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Evidence reviews for radiotherapy
Evidence review M
NICE Guideline, No. 234
Radiotherapy
Review question
How effective is radiotherapy, including both fractionated and unfractionated radiotherapy, for the management of spinal metastases, direct malignant infiltration of the spine or associated spinal cord compression?
Introduction
External beam radiotherapy is widely used for the treatment of painful spinal metastases. A variety of regimen and techniques have been used, and there is some uncertainty over which are the most appropriate. Radiotherapy regimens range from a single dose of 8Gy to fractionated regimens delivered in multiple doses. Different techniques have also been used: for example stereotactic radiotherapy delivers a precise focused dose compared to conventional external beam radiotherapy – but it is unclear whether this leads to improved outcomes.
Summary of the protocol
See Table 1 for a summary of the Population, Intervention, Comparison and Outcome (PICO) characteristics of this review.
Table 1
Summary of the protocol (PICO table).
For further details see the review protocol in appendix A.
Methods and process
This evidence review was developed using the methods and process described in Developing NICE guidelines: the manual. Methods specific to this review question are described in the review protocol in appendix A and the methods document (supplementary document 1).
Declarations of interest were recorded according to NICE’s conflicts of interest policy.
Effectiveness
Included studies
Nineteen studies were included in this review reporting results from 13 randomised controlled trials (Hoskin 2019 [SCORAD-III trial], Howell 2013 [RTOG 97-14 trial], Lee 2018 [ICORG 05-03 trial], Majumder 2012, Maranzano 2005, Maranzano 2009, Patchell 2005, Rades 2016 [SCORE-2 trial], Rades 2018 [SCORE-2 trial], Rades 2019 [SCORE-2 trial], Roos 2005 [TROG 96-05 trial], Sahgal 2021, Sprave 2018 – a, b, c [IRON-1 trial], Sprave 2018d, e, f [NCT- 02358720], Steenland 1999 [Dutch bone metastasis trial]).
The included studies are summarised in Table 2.
Four randomised controlled trials (Howell 2013 [RTOG 97-14], Majumder 2012, Roos 2005 [TROG 96-05], Steenland 1999 [Dutch Bone Metastasis trial]) compared single fraction radio-therapy to multiple fraction radiotherapy in patients with spinal metastases (without evidence of cord compression).
Three randomised controlled trials (Hoskin 2019 [SCORAD-III trial]), Lee 2018 [ICORG 05-03 trial], Maranzano 2009), compared single fraction radiotherapy to multiple fraction or split-course radiotherapy in patients with metastatic spinal cord compression.
One randomised controlled trial (Sprave 2018a, b, c [IRON-1 trial]) compared image guided intensity modulated radiotherapy (IMRT) to conventional radiotherapy (CRT) in patients with spinal metastases (without evidence of cord compression).
Two randomised controlled trials (Sahgal 2021, Sprave 2018d, e, f [NCT- 02358720]) compared stereotactic ablative body radiotherapy (SABR) to CRT in patients with spinal metastases (without evidence of cord compression).
Two randomised controlled trials compared different regimens of radiotherapy (Maranzano 2005, Rades 2016 [SCORE-2 trial], Rades 2018, Rades 2019 [SCORE-2 trial]) in patients with metastatic spinal cord compression; and 1 randomised controlled trial compared surgery + radiotherapy to radiotherapy alone (Patchell 2005) in patients with metastatic spinal cord compression.
See the literature search strategy in appendix B and study selection flow chart in appendix C.
Excluded studies
Studies not included in this review are listed, and reasons for their exclusion are provided in appendix K.
Summary of included studies
Summaries of the studies that were included in this review are presented in Table 2.
Table 2
Summary of included studies.
See the full evidence tables in appendix D and the forest plots in appendix E.
Economic evidence
Included studies
One economic study was identified which was relevant to this review question. (Turner 2018) The study compared surgery and radiotherapy to radiotherapy alone.
A single economic search was undertaken for all topics included in the scope of this guideline. See supplement 2 for details.
Excluded studies
Economic studies not included in this review are listed, and reasons for their exclusion are provided in supplement 2.
Summary of the evidence
People with painful spinal bone metastases (but no evidence of spinal cord compression)
Single fraction verses multiple fraction radiotherapy
There was very low to low quality evidence of no important difference between single fraction radiotherapy and multiple fractions in terms of pain reduction, spinal stability and overall survival. There was very low quality evidence of an important benefit with single fraction radio-therapy which had fewer treatment related adverse events than multiple fractions.
IMRT verses 3D-CRT
There was no evidence of an importance difference between IMRT and 3D-CRT in terms of quality of life, pain response, treatment related morbidity or overall survival in one small trial. This evidence was very low quality.
SABR verses conventional radiotherapy
There was an important benefit with SABR when compared to conventional RT (EBRT or 3D-CRT) in reducing pain. There was no evidence of important differences in quality of life, treatment related morbidity or overall survival. This evidence was all low quality.
People with metastatic spinal cord compression
Single fraction verses multiple fraction radiotherapy
There was moderate to high quality evidence of no important difference between single fraction radiotherapy and multiple fractions in terms of neurological and functional status, quality of life, pain, overall survival and treatment toxicity.
Short course verses split or long course radiotherapy
There was low to high quality evidence of no important difference between short course radiotherapy and split or long course radiotherapy in terms of neurological and functional status, pain response and treatment related morbidity.
Surgery plus radiotherapy verses radiotherapy alone
There was moderate to high quality evidence of an important benefit for surgery + radiotherapy over radiotherapy alone for neurological and functional status (ability to walk, continence and muscle strength).
See appendix F for full GRADE tables.
Summary of included economic evidence
Table 3
Economic evidence profile of an economic evaluation of the addition of radiotherapy for people undergoing surgery for metastatic spinal cord compression.
Economic model
No economic modelling was undertaken for this review because the committee agreed that other topics were higher priorities for economic evaluation.
Evidence Statement
Turner 2018 was a cost utility analysis which reported outcomes in terms of cost per QALY gained for surgery and radiotherapy versus radiotherapy alone in people with symptomatic spinal metastases.
The study found surgery and radiotherapy to be cost saving and health improving compared to radiotherapy alone. This was robust to deterministic sensitivity analysis. The study was deemed to be directly applicable to the review question with potentially serious methodological limitations.
