Proton Beam Radiation therapy for Prostate Cancer Policy: The use of Proton Beam Therapy (PBT) in Prostate cancer has not been established as more effective than other forms of External Beam Radiation Therapies (EBRT s), such as Intensity Modulated Radiation Therapy (IMRT). PBT has more gastrointestinal morbidity than IMRT (1, 3) and IMRT is more cost-effective than PBT for patients with prostate cancer (2, 6). IEHP considers Proton Beam Therapy for localized Prostate cancer to be not medically necessary as it has not been established to be more effective in increasing overall survival, and reducing gastrointestinal morbidities when compared to IMRT. Thus IEHP adopts IMRT as it treatment of choice for localized prostate cancer. Analysis of the medical literature does not demonstrate proton beam therapy to clinically superior to other forms of EBRT (4, 5). Alternative forms of EBRT are more readily available and more cost-effective (2, 6). Medically Necessary/Medical Necessity includes in part that the services is "not more costly than an alternative service or sequence of services at least as likely to produce equivalent therapeutic or diagnostic results as to the diagnosis or treatment of that individual's illness, injury or disease. Medi-Cal Proton Beam Treatment Policy Update Effective for dates of service on or after February 1, 2013, CPT-4 codes 77520 77525 are not reimbursable when claimed with ICD-9-CM code 185 (malignant neoplasm of prostate) or 233.4 (carcinoma in situ, prostate). Neither the National Cancer Institute nor the National Institute of Health recommends Proton Beam Treatment (PBT) for prostate cancer treatment since clinical trials are still being done to prove its efficacy and safety. Additionally, the California Code of Regulations (CCR), Title 22, Section 51303, excludes experimental and investigational therapies as benefits in the scope of services provided by the Department of Health Care Services (DHCS). 10801 Sixth St, Suite 120, Rancho Cucamonga, CA 91730 Tel (909) 890-2000 Fax (909) 890-2003 Visit our web site at: www.iehp.org A Public Entity
Page 2 of 7 Medical Review Criteria Guidelines for Managing Care (Apollo): Indications/Coverage examples: Proton Beam Radiotherapy is covered on the basis of medical necessity for any of the following radiosensitive tumors: 1. Uveal melanomas confined to the globe (iris, choroid or cilial body) without evidence of metastases or extrascleral extension, and tumors up to 24 mm in diameter. (the uvea is comprised of the iris, ciliary body, and choroid - the vascular middle coat of the eye) 2. Chordomas or chondrosarcomas arising at the base of the skull or along the axial skeleton without metastases. 3. Pituitary adenoma when conventional stereotactic radiation is not an option. 4. Other central nervous system tumors located near vital structures. 5. Intracranial arteriovenous malformations (AVMs) not amenable to surgical excision or other conventional forms of treatment. 6. CNS lesions (primary or metastatic malignancies or AVMs) measuring < 3 cm in diameter that are adjacent to critical structures such as the optic nerve, base of skull, brain stem or spinal cord. 7. Prostate cancer (as an option in addition to IMRT or conformal radiation therapy. Limitations/exclusions - verify coverage with each health plan covered indications vary: 1. Proton Beam Therapy is significantly more expensive therapy than other options, but not clinically superior; therefore, some health plans will not cover proton beam therapy for prostate cancer. 2. Proton Beam Radiotherapy does not have substantial evidence for clinical efficacy and may be considered experimental for age-related macular degeneration, non-uveal melanomas, hepatocellular carcinomas and choroidal hemangiomas. ECRI s Health Technology Assessment Information Service: Table 2. Systematic Reviews and Technology Assessments Reference Purpose of Systematic Review Technology Assessment Resources Searched and Inclusion Criteria Findings Conclusions Reported in the Abstract
Page 3 of 7 Samson DJ 2011 Blue Cross and Blue Shield Association (9) Ollendorf et al. 2008 Institute for Clinical and Economic Review (ICER) (6) To compare the effects of proton beam therapy, with or without external beam radiotherapy, against alternative radiotherapy modalities and other treatments of prostate cancer. To appraise the comparative clinical effectiveness and comparative value of brachytherapy, IMRT, and PBT for men with clinically-localized, lowrisk prostate cancer. MEDLINE (via PubMed) search was performed from January 1966 through March 2011 and was limited to English-language articles on human subjects. 234 citations were identified. Bibliographies from recent review articles and clinical studies were also reviewed. Inclusion criteria included fulllength English language publications, comparative trials of any size or single-arm studies of at least 10 patients per arm with prostate cancer; reporting on one or more relevant outcomes. MEDLINE, EMBASE, and The Cochrane Library (including the Database of Abstracts of Reviews of Effects) plus reference lists of all eligible studies published during the period January 1995 August 2008; for IMRT, publications between January 2007 and August 2008 were added to studies from the previous ICER appraisal This review did not identify any clinical trials evaluating the use of intensity-modulated radiation therapy (IMRT) compared to proton beam therapy (PBT) to treat prostate cancer. Of the 387 articles identified for inclusion, no comparison studies of interest were identified; only 15 single arm studies (6 PBT, 9 IMRT). There is inadequate evidence from comparative studies to permit conclusions for any of the 4 comparisons considered here. No evidence has been presented to date on the effects of either PBT or IMRT on overall or disease-specific survival, limiting the Table 3: Comparative Clinical Trials Reference Nonrandomized Controlled/Comparison Studies Sheets et al. 2012 (1) 1368 patients with localized prostate cancer Number of Patients Treatment Results Conclusions Presented in the Abstract Intensity modulated radiation therapy (IMRT) vs. proton therapy Based on Surveillance, Epidemiology, and End Results-Medicare linked data from 2000 to 2009, a propensity scorematched comparison of IMRT and proton therapy indicated that IMRT patients had a lower rate of gastrointestinal morbidity (absolute risk, 12.2 vs. 17.8 per 100 person-years; relative Among patients with nonmetastatic prostate cancer [the use of] IMRT compared with proton therapy was associated with less gastrointestinal morbidity.
