MA: Charged Particle Radiation, Helium Ion or Proton and Stereotactic Radiosurgery

EFFECTIVE: 01/01/2025

Description

Stereotactic radiosurgery (SRS) refers to the delivery of a single very limited number of relatively large doses of radiation administered to a small, precisely defined target. This is achieved by using multiple, non-parallel radiation beams that converge on the target lesion. The full therapeutic dose is limited to the area where all of the beams overlap, while non-target areas receive much smaller doses from one or a limited number of radiation beams. SRS thus requires accurate localization of the lesion and patient positioning during treatment.

SRS may offer a non-invasive alternative to invasive surgery, particularly for patients unable to undergo surgery or for lesions that are difficult to access surgical or are adjacent to vital organs.

Cranial stereotactic radiosurgery (SRS) is a method of delivering high doses of precisely targeted ionizing radiation to intracranial lesions.

SRS, when used extracranially, is called stereotactic body radiation therapy (SBRT). Platforms available for SRS and SBRT are distinguished by their source of radiation: they include gamma radiation from cobalt 60 sources; high energy photon from LINAC systems; and particle beams (protons).

Fractionated stereotactic radiotherapy refers to when SRS or SBRT is performed more than one time on a specific site. SBRT is commonly delivered over 3-5 fractions. SRS is most often single-fraction treatment; however, multiple fractions may be necessary when lesions are near critical structures, tumors have an unusual shape or when high-dose single fraction treatment could not be tolerated.

Many patients with brain metastases can either receive whole brain radiotherapy (WBRT) along with SRS or WBRT may be delayed for use as salvage therapy for recurrent intracranial disease.

Proton beam radiation therapy (PBRT) is a type of radiotherapy using protons rather than photons used in traditional external beam radiation therapy. Proton beam radiation therapy (PBRT) is also known as intensity-modulated proton therapy (IMPT), proton therapy and proton beam radiotherapy. PBRT has been used for the treatment of tumors that would benefit from the delivery of high dose or radiation with limited scatter.

Policy

Stereotactic radiosurgery (SRS) using a gamma knife, cyberknife, or Linac (linear accelerator) may be considered scientifically validated for ANY of the following indications:
1. acoustic neuroma (vestibular schwannomas) OR
2. arteriovenous malformations OR
3. craniopharyngioma OR
4. glomus jugulare tumors (hypervascular tumor that arises within the jugular foramen of the temporal bone) OR
5. malignancies of the CNS (gliomas, astrocyomas) OR
6. solitary or multiple brain metastases, in patients with a good performance status and no systemic disease (Karnofsky performance scale of at least 70) and extracranial disease that is stable or in remission OR
7. meningiomas that are nonresectable, residual, or recurrent OR
8. pituitary adenoma OR
9. trigeminal neuralgia that is refractory to medical management OR
10. mesial temporal lobe epilepsy refractory to medical management when standard alternative surgery is not an option OR
11. uveal melanoma
All other indications for stereotactic radiosurgery (SRS) using a gamma knife, cyberknife, or Linac (linear accelerator) are considered Investigational.
Stereotactic Body Radiotherapy (SBRT) / Stereotactic Ablative Body Radiotherapy (SARB) may be considered scientifically validated for ANY of the following indications:
1. non-small cell lung cancer, Stage 1, in patients who are not candidates for surgery for who refuse surgery after informed consent.
2. non-small cell lung cancer, with oligometastasis, i.e. 1-3 metastatic lesions, when ALL of the following are met:
  1. definitive RT to the oligometastasis is planned AND
  2. radical therapy to the intrathoracic disease is planned or has been received AND
  3. metastatic sites are in the lung and/or adrenal gland AND
  4. patient has good performance status i.e. Karnofsky performance status (KPS) of at least 70
3. oligometastasis to the lung from a cancer of unknown primary (NCCN also refers to this as occult primary), when ALL of the following are met:
  1. metastatic lesions are present in the lungs AND
  2. patient has good performance status i.e. Karnofsky performance status (KPS) is at least 70
4. spinal tumors, primary- that cause intractable pain or spinal cord compression
5. spinal tumors, primary or metastatic - in patients who have received previous radiotherapy (RT)
6. spinal tumors, metastatic- that are radio-resistant e.g. renal cell cancer, melanoma, sarcoma
7. primary or metastatic tumors of the liver as an alternative locoregional treatment for patients with inoperable primary or metastatic lesions.
8. primary renal cell carcinoma in patients who are not good surgical candidates or for metastatic renal carcinoma
9. pancreatic cancer without invasion of bowel or stomach
10. prostate cancer when ALL of the following are met:
  1. low grade prostate cancer with a Gleason score of less than or equal to 6 and a PSA less than 10 ng/ml AND
  2. minimal disease with less than four cores positive, AND
  3. no evidence of extra prostatic disease AND
  4. life expectancy is greater than 10 years
11. oligometastatic prostate cancer with 1-3 metastatic lesions
12. oligometastatic breast cancer with 1-3 metastatic lesions
All other indications for Stereotactic Body Radiotherapy (SBRT)/ Stereotactic Ablative Body Radiotherapy (SABR) are considered Investigational.
Fractionation is considered medically necessary when it is used to deliver stereotactic radiosurgery (SRS) or stereotactic body radiation (SBRT) for the medically necessary indications described above.
Charged-particle irradiation with proton or helium ion beams may be considered scientifically validated for ANY of the following indications:
1. melanoma of the uveal tract (iris, choroid, or ciliary body) with no evidence of extrascleral extension or metastasis OR
2. chordomas or chondrosarcomas arising at the base of the skull or cervical spine without distant metastases OR
3. pediatric central nervous system tumors.
All other indications for Charged-particle irradiation with proton or helium ion beams are considered Investigational.