The committee’s discussion and interpretation of the evidence
The outcomes that matter most
Health related quality of life, pain and neurological and functional status were chosen as critical outcomes because untreated malignant spinal disease can impact on quality of life due to severe pain and impaired neurological and functional status. Overall survival was also a critical outcome because radiotherapy can potentially prolong life.
The committee agreed that treatment related morbidity is an important outcome, due to side effects of radiotherapy, and is an important consideration when choosing radiotherapy dose and fractionation. Spinal stability was also an important outcome, because different radio-therapy doses and fractionations may have differing impact on re-ossification rates of unstable spinal bone metastases. Fitness for subsequent anti-cancer therapy was an important outcome because morbidity due to radiotherapy could delay further anti-cancer therapy until the person recovers fitness.
The quality of the evidence
The quality of the evidence for outcomes was assessed with GRADE and ranged from very low to high. The main issues that lowered the quality of the evidence were risk of bias as per Cochrane RoB 2 and imprecision of the effect estimates. In one case evidence quality was downgraded for indirectness because the study included some people with non-spinal bone metastases.
The committee considered the quality of evidence was sufficient to make recommendations on fractionation and on SABR for painful spinal metastases. They used their clinical experience to make recommendations where there was a lack of evidence on the timing of radio-therapy, radiotherapy for people with asymptomatic spinal metastases and the use of SABR for MSCC.
Benefits and harms
Radiotherapy and fertility
The committee agreed that the impact on future fertility of both the cancer and the radiotherapy treatment should be discussed with the person and, if appropriate (for example, depending on age and preferences), a referral should be made to a fertility. The committee discussed that treatment of MSCC is usually urgent and fertility treatment can take time to organise and undertake in practice and that it is therefore important to bear in mind that MSCC treatment should not be delayed awaiting further discussions with a fertility specialist. They also acknowledged that radiotherapy fields for MSCC would usually not affect the gonads so, urgent radiotherapy treatment might not impact as much on fertility as radiotherapy does for other cancers which is another reason why urgent treatment should not be delayed.
Radiotherapy to treat painful spinal metastases or DMI of the spine and prevent MSCC
Evidence supported the recommendation for single fraction radiotherapy in people with painful spinal metastases (without MSCC). They acknowledged that there are people who can have their pain controlled in other ways, too, but this is covered by Evidence Review I. Single fraction radiotherapy appeared as effective as multiple fractions in terms of reducing pain but with fewer adverse effects. Although the evidence was very low quality, the committee discussed that a strong recommendation was supported because single fractionation would likely be more acceptable to patients with fewer visits and transfers required to complete the treatment. There was limited evidence from 2 small RCTs that stereotactic ablative body radio-therapy (SABR) is more effective than conventional radiotherapy in reducing pain for people with spinal metastases without MSCC. Although the evidence was very low quality the committee agreed that the ability of SABR to deliver a precise dose while sparing damage to healthy tissue supported their recommendation. The committee agreed that this could be an option for a subgroup of people who have a good overall prognosis because they can tolerate this radiotherapy and it would not be too risky. They also discussed that those with limited metastatic disease (based on expertise they thought currently up to 3 discrete metastases would be considered standard for oligometastases in accordance with NHS commissioning of stereotactic ablative body radiotherapy) could benefit from this. They agreed that this number would balance the potential that all cancer sites could be controlled with an acceptable level of toxicity.
Although there was a lack of evidence about the impact of radiotherapy on stem cell harvest in people with haematological cancers, the committee agreed that in their experience it could lower the chance of a successful procedure. For this reason they recommended a discussion with the relevant haematology MDT whenever this was being considered to allow for careful consideration of the risks and benefits for each individual.
Radiotherapy to treat MSCC
Although there was no evidence on the timing of radiotherapy for people with MSCC, the committee agreed that MSCC can be an oncologic emergency and rapid access to radiotherapy would be needed in some cases to prevent neurological impairment (as soon as possible and within 24 hours). The committee discussed that in patients with MSCC who are not candidates for surgery, radiotherapy may help prevent further neurological damage and alleviate pain. In this situation radiotherapy should be given urgently – unless the person already has paraplegia or tetraplegia for 2 weeks or longer and their pain is controlled or their overall prognosis is poor. In these cases, the benefits of radiotherapy are unlikely to outweigh the harms.
There was evidence that single fractionation was as effective as multiple fractions for people with MSCC, but with the benefit of increased patient convenience and reduced costs. The committee agreed that a strong recommendation was appropriate based on the evidence and because this would lead to less time spent in multiple hospital visits which can be particularly important in a patient group with reduced life expectancy. This would also use fewer resources in relation to appointments and staff time.
The committee agreed, based on their experience, that it can be technically difficult to treat multilevel disease in a single dose and that radiologists avoid large single dose treatment fields which cover a large proportion of the spinal cord due to toxicity. For these reasons in some cases multiple fraction radiotherapy would be more appropriate.
The committee agreed to make a research recommendation stereotactic ablative body radiotherapy for the treatment of MSCC, given a lack of evidence about its use in this indication.
Radiotherapy for asymptomatic spinal metastases
There was a lack of evidence about the use of radiotherapy in people with asymptomatic spinal metastases. The committee agreed that benefits of radiotherapy were less clear cut in this population whereas the harms of radiotherapy are known. They recommended radiotherapy only in limited circumstances: for those with limited metastatic disease (where radiotherapy could be used to control disease), if there are radiological signs of impending cord compression by an epidural or intradural tumour (where presumably radiotherapy may prevent progression to symptomatic MSCC) and for those in a randomised trial.
Postoperative radiotherapy
There was evidence showing that radiotherapy and surgery had an important benefit in relation to neurological and functional status over radiotherapy alone. The committee noted also that this is now routine practice in most services and is suitable for most people with MSCC post surgery. To standardise this practice and based on the evidence they recommended that postoperative radiotherapy should be offered.
Further radiotherapy
The committee also discussed retreatment with radiotherapy in people who had previously had radiotherapy. No evidence was identified so the committee, based on experience, decided to recommend this treatment option in some cases but also to highlight some of the factors linked to treatment toxicity (dose, timing and volume of treatment field) that should be taken into account when making decisions about whether or not to offer further radiotherapy treatment.