Page 4 of 7 risk, 0.66; 95% confidence interval, 0.55 0.79). Yoon et al. 2010 (8) 5 prostate cancer patients IMRT vs. proton therapy Secondary cancer risk was assessed by ion chamber and CR-39 detectors during IMRT and proton therapy, respectively. The average secondary dose of IMRT was approximately one order of magnitude higher than proton therapy (range 3 msv/gy [millisievert/gray] to 1 msv/gy (IMRT) vs. 0.4 msv/gy to 0.1 msv/gy (proton therapy). Comparisons of organspecific organ equivalent dose showed that the estimated secondary cancer risk using scattering mode in proton therapy is either significantly lower than the cases in IMRT treatment or, at least, does not exceed the risk induced by conventional IMRT treatment. National Comprehensive Cancer Network Guideline on Prostate Cancer: Proton Therapy is not recommended for routine use at this time, since clinical trials have not yet yielded data to demonstrate superiority to, or equivalence of, Proton Beam and conventional beam for treatment of prostate cancer. (4) AHRQ s Technology Assessment (March 2010): For comparative effectiveness between different forms of radiation treatments (BT, EBRT, SBRT), available data also could not determine if one form of radiation therapy is superior to another form in terms of overall or disease-specific survival. Available data suggest that higher EBRT dose is associated with increased rates of long-term biochemical control compared with lower EBRT dose. Available data also suggest BT is associated with more genitourinary toxicity and less gastrointestinal toxicity compared with EBRT. Whether EBRT is administered as a standard fractionation or moderate hypofractionation seems to make little difference in terms of biochemical control and late genitourinary and gastrointestinal toxicities. (5) American College of Radiology (2006): For stage T1 and T2 prostate cancer, the American College of Radiology (ACR) (2006) indicates that dose escalation using IMRT has an improved therapeutic ratio with improved PSA relapse free survival rates and reduced gastrointestinal and genitourinary toxicity. Due to limited data comparing Proton Beam Therapy to other methods of irradiation or to radical Prostatectomy, however, the ACR indicates that further studies are needed to clearly define its role to treat stage T1, and T2 prostate cancer. (7)
Page 5 of 7 National Cancer Institute (NCI): The NCI (2011) lists PBT as a treatment option under clinical evaluation due to a lack of supporting data. NCI states although Proton Therapy could theoretically improve the therapeutic ratio of prostate radiation, allowing for an increase in dose to the tumor without a substantial increase in side effects, no randomized controlled trials have been conducted to compare its efficacy and toxicity with those of other forms of radiation therapy. American Society of Radiation Oncology (ASTRO): In a technology evaluation of PBT, ASTRO (2010) concluded that outcomes for patients treated with PBT were similar to those treated with Intensity Modulated Radiation Therapy (IMRT). Based on the clinical data, there was no clear benefit from PBT over IMRT including disease control or prevention of late toxicity. ASTRO stated that further head to head clinical trials may be needed to determine the role of PBT in treating prostate cancer. Cigna Medical Coverage Policy for Proton Beam Therapy in Prostate Cancer: Cigna covers Proton Beam Therapy (PBT) as medically necessary for the treatment of localized cancer of the prostate (i.e., cancer that is confined to the prostate). Cigna considers proton beam therapy to be clinically equivalent, but not clinically superior, to conventional external beam radiation therapy (i.e., three-dimensional conformal radiotherapy [3D-CRT], intensity modulated radiation therapy [IMRT] or image-guided radiation therapy [IGRT]) for the treatment of localized cancer of the prostate. Coverage for Proton Beam Therapy for the treatment of localized prostate cancer may depend upon the applicable health benefit plan definition of medical necessity. Many health benefit plans administered by Cigna contain definitions of medical necessity which include a cost comparison component. Because Proton Beam Therapy for the treatment of localized prostate cancer is significantly more expensive than conventional External Beam Radiation Therapy (i.e., threedimensional Conformal Radiotherapy [3D-CRT], Intensity Modulated Radiation Therapy [IMRT] or Image-Guided Radiation Therapy [IGRT]) but is not clinically superior, it is considered not medically necessary under those plans. For health benefit plans which contain definitions of medical necessity that do not include a cost comparison component, proton beam therapy may be covered as medically necessary for the treatment of localized prostate cancer (i.e., cancer that is confined to the prostate). Effective Date: May 9, 2012 Reviewed Annually: November 12, 2014 Revised: April 2, 2015