Karnofsky Performance Status Scale

Able to carry on normal activity and to work; no special care needed.	100	Normal no complaints; no evidence of disease.
	90	Able to carry on normal activity; minor signs or symptoms of disease.
	80	Normal activity with effort; some signs or symptoms of disease.
Unable to work; able to live at home and care for most personal needs; varying amount of assistance needed.	70	Cares for self; unable to carry on normal activity or to do active work.
	60	Requires occasional assistance, but is able to care for most of his personal needs.
	50	Requires considerable assistance and frequent medical care.
Unable to care for self; requires equivalent of institutional or hospital care; disease may be progressing rapidly.	40	Disabled; requires special care and assistance.
	30	Severely disabled; hospital admission is indicated although death not imminent.
	20	Very sick; hospital admission necessary; active supportive treatment necessary.
	10	Moribund; fatal processes progressing rapidly.
	0	Dead

Background

Stereotactic guidance: precision in target localization is a prerequisite for successful SRS.

This can be accomplished through the attachment of a stereotactic head frame using four pins that attach to the outer table of the skull. The head frame placement is usually done with local anesthesia, although sedation may be required.

After placement of a head frame, high resolution computed tomography (CT) or magnetic resonance imaging (MRI) is obtained to visualize its four posts. Spatial coordinates for the lesion are calculated relative to these landmarks. During the RT session, the frame is bolted to the treatment couch to immobilize the patient, allowing precise targeting of the radiation. The patient is treated on the same day that the head frame is placed.

Frameless radiosurgery is a reasonable option for palliative treatment of malignant disease, larger lesions, and mulitfraction treatments.

Codes

32701	61796	61797	61798
61799	61800	63620	63621
76499	77432	77435	77499
7750	77522	77523	77525
C9795	G0339	G0340

References

Wijetunga N, Anjos C, Zhi W et al. Long-term disease control and survival observed after stereotactic ablative body radiotherapy for oligometastatic breast cancer. Cancer Med. 2021 Aug;10(15):5163-5174. Published: 2021

Palma D, Olson R, Harrow S et al. Stereotactic Ablative Radiotherapy for the Comprehensive Treatment of Oligometastatic Cancers: Long-Term Results for the SABR-COMET Phase II Randomized Trial. Journal of Clinical Oncology. 2019; May 18;393(1085):2051-2058. Published: 2019

Mehrens D, Unterrainer M, Corradini S, et al. Cost-Effectiveness Analysis of Local Treatment in Oligometastatic Disease. Frontiers in Oncology. 2021;(11):667993 Published: 2021

Li J, Arifin A, Al-Shafa F et al. A review of ongoing trials of stereotactic ablative radiotherapy for oligometastatic disease in the context of new consensus definitions. Annals of Palliatvie Medicine. 2021 May;10(5):6045-6054. Published: 2021

David S, Tan J et al. Stereotactic ablative body radiotherapy (SABR) for bone only oligometastatic breast cancer: A prospective clinical trial. Breast. 2020; Feb;49:55-62. Published: 2020

Rogowski, P., Roach, M., Schmidt-Hagemann, N.S., et al. Radiotherapy of oligometastatic prostate cancer: a systematic review. Radiation Oncology. 2021;16(50). Published: 2021

Viani, G.A., Arruda, C.V., Hamamura, A.C., et al. Stereotactic body radiotherapy for oligometastatic prostate cancer recurrence- a meta analysis. American Journal of Clinical Oncology. 2020;43(2) 73-81. Published: 2020

Parker T, Rigney G, Kallos J, et al. Gamma knife radiosurgery for uveal melanomas and metastases: a systematic review and meta-analysis. Lancet Oncol. Nov 2020; 21(11): 1526-1536. PMID 33152286 Published: 2020

Evans, J.D., Morris, L.K., Zhang, H., et al. Prospective immunophenotyping of CD8 T-cells and associated clinical outcomes of patients with oligometastatic prostate cancer treated with metastatsis directed SBRT. Int J Radiat Oncol Biol Phys. January 2019;103(1):229-240. Published: 2019