Providing urgent radiotherapy services
The committee discussed that their recommendation regarding radiotherapy within 24 hours would require some configuration of services that would help enable this to happen. Based on experience they therefore recommended that MSCC services need to ensure that radio-therapy and simulator facilities are available for urgent (within 24 hours) daytime sessions, 7 days a week. This would enable treatment to be given within this timeframe.
Cost effectiveness and resource use
The economic evidence showed that giving post-operative radiotherapy to people who have undergone surgery will be cost saving and health improving compared to radiotherapy alone. These savings and health improvements are largely being driven through people being ambulant for longer periods of time, improving quality of life and reducing costs to community services which are involved with non-ambulant people.
Stereotactic ablative body radiotherapy (SABR) is not widely used for painful spinal metastases in the NHS and would represent a change in practice. The technology is already available in the NHS for other cancers and all cancer centres will already have access to this technology. These recommendations will increase the use of stereotactic ablative body radiotherapy but this is similar in cost to alternative radiotherapy and the committee agreed this will not lead to a significant resource impact. There may be an initial cost of setting up pathways for people with painful spinal metastases to access SABR, as these are not currently established, but this will be a one-off cost and would not lead to significant resource impact. There was also evidence that SABR will reduce pain leading to reduced use of analgesics and other treatments for pain, decreasing costs and increasing quality of life. The committee therefore concluded that SABR was likely to be cost neutral or potentially cost saving once the initial set-up costs had been incurred.
Recommendations supported by this evidence review
This evidence review supports recommendations 1.1.21, 1.10.1 to 1.10.10 and research recommendation 1 on the effectiveness of stereotactic ablative body radiotherapy in the treatment of MSCC, in the guideline.
References – included studies
Hoskin 2019 [SCORAD-III trial]
Hoskin P, Hopkins K, Misra V, et al. Effect of Single-Fraction vs Multifraction Radiotherapy on Ambulatory Status Among Patients With Spinal Canal Compression From Metastatic Cancer: the SCORAD Randomized Clinical Trial. JAMA 322, 2084–2094, 2019 [PMC free article: PMC6902166] [PubMed: 31794625]Howell 2013 [RTOG 97-14 trial]
Howell D, James J, Hartsell W, et al. Single-fraction radiotherapy versus multifraction radio-therapy for palliation of painful vertebral bone metastases - Equivalent efficacy, less toxicity, more convenient: A subset analysis of Radiation Therapy Oncology Group trial 97-14. Cancer 119, 888–896, 2013 [PMC free article: PMC5746185] [PubMed: 23165743]Lee 2018 [ICORG 05-03 trial]
Lee K, Dunne M, Small C, et al. (ICORG 05-03): prospective randomized non-inferiority phase III trial comparing two radiation schedules in malignant spinal cord compression (not proceeding with surgical decompression); the quality of life analysis. Acta Oncologica, 1–8, 2018 [PubMed: 29419331]Majumder 2012
Majumder D, Chatterjee D, Bandyopadhyay A, et al. Single Fraction versus Multiple Fraction Radiotherapy for Palliation of Painful Vertebral Bone Metastases: A Prospective Study. Indian Journal of Palliative Care, 18, 202–6, 2012 [PMC free article: PMC3573475] [PubMed: 23440009]Maranzano 2005
Maranzano E, Bellavita R, Rossi R, et al. Short-course versus split-course radiotherapy in metastatic spinal cord compression: results of a phase III, randomized, multicenter trial. Journal of Clinical Oncology 23: 3358–65, 2005 [PubMed: 15738534]Maranzano 2009
Maranzano E, Trippa F, Casale M, et al. 8Gy single-dose radiotherapy is effective in metastatic spinal cord compression: results of a phase III randomized multicentre Italian trial. Radiotherapy and Oncology 93, 174–9, 2009 [PubMed: 19520448]Patchell 2005
Patchell R, Tibbs P Regine W, et al. Direct decompressive surgical resection in the treatment of spinal cord compression caused by metastatic cancer: a randomised trial. Lancet 366, 643–8, 2005 [PubMed: 16112300]Rades 2016 [SCORE-2 trial]
Rades D, Šegedin B, Conde-Moreno A, et al, Radiotherapy With 4 Gy × 5 Versus 3 Gy × 10 for Metastatic Epidural Spinal Cord Compression: final results of the SCORE-2 Trial (ARO 2009/01). Journal of Clinical Oncology 34, 597–602, 2016 [PubMed: 26729431]Rades 2018 [SCORE-2 trial]
Rades D, Conde-Moreno A, Cacicedo J et al. Comparison of Two Radiotherapy Regimens for Metastatic Spinal Cord Compression: subgroup Analyses from a Randomized Trial. Anti-cancer Research 38, 1009–1015, 2018 [PubMed: 29374734]Rades 2019 [SCORE-2 trial]
Rades D, Segedin B, Conde-Moreno A, et al. Patient-Reported Outcomes-Secondary Analysis of the SCORE-2 Trial Comparing 4 Gy x 5 to 3 Gy x 10 for Metastatic Epidural Spinal Cord Compression. International Journal of Radiation Oncology, Biology, Physics, 105, 760–764, 2019 [PubMed: 31415797]Roos 2005 [TROG 96-05 trial]
Roos D, Turner S, O’Brien, P, et al. Randomized trial of 8 Gy in 1 versus 20 Gy in 5 fractions of radiotherapy for neuropathic pain due to bone metastases (Trans-Tasman Radiation Oncology Group, TROG 96.05). Radiotherapy and Oncology 75, 54–63, 2005 [PubMed: 15878101]Sahgal 2021
Sahgal A, Myrehaug S, Siva S, et al. Stereotactic body radiotherapy versus conventional external beam radiotherapy in patients with painful spinal metastases: an open-label, multicentre, randomised, controlled, phase 2/3 trial. Lancet Oncology 22, 1023–1033, 2021 [PubMed: 34126044]Sprave 2018a [IRON-1 trial]
Sprave T, Verma V, Förster R et al. Radiation-induced acute toxicities after image-guided intensity-modulated radiotherapy versus three-dimensional conformal radiotherapy for patients with spinal metastases (IRON-1 trial): first results of a randomized controlled trial. Strahlen-therapie und Onkologie 194, 911–920, 2018 [PubMed: 29978307]Sprave 2018b [IRON-1 trial]
Sprave T, Verma V, Förster R et al. Quality of Life and Radiation-induced Late Toxicity Following Intensity-modulated Versus Three-dimensional Conformal Radiotherapy for Patients with Spinal Bone Metastases: results of a Randomized Trial. Anticancer Research 38, 4953–4960, 2018 [PubMed: 30061275]Sprave 2018c [IRON-1 trial]
