to PubMed...
    14. Ho AK, Fu D, Cotrutz C, Hancock SL, Chang SD, Gibbs IC, Adler JR. A study of the accuracy of cyberknife spinal radiosurgery using skeletal structure tracking. Neurosurgery 2007;60(suppl_2):ONS-147. Go to original source... Go to PubMed...
    15. Elibe E, Boyce-Fappiano D, Ryu S, Siddiqui MS, Lee I, Rock J, Siddiqui F. Stereotactic radiosurgery for primary tumors of the spine and spinal cord. J Radiosurg SBRT 2018;5(2):107. Go to original source...
    16. Li W, Sahgal A, Foote M, Millar BA, Jaffray DA, Letourneau D. Impact of immobilization on intrafraction motion for spine stereotactic body radiotherapy using cone beam computed tomography. Int J Radiat Oncol Biol Phys 2012;84(2):520-6. Go to original source... Go to PubMed...
    17. Hyde D, Lochray F, Korol R, Davidson M, Wong CS, Ma L, Sahgal A. Spine stereotactic body radiotherapy utilizing cone-beam CT image-guidance with a robotic couch: intrafraction motion analysis accounting for all six degrees of freedom. Int J Radiat Oncol Biol Phys 2012;82(3):e555-62. Go to original source... Go to PubMed...
    18. Descovich M, Ma L, Chuang CF, Larson DA, Barani IJ. Comparison between prone and supine patient setup for spine stereotactic body radiosurgery. Technol Cancer Res Treat 2012;11(3):229-36. Go to original source... Go to PubMed...
    19. Agazaryan N, Tenn SE, Desalles AA, Selch MT. Image-guided radiosurgery for spinal tumors: methods, accuracy and patient intrafraction motion. Phys Med Biol 2008;53(6):1715. Go to original source... Go to PubMed...
    20. Murphy MJ, Chang SD, Gibbs IC, Le QT, Hai J, Kim D, Adler Jr JR. Patterns of patient movement during frameless image-guided radiosurgery. Int J Radiat Oncol Biol Phys 2003;55(5):1400-08. Go to original source... Go to PubMed...
    21. Jin JY, Ryu S, Rock J, Faber K, Chen Q, Ajlouni M, Movsas B. Evaluation of residual patient position variation for spinal radiosurgery using the Novalis image guided system. Mel Phys 2008,35(3):1087-93. Go to original source... Go to PubMed...
    22. Hoogeman MS, Nuyttens JJ, Levendag PC, Heijmen BJ. Time dependence of intrafraction patient motion assessed by repeat stereoscopic imaging. Int J Radiat Oncol Biol Phys 2008;70(2):609-18. Go to original source... Go to PubMed...
    23. Kim J, Hsia AT, Xu Z, Ryu S. Motion Likelihood Over Spine Radiosurgery Treatments-An Intrafraction Motion Analysis. Int J Radiat Oncol Biol Phys 2017,99(2):E678. Go to original source...

    This is an open access article distributed under the terms of the Creative Commons Attribution 4.0 International License (CC BY 4.0), which permits use, distribution, and reproduction in any medium, provided the original publication is properly cited. No use, distribution or reproduction is permitted which does not comply with these terms.


    Return to the content