Eibl-Lindner K, Furweger C, Nentwich M, et al. Robotic radiosurgery for the treatment of medium and large uveal melanoma. Melanoma Res. Feb 2016; 26(1): 51-7. PMID 26484738 Published: 2016

Palacios-Eito, A., Bejar-Luque, A., et al. Oligometastases in prostate cancer: ablative treatment. World Journal of Clinical Oncology. 2019;10(2): 38-51. Published: 2019

Gerszten PC, et al. Radiosurgery for Spinal Metastases. Clinical Experience in 500 Cases From a Single Institution. Spine. 2007. 32(2): pp 193-199. Published: 2007

Hara R, et al. Clinical Outcomes of Single-Fraction Stereotactic Radiation Therapy of Lung Tumors. Cancer. 2006. 106(6): pp 1347-1352. Published: 2006

Naff NJ. CyberKnife Radiosurgery in Neurosurgical Practice. Neurosurg Q. 2007; 17(4):pp 273-282. Published: 2007

California Technology Assessment Forum. (Draft) Stereotactic Body Radiation Therapy for the Treatment of Early Stage Non Small Cell Lung Cancer. Last Reviewed: 2008. Published: 2008

Romanelli P and Adler JR. Technology Insight: image-guided robotic radiosurgery—a new approach for noninvasive ablation of spinal lesions. Nature Clinical Practice Oncology. 2008; 5(7):405-414. Published: 2008

Cotter, S et al. Proton radiotherapy for solid tumors of childhood. Technology in Cancer Research & Treatment. Volume 11, Number 3, June 2012. Published: 2012

Ruysscher, D et al. Charged particles in radiotherapy: a 5 year update of a systematic review. Radiotherapy and Oncology 103 (2012) 5–7. Published: 2012

Furdova A, Sramka M, Chorvath M, et al. Stereotactic radiosurgery in intraocular malignant melanoma--retrospective study. Neuro Endocrinol Lett. 2014; 35(1): 28-36. PMID 24625918 Published: 2014

Sarici AM, Pazarli H. Gamma-knife-based stereotactic radiosurgery for medium- and large-sized posterior uveal melanoma. Graefes Arch Clin Exp Ophthalmol. Jan 2013; 251(1): 285-94. PMID 22944897 Published: 2013

Muller K, Naus N, Nowak PJ, et al. Fractionated stereotactic radiotherapy for uveal melanoma, late clinical results. Radiother Oncol. Feb 2012; 102(2): 219-24. PMID 21864922 Published: 2012

Barbaro NM, Quigg M, Ward MM, et al. Radiosurgery versus open surgery for mesial temporal lobe epilepsy: The randomized, controlled ROSE trial. Epilepsia. Jun 2018; 59(6): 1198-1207. PMID 29600809 Published: 2018

Quigg M, Barbaro NM, Ward MM, et al. Visual field defects after radiosurgery versus temporal lobectomy for mesial temporal lobe epilepsy: Findings of the ROSE trial. Seizure. Dec 2018; 63: 62-67. PMID 30408713 Published: 2018

McGonigal A, Sahgal A, De Salles A, et al. Radiosurgery for epilepsy: Systematic review and International Stereotactic Radiosurgery Society (ISRS) practice guideline. Epilepsy Res. Nov 2017; 137: 123-131. PMID 28939289 Published: 2017

Feng ES, Sui CB, Wang TX, et al. Stereotactic radiosurgery for the treatment of mesial temporal lobe epilepsy. Acta Neurol Scand. Dec 2016; 134(6): 442-451. PMID 26846702 Published: 2016

Regis J, Bartolomei F, Rey M, et al. Gamma knife surgery for mesial temporal lobe epilepsy. J Neurosurg. Dec 2000; 93 Suppl 3: 141-6. PMID 11143232 Published: 2009

De Maria L, Terzi di Bergamo L, Conti A, et al. CyberKnife for Recurrent Malignant Gliomas: A Systematic Review and Meta-Analysis. Front Oncol. 2021; 11: 652646. PMID 33854978 Published: 2021

El-Shehaby AM, Reda WA, Abdel Karim KM, et al. Gamma Knife radiosurgery for low-grade tectal gliomas. Acta Neurochir (Wien). Feb 2015; 157(2): 247-56. PMID 25510647 Published: 2015

Clark GM, McDonald AM, Nabors LB, et al. Hypofractionated stereotactic radiosurgery with concurrent bevacizumab for recurrent malignant gliomas: the University of Alabama at Birmingham experience. Neurooncol Pract. Dec 2014; 1(4): 172-177. PMID 26034629 Published: 2014

Dodoo E, Huffmann B, Peredo I, et al. Increased survival using delayed gamma knife radiosurgery for recurrent high-grade glioma: a feasibility study. World Neurosurg. Nov 2014; 82(5): e623-32. PMID 24930898 Published: 2014

MA: Charged Particle Radiation, Helium Ion or Proton and Stereotactic Radiosurgery

EFFECTIVE: 01/01/2025

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