Sprave T, Verma V, Förster R, et al. Bone density and pain response following intensity-modulated radiotherapy versus three-dimensional conformal radiotherapy for vertebral metastases - secondary results of a randomized trial. Radiation Oncology, 13, 212, 2018 [PMC free article: PMC6208115] [PubMed: 30376859]Sprave 2018d [NCT - 02358720]
Sprave T, Verma V, Forster R, et al, Quality of Life Following Stereotactic Body Radiotherapy Versus Three-Dimensional Conformal Radiotherapy for Vertebral Metastases: Secondary Analysis of an Exploratory Phase II Randomized Trial. Anticancer Research 38, 4961–4968, 2018 [PubMed: 30061276]Sprave 2018e [NCT - 02358720]
Sprave T, Verma V, Forster R, et al, Randomized phase II trial evaluating pain response in patients with spinal metastases following stereotactic body radiotherapy versus three-dimensional conformal radiotherapy. Radiotherapy and Oncology 128, 274–282, 2018 [PubMed: 29843899]Sprave 2018f [NCT - 02358720]
Sprave T, Verma V, Forster R, et al, Local response and pathologic fractures following stereotactic body radiotherapy versus three-dimensional conformal radiotherapy for spinal metastases - a randomized controlled trial. BMC Cancer 18, 859, 2018 [PMC free article: PMC6119304] [PubMed: 30170568]Steenland 1999 [Dutch Bone Metastasis trial]
Steenland E, Leer J, van Houwelingen H, et al. The effect of a single fraction compared to multiple fractions on painful bone metastases: a global analysis of the Dutch Bone Metastasis Study. Radiotherapy and Oncology, 52, 101–109, 1999 [PubMed: 10577695]Turner 2018
Turner I, Kennedy J, Morris S, et al. Surgery and radiotherapy for symptomatic spinal metastases is more cost effective than radiotherapy alone: a cost utility analysis in a UK Spinal Center. World Neurosurgery, 109, e389–e397, 2018. [PubMed: 28987846]
Effectiveness
Economic
Appendices
Appendix A. Review protocols
Appendix B. Search strategy (clinical/economic)
Appendix C. Effectiveness evidence study selection
Appendix D. Evidence tables
Appendix E. Forest plots
Appendix F. GRADE tables
Appendix G. Economic evidence study selection
Study selection for: How effective is radiotherapy, including both fractionated and unfractionated radiotherapy, for the management of spinal metastases, direct malignant infiltration of the spine or associated spinal cord compression?
A global search of economic evidence was undertaken for all review questions in this guideline. See Supplement 2 for further information
Appendix H. Economic evidence tables
Appendix I. Economic model
Economic model for review question: How effective is radiotherapy, including both fractionated and unfractionated radiotherapy, for the management of spinal metastases, direct malignant infiltration of the spine or associated spinal cord compression?
No economic analysis was conducted for this review question.
Appendix J. Excluded studies
Excluded studies for review question: How effective is radiotherapy, including both fractionated and unfractionated radiotherapy, for the management of spinal metastases, direct malignant infiltration of the spine or associated spinal cord compression?
Excluded effectiveness studies
Table 14Excluded studies and reasons for their exclusion
| Study | Reason for exclusion |
|---|---|
| (2013) Xofigo (radium-223 dichloride; Bayer HealthCare Pharmaceuticals Inc.) for treatment of bone metastases in castration-resistant prostate cancer. Lansdale, PA: HAYES, Inc | Publication type does not match review protocol – conference abstract |
| (2011) Robotically assisted stereotactic radiosurgery (SRS) for spinal and extracranial head and neck indications. Lansdale, PA: HAYES, Inc | Publication type does not match review protocol – conference abstract |
| Amouzegar-Hashemi, F, Behrouzi, H, Kazemian, A et al. (2008) Single versus multiple fractions of palliative radiotherapy for bone metastases: a randomized clinical trial in Iranian patients. Current oncology (toronto, ont.) 15(3): 36–39 [PMC free article: PMC2442760] [PubMed: 18596887] | Population does not match review protocol |
| Bakar, D., Tanenbaum, J. E., Phan, K. et al. (2016) Decompression surgery for spinal metastases: a systematic review. Neurosurgical Focus 41: e2 [PubMed: 27476844] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Barrie, U., Elguindy, M., Pernik, M. et al. (2020) Intramedullary Spinal Metastatic Renal Cell Carcinoma: Systematic Review of Disease Presentation, Treatment, and Prognosis with Case Illustration. World Neurosurgery 134: 584–593 [PubMed: 31734421] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Bilsky, M. H.; Laufer, I.; Burch, S. (2009) Shifting paradigms in the treatment of metastatic spine disease. Spine 34: S101–7 [PubMed: 19829269] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Broder, M. S., Gutierrez, B., Cherepanov, D. et al. (2015) Burden of skeletal-related events in prostate cancer: unmet need in pain improvement. Supportive Care in Cancer 23(1): 237–247 [PubMed: 25270847] | Population does not match review protocol |
| Cellini, F., Manfrida, S., Deodato, F. et al. (2019) Pain REduction with bone metastases STereotactic radiotherapy (PREST): A phase III randomized multicentric trial. Trials 20(1) [PMC free article: PMC6816218] [PubMed: 31661034] | Publication type does not match review protocol – study protocol |
| Chang, J. H., Shin, J. H., Yamada, Y. J. et al. (2016) Stereotactic Body Radiotherapy for Spinal Metastases: What are the Risks and How Do We Minimize Them?. Spine 41suppl20: S238–S245 [PMC free article: PMC5552170] [PubMed: 27488294] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Chen, B., Xiao, S., Tong, X. et al. (2015) Comparison of the Therapeutic Efficacy of Surgery with or without Adjuvant Radiotherapy versus Radiotherapy Alone for Metastatic Spinal Cord Compression: A Meta-Analysis. World Neurosurgery 83(6): 1066–1073 [PubMed: 25536156] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Chi, J. H., Gokaslan, Z., McCormick, P. et al. (2009) Selecting treatment for patients with malignant epidural spinal cord compressiondoes age matter? Results from a randomized clinical trial. Spine 34(5): 431–435 [PubMed: 19212272] | Other protocol criteria - posthoc analysis of Patchell 2005 trial |
