3D calculation of radiation-induced second cancer risk including dose and tissue response heterogeneities.

PURPOSE Tools for comparing relative induced second cancer risk, to inform choice of radiotherapy treatment plan, are becoming increasingly necessary as the availability of new treatment modalities expands. Uncertainties, in both radiobiological models and model parameters, limit the confidence of such calculations. The aim of this study was to develop and demonstrate a software tool to produce a malignant induction probability (MIP) calculation which incorporates patient-specific dose and allows for the varying responses of different tissue types to radiation. METHODS The tool has been used to calculate relative MIPs for four different treatment plans targeting a subtotally resected meningioma: 3D conformal radiotherapy (3DCFRT), volumetric modulated arc therapy (VMAT), intensity-modulated x-ray therapy (IMRT), and scanned protons. RESULTS Two plausible MIP models, with considerably different dose-response relationships, were considered. A fractionated linear-quadratic induction and cell-kill model gave a mean relative cancer risk (normalized to 3DCFRT) of 113% for VMAT, 16% for protons, and 52% for IMRT. For a linear no-threshold model, these figures were 105%, 42%, and 78%, respectively. The relative MIP between plans was shown to be significantly more robust to radiobiological parameter uncertainties compared to absolute MIP. Both models resulted in the same ranking of modalities, in terms of MIP, for this clinical case. CONCLUSIONS The results demonstrate that relative MIP is a useful metric with which treatment plans can be ranked, regardless of parameter- and model-based uncertainties. With further validation, this metric could be used to discriminate between plans that are equivalent with respect to other planning priorities.

[1]  Buddhini Samarasinghe,et al.  The Hallmarks of Cancer: Fighting Back , 2013 .

[2]  S. Ashley,et al.  Risk of second brain tumor after conservative surgery and radiotherapy for pituitary adenoma: update after an additional 10 years. , 2005, The Journal of clinical endocrinology and metabolism.

[3]  Joseph O Deasy,et al.  CERR: a computational environment for radiotherapy research. , 2003, Medical physics.

[4]  David J Brenner,et al.  Solid tumor risks after high doses of ionizing radiation. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[5]  A. Niemierko,et al.  Secondary Carcinogenesis in Patients Treated with Radiation: A Review of Data on Radiation-Induced Cancers in Human, Non-human Primate, Canine and Rodent Subjects , 2007, Radiation research.

[6]  P. Mahadevan,et al.  An overview , 2007, Journal of Biosciences.

[7]  Philip Hahnfeldt,et al.  Second cancers after fractionated radiotherapy: stochastic population dynamics effects. , 2007, Journal of theoretical biology.

[8]  S. Yuspa,et al.  Critical Aspects of Initiation, Promotion, and Progression in Multistage Epidermal Carcinogenesis , 1993, Proceedings of the Society for Experimental Biology and Medicine. Society for Experimental Biology and Medicine.

[9]  I. Toma-Dasu,et al.  The use of risk estimation models for the induction of secondary cancers following radiotherapy , 2005, Acta oncologica.

[10]  S. Moolgavkar Model for human carcinogenesis: action of environmental agents. , 1983, Environmental health perspectives.

[11]  Preetha Rajaraman,et al.  Second solid cancers after radiation therapy: a systematic review of the epidemiologic studies of the radiation dose-response relationship. , 2013, International journal of radiation oncology, biology, physics.

[12]  Harald Paganetti,et al.  A review of dosimetry studies on external-beam radiation treatment with respect to second cancer induction , 2008, Physics in medicine and biology.

[13]  Philip Hahnfeldt,et al.  A new view of radiation-induced cancer: integrating short- and long-term processes. Part II: second cancer risk estimation , 2009, Radiation and environmental biophysics.

[14]  B. Jones,et al.  Malignant induction probability maps for radiotherapy using X-ray and proton beams. , 2011, The British journal of radiology.

[15]  E. Hall Henry S. Kaplan Distinguished Scientist Award 2003The crooked shall be made straight; dose–response relationships for carcinogenesis , 2004, International journal of radiation biology.

[16]  U. Schneider Modeling the Risk of Secondary Malignancies after Radiotherapy , 2011, Genes.

[17]  J. Slabbert,et al.  Assessment of the α/ß ratios for arteriovenous malformations, meningiomas, acoustic neuromas, and the optic chiasma , 2010, International journal of radiation biology.

[18]  T. Vincent,et al.  An evolutionary model for initiation, promotion, and progression in carcinogenesis. , 2008, International journal of oncology.

[19]  A. Sigurdson,et al.  Risk of Second Primary Thyroid Cancer after Radiotherapy for a Childhood Cancer in a Large Cohort Study: An Update from the Childhood Cancer Survivor Study , 2010, Radiation research.

[20]  W. F. Heidenreich,et al.  Systems biological and mechanistic modelling of radiation-induced cancer , 2007, Radiation and environmental biophysics.

[21]  B. Jones Modelling carcinogenesis after radiotherapy using Poisson statistics: implications for IMRT, protons and ions , 2009, Journal of radiological protection : official journal of the Society for Radiological Protection.

[22]  Paolo Vineis,et al.  Models of carcinogenesis: an overview. , 2010, Carcinogenesis.

[23]  Yukiko Shimizu,et al.  Studies of the Mortality of Atomic Bomb Survivors, Report 14, 1950–2003: An Overview of Cancer and Noncancer Diseases , 2012, Radiation research.

[24]  Barbara Kaser-Hotz,et al.  Estimation of radiation-induced cancer from three-dimensional dose distributions: Concept of organ equivalent dose. , 2005, International journal of radiation oncology, biology, physics.

[25]  Paolo Vineis,et al.  Third version: response to reviewers , 2010 .

[26]  M. Tubiana Can we reduce the incidence of second primary malignancies occurring after radiotherapy? A critical review. , 2009, Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology.

[27]  E. Hall,et al.  Radiation-induced second cancers: the impact of 3D-CRT and IMRT. , 2003, International journal of radiation oncology, biology, physics.

[28]  R M Harrison,et al.  Second cancers following radiotherapy: a suggested common dosimetry framework for therapeutic and concomitant exposures. , 2004, The British journal of radiology.

[29]  E. Pedroni,et al.  Secondary neutron dose during proton therapy using spot scanning. , 2002, International journal of radiation oncology, biology, physics.

[30]  B Rachet,et al.  Cancer survival in Australia, Canada, Denmark, Norway, Sweden, and the UK, 1995–2007 (the International Cancer Benchmarking Partnership): an analysis of population-based cancer registry data , 2011, Lancet.

[31]  N. Fukuda,et al.  Dose-response relationship for induction of solid tumors in female B6C3F1 mice irradiated neonatally with a single dose of gamma rays. , 1999, Journal of radiation research.

[32]  P. Strojan,et al.  Secondary intracranial meningiomas after high-dose cranial irradiation: report of five cases and review of the literature. , 2000, International journal of radiation oncology, biology, physics.