Page 6 of 7 Bibliography: 1. Sheets, NC, Goldin, GH, Meyer, AM, Wu, Y, Chang, Y, Sturmer, T, Holmes, JA, Reeve, BB, Godley, PA, Carpenter, WR, and Chen, RC. Intensity-modulated radiation therapy, proton therapy, or conformal radiation therapy and morbidity and disease control in localized prostate cancer. JAMA. 2012;307(15):1611-1620.. 2. Kagan, RA. And Schulz RJ. Proton-Beam Therapy for Prostate Cancer. The Cancer Journal. 2010; 16: 405-409. 3. Kim, S. Shen, S. Moore, DF. Et al. Late Gastrointestinal Toxicities following Radiation Therapy for Prostate Cancer. Eur Urol. 2011 4. National Comprehensive Cancer Network Clinical Guidelines in Oncology. Prostate Cancer Version 3.2012. website http://www.nccn.org/index.asp 5. Stanley, IP. Dvorak T. Yu, WW. et al. Comparative Evaluation of Radiation Treatments for Clinically Localized Prostate Cancer. Agency for Healthcare Research and Quality technology assessment program. March 2010. Accessed at https://www.cms.gov/medicare/coverage/coveragegeninfo/downloads//id69ta.pdf 6. Ollendorf DA, Hayes J, McMahon P, Kuba M, Tramontano A, Pearson SD. Brachytherapy/proton beam therapy for clinically localized, low-risk prostate cancer. Institute for Clinical and Economic Review. 2008. 7. American College of Radiology (ACR). Moran BJ, DeRose P, Merrick G, Hsu IC, Abdel-Wahab M, Arterbery VE, Ciezki JP, Frank SJ, Mohler JL, Rosenthal SA, Rossi CJ Jr, Yamada Y, Expert Panel on Radiation Oncology-Prostate. ACR Appropriateness Criteria definitive external beam irradiation in stage T1 and T2 prostate cancer. 2006 (reviewed 2010). 8. Yoon, M, Ahn, SH, Kim, J, Shin, DH, Park, SY, Lee, SB, Shin, KH, and Cho, KH. Radiation-induced cancers from modern radiotherapy techniques: intensity-modulated radiotherapy versus proton therapy. Int J Radiat Oncol Biol Phys. 2010;77(5):1477-1485. 9. Blue Cross and Blue Shield Association, Technology Evaluation Center, Samson DJ. Proton beam therapy for prostate cancer. 2011. 10. Cigna Medical Coverage Policy on Proton Beam Therapy for Prostate Cancer. Policy # 0252. Accessed 5/7/2012 at http://www.cigna.com/assets/docs/health-careprofessionals/coverage_positions/mm_0252_coveragepositioncriteria_proton_beam_therapy_for_prostate_ cancer.pdf 11. National Cancer Institute (NCI). Prostate cancer (PDQ): treatment. Oct 7, 2011. Accessed Nov 4, 2011. Available at URL address: http://www.cancer.gov/cancertopics/pdq/treatment/prostate/healthprofessional/allpages 12. American Society of Radiation Oncology (ASTRO). Emerging technology. Proton beam radiation therapy. 2010. Accessed Nov 4, 2011. Available at URL address: http://www.astro.org/healthpolicy/emergingtechnology/evaluationprojects/index.aspx 13. Medi-Cal, Proton Beam Treatment Policy Update Accessed 04/02/2015 from http://files.medi-cal.ca.gov/pubsdoco/bulletins/artfull/gm201301.asp#a9
Page 7 of 7 Disclaimer IEHP Clinical Authorization Guidelines (CAG) are developed to assist in administering plan benefits, they do not constitute a description of plan benefits. The Clinical Authorization Guidelines (CAG) express IEHP's determination of whether certain services or supplies are medically necessary, experimental and investigational, or cosmetic. IEHP has reached these conclusions based upon a review of currently available clinical information (including clinical outcome studies in the peer-reviewed published medical literature, regulatory status of the technology, evidencebased guidelines of public health and health research agencies, evidence-based guidelines and positions of leading national health professional organizations, views of physicians practicing in relevant clinical areas, and other relevant factors). IEHP makes no representations and accepts no liability with respect to the content of any external information cited or relied upon in the Clinical Authorization Guidelines (CAG). IEHP expressly and solely reserves the right to revise the Clinical Authorization Guidelines (CAG), as clinical information changes.