| Chow, E., Harris, K., Fan, G. et al. (2007) Palliative radiotherapy trials for bone metastases: a systematic review. Journal of Clinical Oncology 25: 1423–36 [PubMed: 17416863] | Population does not match review protocol |
| Chow, E., Hoskin, P. J., Wu, J. et al. (2006) A phase III international randomised trial comparing single with multiple fractions for re-irradiation of painful bone metastases: National Cancer Institute of Canada Clinical Trials Group (NCIC CTG) SC 20. Clinical Oncology 18(2): 125–128 [PubMed: 16523812] | Population does not match review protocol |
| Chow, E., van der Linden, Y. M., Roos, D. et al. (2014) Single versus multiple fractions of repeat radiation for painful bone metastases: a randomised, controlled, non-inferiority trial. Lancet Oncology 15: 164–71 [PubMed: 24369114] | Population does not match review protocol |
| Chow, E., Zeng, L., Salvo, N. et al. (2012) Update on the systematic review of palliative radiotherapy trials for bone metastases. Clinical Oncology (Royal College of Radiologists) 24: 112–24 [PubMed: 22130630] | Population does not match review protocol |
| Dhamija, B.; Batheja, D.; Balain, B. S. (2021) A systematic review of MIS and open decompression surgery for spinal metastases in the last two decades. Journal of Clinical Orthopaedics & Trauma 22: 101596 [PMC free article: PMC8488238] [PubMed: 34631409] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Donovan, E. K., Sienna, J., Mitera, G. et al. (2019) Single versus multifraction radiotherapy for spinal cord compression: A systematic review and meta-analysis. Radiotherapy & Oncology 134: 55–66 [PubMed: 31005225] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Dy, S. M., Asch, S. M., Naeim, A. et al. (2008) Evidence-based standards for cancer pain management. Journal of Clinical Oncology 26(23): 3879–3885 [PubMed: 18688056] | Population does not match review protocol |
| Falkmer, U., Jarhult, J., Wersall, P. et al. (2003) A systematic overview of radiation therapy effects in skeletal metastases. Acta Oncologica 42(5–6): 620–633 [PubMed: 14596519] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Feyer, P., Sautter-Bihl, M. L., Budachs, W. et al. (2010) DEGRO practical guidelines for palliative radiotherapy of breast cancer patients: Brain metastases and leptomeningeal carcinomatosis. Strahlentherapie und Onkologie 186(2): 63–69 [PubMed: 20127222] | Population does not match review protocol |
| Garcia-Torralba, E., Spada, F., Lim, K. H. J. et al. (2021) Knowns and unknowns of bone metastases in patients with neuroendocrine neoplasms: A systematic review and meta-analysis. Cancer Treatment Reviews 94 (no pagination) [PubMed: 33730627] | Population does not match review protocol |
| George, R, Sundararaj, JJ, Govindaraj, R et al. (2015) Interventions for the treatment of metastatic extradural spinal cord compression in adults. Cochrane Database of Systematic Reviews [PMC free article: PMC6513178] [PubMed: 26337716] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Gerszten, P. C.; Mendel, E.; Yamada, Y. (2009) Radiotherapy and radiosurgery for metastatic spine disease: what are the options, indications, and outcomes?. Spine 34: S78–92 [PubMed: 19829280] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Ghia, A. J., Chang, E. L., Bishop, A. J. et al. (2016) Single-fraction versus multifraction spinal stereotactic radiosurgery for spinal metastases from renal cell carcinoma: secondary analysis of Phase I/II trials. Journal of Neurosurgery Spine 24: 829–36 [PubMed: 26799117] | Study design - phase I or II trials - patients not randomly allocated to treatment |
| Glicksman, R. M., Tjong, M. C., Neves-Junior, W. F. P. et al. (2020) Stereotactic Ablative Radiotherapy for the Management of Spinal Metastases: A Review. JAMA Oncology 6: 567–577 [PubMed: 31895403] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Gong, Y., Xu, L., Zhuang, H. et al. (2019) Efficacy and safety of different fractions in stereotactic body radiotherapy for spinal metastases: A systematic review. Cancer Medicine 8: 6176–6184 [PMC free article: PMC6797563] [PubMed: 31489788] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Goodwin, C. R., Sankey, E. W., Liu, A. et al. (2016) A systematic review of clinical outcomes for patients diagnosed with skin cancer spinal metastases. Journal of Neurosurgery: Spine 24(5): 837–849 [PubMed: 26544595] | Intervention does not match review protocol |
| Hamouda, W. E.; Roshdy, W.; Teema, M. (2007) Single versus conventional fractionated radiotherapy in the palliation of painful bone metastases. The gulf journal of oncology 1: 35–41 [PubMed: 20084712] | Population does not match review protocol |
| Hernandez-Duran, S., Hanft, S., Komotar, R. J. et al. (2016) The role of stereotactic radiosurgery in the treatment of intramedullary spinal cord neoplasms: a systematic literature review. Neurosurgical Review 39(2): 175–183 [PubMed: 26219855] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Holt, T., Hoskin, P., Maranzano, E. et al. (2012) Malignant epidural spinal cord compression: the role of external beam radiotherapy. Current Opinion in Supportive & Palliative Care 6: 103–8 [PubMed: 22156794] | Study design does not match review protocol – expert review/narrative |
| Howell, DD, James, JL, Hartsell, WF et al. (2009) Randomized trial of short-course versus long-course radiotherapy for palliation of painful vertebral bone metastases: a retrospective analysis of RTOG 97-14. Journal of clinical oncology 27(15sparti): 488 | Publication type does not match review protocol – conference abstract |
| Husain, Z. A., Sahgal, A., De Salles, A. et al. (2017) Stereotactic body radiotherapy for de novo spinal metastases: systematic review. Journal of Neurosurgery Spine 27: 295–302 [PubMed: 28598293] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Jeremic, B. (2001) Single fraction external beam radiation therapy in the treatment of localized metastatic bone pain. A review. Journal of Pain and Symptom Management 22(6): 1048–1058 [PubMed: 11738168] | Population does not match review protocol |
| Jeremic, B, Shibamoto, Y, Acimovic, L et al. (1998) A randomized trial of three single-dose radiation therapy regimens in the treatment of metastatic bone pain. International journal of radiation oncology, biology, physics 42(1): 161–167 [PubMed: 9747834] | Population does not match review protocol |
