Proliferation Saturation Index in an adaptive Bayesian approach to predict patient-specific radiotherapy responses

Abstract Purpose: Radiotherapy prescription dose and dose fractionation protocols vary little between individual patients having the same tumor grade and stage. To personalize radiotherapy a predictive model is needed to simulate radiation response. Previous modeling attempts with multiple variables and parameters have been shown to yield excellent data fits at the cost of non-identifiability and clinically unrealistic results. Materials and methods: We develop a mathematical model based on a proliferation saturation index (PSI) that is a measurement of pre-treatment tumor volume-to-carrying capacity ratio that modulates intrinsic tumor growth and radiation response rates. In an adaptive Bayesian approach, we utilize an increasing number of data points for individual patients to predict patient-specific responses to subsequent radiation doses. Results: Model analysis shows that using PSI as the only patient-specific parameter, model simulations can fit longitudinal clinical data with high accuracy (R2=0.84). By analyzing tumor response to radiation using daily CT scans early in the treatment, response to the remaining treatment fractions can be predicted after two weeks with high accuracy (c-index = 0.89). Conclusion: The PSI model may be suited to forecast treatment response for individual patients and offers actionable decision points for mid-treatment protocol adaptation. The presented work provides an actionable image-derived biomarker prior to and during therapy to personalize and adapt radiotherapy.

[1]  Ping Xia,et al.  Repeat CT imaging and replanning during the course of IMRT for head-and-neck cancer. , 2006, International journal of radiation oncology, biology, physics.

[2]  G. Sandison,et al.  Ill-posed problem and regularization in reconstruction of radiobiological parameters from serial tumor imaging data , 2015, Physics in medicine and biology.

[3]  L. Hlatky,et al.  Acute and fractionated irradiation differentially modulate glioma stem cell division kinetics. , 2013, Cancer research.

[4]  K Hendrickson,et al.  Predicting the efficacy of radiotherapy in individual glioblastoma patients in vivo: a mathematical modeling approach , 2010, Physics in medicine and biology.

[5]  J F Fowler,et al.  21 years of biologically effective dose. , 2010, The British journal of radiology.

[6]  B. Yaremko,et al.  Stereotactic ablative radiotherapy for comprehensive treatment of oligometastatic tumors (SABR-COMET): Study protocol for a randomized phase II trial , 2012, BMC Cancer.

[7]  P. Hahnfeldt,et al.  The Importance of Spatial Distribution of Stemness and Proliferation State in Determining Tumor Radioresponse , 2009 .

[8]  D. Coppola,et al.  Personalizing Gastric Cancer Screening With Predictive Modeling of Disease Progression Biomarkers , 2017, Applied immunohistochemistry & molecular morphology : AIMM.

[9]  Kujtim Latifi,et al.  Predicting Patient-Specific Radiotherapy Protocols Based on Mathematical Model Choice for Proliferation Saturation Index , 2018, Bulletin of mathematical biology.

[10]  David R. Anderson,et al.  Model selection and multimodel inference : a practical information-theoretic approach , 2003 .

[11]  T. Dilling,et al.  Altered fractionation schedules in radiation treatment: a review. , 2014, Seminars in oncology.

[12]  I. Chetty,et al.  Impact of fraction size on lung radiation toxicity: hypofractionation may be beneficial in dose escalation of radiotherapy for lung cancers. , 2010, International journal of radiation oncology, biology, physics.

[13]  Slav Yartsev,et al.  Adaptive radiotherapy planning on decreasing gross tumor volumes as seen on megavoltage computed tomography images. , 2007, International journal of radiation oncology, biology, physics.

[14]  Thomas E Yankeelov,et al.  Toward a science of tumor forecasting for clinical oncology. , 2015, Cancer research.

[15]  P. Hahnfeldt,et al.  Tumor development under angiogenic signaling: a dynamical theory of tumor growth, treatment response, and postvascular dormancy. , 1999, Cancer research.

[16]  L. Norton,et al.  Growth curve of an experimental solid tumor following radiotherapy. , 1977, Journal of the National Cancer Institute.

[17]  W. Tomé,et al.  Systematic Review of Normal Tissue Complication Models Relevant to Standard Fractionation Radiation Therapy of the Head and Neck Region Published After the QUANTEC Reports. , 2018, International journal of radiation oncology, biology, physics.

[18]  M. Beasley,et al.  Complications of radiotherapy: improving the therapeutic index , 2005, Cancer imaging : the official publication of the International Cancer Imaging Society.

[19]  Kristin R. Swanson,et al.  Toward Patient-Specific, Biologically Optimized Radiation Therapy Plans for the Treatment of Glioblastoma , 2013, PloS one.

[20]  Harald Paganetti,et al.  Prediction of Treatment Response for Combined Chemo- and Radiation Therapy for Non-Small Cell Lung Cancer Patients Using a Bio-Mathematical Model , 2017, Scientific Reports.

[21]  Kujtim Latifi,et al.  A proliferation saturation index to predict radiation response and personalize radiotherapy fractionation , 2015, Radiation Oncology.

[22]  Eduardo G Moros,et al.  The future of personalised radiotherapy for head and neck cancer. , 2017, The Lancet. Oncology.

[23]  J. Fowler The linear-quadratic formula and progress in fractionated radiotherapy. , 1989, The British journal of radiology.

[24]  Philip Gerlee,et al.  The model muddle: in search of tumor growth laws. , 2012, Cancer research.

[25]  John M. L. Ebos,et al.  Classical Mathematical Models for Description and Prediction of Experimental Tumor Growth , 2014, PLoS Comput. Biol..

[26]  Eddie Barendsen,et al.  21 years of Biologically Effective Dose , 2022 .

[27]  N. Mayr,et al.  Assessment of interpatient heterogeneity in tumor radiosensitivity for nonsmall cell lung cancer using tumor-volume variation data. , 2014, Medical physics.

[28]  J. Torres-Roca,et al.  A molecular assay of tumor radiosensitivity: a roadmap towards biology-based personalized radiation therapy. , 2012, Personalized medicine.

[29]  M. Chaplain,et al.  Mathematical modeling of tumor growth and treatment. , 2014, Current pharmaceutical design.

[30]  Rajesh Jena,et al.  Modelling and Bayesian adaptive prediction of individual patients’ tumour volume change during radiotherapy , 2016, Physics in medicine and biology.

[31]  S. F. C. O’Rourke,et al.  Linear quadratic and tumour control probability modelling in external beam radiotherapy , 2009, Journal of mathematical biology.

[32]  F. Harrell,et al.  Evaluating the yield of medical tests. , 1982, JAMA.