| Kim, J. M., Losina, E., Bono, C. M. et al. (2012) Clinical outcome of metastatic spinal cord compression treated with surgical excision +/- radiation versus radiation therapy alone: a systematic review of literature. Spine 37: 78–84 [PMC free article: PMC3876411] [PubMed: 21629164] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Klimo Jr, P., Thompson, C. J., Kestle, J. R. W. et al. (2005) A meta-analysis of surgery versus conventional radiotherapy for the treatment of metastatic spinal epidural disease. Neuro-Oncology 7(1): 64–76 [PMC free article: PMC1871618] [PubMed: 15701283] | Intervention and comparator do not match review protocol |
| Kumar, N., Madhu, S., Bohra, H. et al. (2020) Is there an optimal timing between radiotherapy and surgery to reduce wound complications in metastatic spine disease? A systematic review. European Spine Journal 29: 3080–3115 [PubMed: 32556627] | Outcomes do not match review protocol |
| Lee, C. H., Kwon, J. W., Lee, J. et al. (2014) Direct decompressive surgery followed by radiotherapy versus radiotherapy alone for metastatic epidural spinal cord compression: a meta-analysis. Spine 39: E587–92 [PubMed: 24503688] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Leer, JWH; Steenland, E; van Houwelingen, H (1999) Pain control for bone metastases. European journal of cancer 35(abstract462): 129 | Publication type does not match review protocol – conference abstract |
| Loblaw, D. A. and Laperriere, N. J. (1998) Emergency treatment of malignant extradural spinal cord compression: An evidence-based guideline. Journal of Clinical Oncology 16(4): 1613–1624 [PubMed: 9552073] | Publication type does not match review protocol – duplicate publication - updated version available |
| Loblaw, D. A., Mitera, G., Ford, M. et al. (2012) A 2011 updated systematic review and clinical practice guideline for the management of malignant extradural spinal cord compression. International Journal of Radiation Oncology, Biology, Physics 84: 312–7 [PubMed: 22420969] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Loblaw, D. A., Perry, J., Chambers, A. et al. (2005) Systematic review of the diagnosis and management of malignant extradural spinal cord compression: the Cancer Care Ontario Practice Guidelines Initiative’s Neuro-Oncology Disease Site Group. Journal of Clinical Oncology 23: 2028–37 [PubMed: 15774794] | Publication type does not match review protocol – duplicate publication - updated version available |
| Lohre, E. T.; Lund, J.; Kaasa, S. (2012) Radiation therapy in malignant spinal cord compression: what is the current knowledge on fractionation schedules? A systematic literature review. BMJ supportive & palliative care 2(1): 51–56 [PubMed: 24653500] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Lutz, S., Balboni, T., Jones, J. et al. (2017) Palliative radiation therapy for bone metastases: Update of an ASTRO Evidence-Based Guideline. Practical Radiation Oncology 7: 4–12 [PubMed: 27663933] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Ma, Y., He, S., Liu, T. et al. (2017) Quality of Life of Patients with Spinal Metastasis from Cancer of Unknown Primary Origin: A Longitudinal Study of Surgical Management Combined with Postoperative Radiation Therapy. Journal of Bone & Joint Surgery - American Volume 99: 1629–1639 [PubMed: 28976427] | Study design does not match review protocol – non-randomised study |
| Maranzano, E., Trippa, F., Casale, M. et al. (2011) Reirradiation of metastatic spinal cord compression: definitive results of two randomized trials. Radiotherapy & Oncology 98: 234–7 [PubMed: 21295881] | Study design does not match review protocol - post-hoc analysis (patients not randomised to re-treatment with radiotherapy) |
| Migliorini, F., Eschweiler, J., Trivellas, A. et al. (2021) Better pain control with 8-gray single fraction palliative radiotherapy for skeletal metastases: a Bayesian network meta-analysis. Clinical and Experimental Metastasis 38(2): 197–208 [PMC free article: PMC7987640] [PubMed: 33559808] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Moller, T. (1996) Skeletal metastases. Acta oncologica (Stockholm, Sweden) 35suppl7: 125–136 [PubMed: 9154105] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Moulding, H. D. and Bilsky, M. H. (2010) Metastases to the craniovertebral junction. Neurosurgery 66(SUPPL. 3): A113–A118 [PubMed: 20173512] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Myrehaug, S., Sahgal, A., Hayashi, M. et al. (2017) Reirradiation spine stereotactic body radiation therapy for spinal metastases: systematic review. Journal of Neurosurgery Spine 27: 428–435 [PubMed: 28708043] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Niewald, M., Tkocz, H. J., Abel, U. et al. (1996) Rapid course radiation therapy vs. more standard treatment: a randomized trial for bone metastases. International Journal of Radiation Oncology, Biology, Physics 36: 1085–9 [PubMed: 8985030] | Population does not match review protocol - data for spinal metastases group not reported |
| Ozsaran, Z, Yalman, D, Anacak, Y et al. (2001) Palliative radiotherapy in bone metastases: results of a randomized trial comparing three fractionation schedules. Journal of B.U.ON. 6(1): 43–48 | Population does not match review protocol |
| Pontoriero, A., Lillo, S., Caravatta, L. et al. (2021) Cumulative dose, toxicity, and outcomes of spinal metastases re-irradiation: Systematic review on behalf of the Re-Irradiation Working Group of the Italian Association of Radiotherapy and Clinical Oncology (AIRO). Strahlentherapie und Onkologie 197: 369–384 [PubMed: 33635395] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Qu, S., Meng, H. L., Liang, Z. G. et al. (2015) Comparison of shortcourse radiotherapy versus long-course radiotherapy for treatment of metastatic spinal cord compression: A systematic review and meta-analysis. Medicine (United States) 94(43) [PMC free article: PMC4985404] [PubMed: 26512590] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Quraishi, N. A., Giannoulis, K. E., Edwards, K. L. et al. (2012) Management of metastatic sacral tumours. European Spine Journal 21: 1984–93 [PMC free article: PMC3463705] [PubMed: 22729363] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Rades, D. (2010) Dose-fractionation schedules for radiotherapy of bone metastases. Breast Care 5(5): 339–344 [PMC free article: PMC3132960] [PubMed: 21779218] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Rades, D., Cacicedo, J., Conde-Moreno, A. J. et al. (2021) Comparison of 5 x 5 Gy and 10 x 3 Gy for metastatic spinal cord compression using data from three prospective trials. Radiation Oncology 16: 7 [PMC free article: PMC7788916] [PubMed: 33413492] | Patients were not randomly allocated to treatment groups |
| Rich, S. E., Chow, R., Raman, S. et al. (2018) Update of the systematic review of palliative radiation therapy fractionation for bone metastases. Radiotherapy & Oncology 126: 547–557 [PubMed: 29397209] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Roos, D. E., O’Brien, P. C., Smith, J. G. et al. (2000) A role for radiotherapy in neuropathic bone pain: preliminary response rates from a prospective trial (Trans-tasman radiation oncology group, TROG 96.05). International Journal of Radiation Oncology, Biology, Physics 46: 975–81 [PubMed: 10705020] | Other protocol criteria - data from preliminary analysis reported in Roos 2005 which has been included in this review |
| Roos, D. E., Davis, S. R., Turner, S. L. et al. (2003) Quality assurance experience with the randomized neuropathic bone pain trial (Trans-Tasman Radiation Oncology Group, 96.05). Radiotherapy & Oncology 67: 207–12 [PubMed: 12812852] | Population does not match review protocol - data for spinal metastases group not reported |
| Roque i Figuls, M., Martinez-Zapata, M. J., Scott-Brown, M. et al. (2017) Radioisotopes for metastatic bone pain. Cochrane Database of Systematic Reviews 2017(3) [PMC free article: PMC6464104] [PubMed: 28334435] | Publication type does not match review protocol – duplicate publication - withdrawn version of a Cochrane review |
| Sahgal, A., Myrehaug, S. D., Siva, S. et al. (2020) CCTG SC.24/TROG 17.06: A Randomized Phase II/III Study Comparing 24Gy in 2 Stereotactic Body Radiotherapy (SABR) Fractions Versus 20Gy in 5 Conventional Palliative Radiotherapy (CRT) Fractions for Patients with Painful Spinal Metastases. International journal of radiation oncology, biology, physics 108(5): 1397–1398 [PubMed: 33427654] | Publication type does not match review protocol – conference abstract |
| Sande, T. A., Ruenes, R., Lund, J. A. et al. (2009) Long-term follow-up of cancer patients receiving radiotherapy for bone metastases: results from a randomised multicentre trial. Radiotherapy & Oncology 91: 261–6 [PubMed: 19307034] | Population does not match review protocol |
| Sapkaroski, D.; Osborne, C.; Knight, K. A. (2015) A review of stereotactic body radiotherapy - is volumetric modulated arc therapy the answer?. Journal of Medical Radiation Sciences 62(2): 142–151 [PMC free article: PMC4462986] [PubMed: 26229679] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Sharma, R., Sagoo, N. S., Haider, A. S. et al. (2021) Iodine-125 radioactive seed brachytherapy as a treatment for spine and bone metastases: A systematic review and meta-analysis. Surgical Oncology 38 (no pagination) [PubMed: 34153905] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Singh, R., Lehrer, E. J., Dahshan, B. et al. (2020) Single fraction radiosurgery, fractionated radiosurgery, and conventional radiotherapy for spinal oligometastasis (SAFFRON): A systematic review and meta-analysis. Radiotherapy & Oncology 146: 76–89 [PubMed: 32114269] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Smith, B. W., Joseph, J. R., Saadeh, Y. S. et al. (2018) Radiosurgery for Treatment of Renal Cell Metastases to Spine: A Systematic Review of the Literature. World Neurosurgery 109: e502–e509 [PubMed: 29038086] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Sohn, S. and Chung, C. K. (2012) The role of stereotactic radiosurgery in metastasis to the spine. Journal of Korean Neurosurgical Society 51: 1–7 [PMC free article: PMC3291699] [PubMed: 22396835] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Soltys, S. G., Grimm, J., Milano, M. T. et al. (2021) Stereotactic Body Radiation Therapy for Spinal Metastases: Tumor Control Probability Analyses and Recommended Reporting Standards. International Journal of Radiation Oncology, Biology, Physics 110: 112–123 [PubMed: 33516580] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Souchon, R., Wenz, F., Sedlmayer, F. et al. (2009) DEGRO practice guidelines for palliative radiotherapy of metastatic breast cancer: bone metastases and metastatic spinal cord compression (MSCC). Strahlentherapie und Onkologie 185: 417–24 [PubMed: 19714302] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Stebbing, J. and Ngan, S. (2010) Breast cancer (metastatic). BMJ clinical evidence [PMC free article: PMC3217794] [PubMed: 21418674] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Suppli, MH, Munck Af Rosenschold, P, Dahl, B et al. (2020) Premature Termination of a Randomized Controlled Trial on Image-Guided Stereotactic Body Radiotherapy of Metastatic Spinal Cord Compression. Oncologist 25(3): 210–e422 [PMC free article: PMC7066690] [PubMed: 32162821] | Outcomes do not match review protocol – no outcomes reported (trial was closed prematurely) |
| Sze, W. M., Shelley, M., Held, I. et al. (2004) Palliation of metastatic bone pain: single fraction versus multifraction radiotherapy - a systematic review of the randomised trials. Cochrane Database of Systematic Reviews: cd004721 [PMC free article: PMC6599833] [PubMed: 15106258] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Thirion, P. G., Dunne, M. T., Kelly, P. J. et al. (2020) Non-inferiority randomised phase 3 trial comparing two radiation schedules (single vs. five fractions) in malignant spinal cord compression. British Journal of Cancer 122: 1315–1323 [PMC free article: PMC7188681] [PubMed: 32157242] | Other protocol criteria - secondary publication of ICORG 05-03 trial (Lee 2018), but no additional relevant outcome data reported that match the protocol for this review |
| Trilling, G. M., Cho, H., Ugas, M. A. et al. (2012) Spinal metastasis in head and neck cancer. Head and Neck Oncology 4(1) [PMC free article: PMC3448515] [PubMed: 22716187] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| van der Linden, YM, Dijkstra, SP, Vonk, EJ et al. (2005) Prediction of survival in patients with metastases in the spinal column: results based on a randomized trial of radiotherapy. Cancer 103(2): 320–328 [PubMed: 15593360] | Intervention does not match review protocol |
| Van Der Linden, YM, Steenland, E, Post, WJ et al. (2002) Singledose irradiation of painful bone metastases is as effective as multiple fractions. Outcome of the Dutch Bone Metastasis Study. Nederlands tijdschrift voor geneeskunde 146(35): 1645–1650 | Other protocol criteria – not available in English |
| Verbiest, A., De Meerleer, G., Albersen, M. et al. (2018) Non-surgical ablative treatment of distant extracranial metastases for renal cell carcinoma: A systematic review. Kidney Cancer 2(1): 57–67 | Intervention does not match review protocol |
| Westhoff, P. G., de Graeff, A., Monninkhof, E. M. et al. (2018) Effectiveness and toxicity of conventional radiotherapy treatment for painful spinal metastases: a detailed course of side effects after opposing fields versus a single posterior field technique. Journal of Radiation Oncology 7: 17–26 [PMC free article: PMC5856865] [PubMed: 29576859] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Wild, A. T. and Yamada, Y. (2017) Treatment Options in Oligometastatic Disease: Stereotactic Body Radiation Therapy - Focus on Colorectal Cancer. Visceral Medicine 33: 54–61 [PMC free article: PMC5465794] [PubMed: 28612018] | Publication type does not match review protocol – expert review/narrative |
| Wowra, B, Zausinger, S, Muacevic, A et al. (2009) Radiosurgery for spinal malignant tumors. Deutsches Aerzteblatt International 106(7): 106–112 [PMC free article: PMC2696242] [PubMed: 19562022] | Study design does not match review protocol – expert review/narrative |
| Yang, J., Yan, J., Zeng, M. et al. (2020) Bone metastases of gastrointestinal stromal tumor: A review of published literature. Cancer Management and Research 12: 1411–1417 [PMC free article: PMC7049741] [PubMed: 32161493] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Yao, A., Sarkiss, C. A., Ladner, T. R. et al. (2017) Contemporary spinal oncology treatment paradigms and outcomes for metastatic tumors to the spine: A systematic review of breast, prostate, renal, and lung metastases. Journal of Clinical Neuroscience 41: 11–23 [PubMed: 28462790] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
| Young, RF; Post, EM; King, GA (1980) Treatment of spinal epidural metastases. Randomized prospective comparison of laminectomy and radiotherapy. Journal of neurosurgery 53(6): 741–748 [PubMed: 7441333] | Publication date before cutoff in review protocol |
| Zuckerman, S. L., Lim, J., Yamada, Y. et al. (2018) Brachytherapy in Spinal Tumors: A Systematic Review. World Neurosurgery 118: e235–e244 [PubMed: 29966796] | Study design does not match protocol criteria - systematic review without pooled results/quantitative data, checked for relevant studies |
Excluded economic studies
A global search of economic evidence was undertaken for all review questions in this guideline. See Supplement 2 for further information
Appendix K. Research recommendations – full details
Final
These evidence reviews were developed by NICE
Disclaimer: The recommendations in this guideline represent the view of NICE, arrived at after careful consideration of the evidence available. When exercising their judgement, professionals are expected to take this guideline fully into account, alongside the individual needs, preferences and values of their patients or service users. The recommendations in this guideline are not mandatory and the guideline does not override the responsibility of healthcare professionals to make decisions appropriate to the circumstances of the individual patient, in consultation with the patient and/or their carer or guardian.
Local commissioners and/or providers have a responsibility to enable the guideline to be applied when individual health professionals and their patients or service users wish to use it. They should do so in the context of local and national priorities for funding and developing services, and in light of their duties to have due regard to the need to eliminate unlawful discrimination, to advance equality of opportunity and to reduce health inequalities. Nothing in this guideline should be interpreted in a way that would be inconsistent with compliance with those duties.
NICE guidelines cover health and care in England. Decisions on how they apply in other UK countries are made by ministers in the Welsh Government, Scottish Government, and Northern Ireland Executive. All NICE guidance is subject to regular review and may be updated or withdrawn.
- Stereotactic body radiotherapy versus conventional external beam radiotherapy in patients with painful spinal metastases: an open-label, multicentre, randomised, controlled, phase 2/3 trial.[Lancet Oncol. 2021]Stereotactic body radiotherapy versus conventional external beam radiotherapy in patients with painful spinal metastases: an open-label, multicentre, randomised, controlled, phase 2/3 trial.Sahgal A, Myrehaug SD, Siva S, Masucci GL, Maralani PJ, Brundage M, Butler J, Chow E, Fehlings MG, Foote M, et al. Lancet Oncol. 2021 Jul; 22(7):1023-1033. Epub 2021 Jun 11.
- Re-irradiation of brain metastases and metastatic spinal cord compression: clinical practice suggestions.[Tumori. 2005]Re-irradiation of brain metastases and metastatic spinal cord compression: clinical practice suggestions.Maranzano E, Trippa F, Pacchiarini D, Chirico L, Basagni ML, Rossi R, Bellavita R, Schiavone C, Italiani M, Muti M. Tumori. 2005 Jul-Aug; 91(4):325-30.
- External beam radiation dose escalation for high grade glioma.[Cochrane Database Syst Rev. 2020]External beam radiation dose escalation for high grade glioma.Khan L, Soliman H, Sahgal A, Perry J, Xu W, Tsao MN. Cochrane Database Syst Rev. 2020 May 21; 5(5):CD011475. Epub 2020 May 21.
- Review Radiotherapy for palliation of symptoms in incurable cancer.[Curr Probl Cancer. 1997]Review Radiotherapy for palliation of symptoms in incurable cancer.Hoegler D. Curr Probl Cancer. 1997 May-Jun; 21(3):129-83.
- Review Single fraction external beam radiation therapy in the treatment of localized metastatic bone pain. A review.[J Pain Symptom Manage. 2001]Review Single fraction external beam radiation therapy in the treatment of localized metastatic bone pain. A review.Jeremic B. J Pain Symptom Manage. 2001 Dec; 22(6):1048-58.
- Evidence reviews for radiotherapyEvidence reviews for radiotherapy
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