Optimization of Radiation Therapy Fractionation Schedules in the Presence of Tumor Repopulation

Author(s)

Bortfeld, Thomas; Ramakrishnan, Jagdish; Unkelbach, Jan; Tsitsiklis, John N

Abstract

We analyze the effect of tumor repopulation on optimal dose delivery in radiation therapy. We are primarily motivated by accelerated tumor repopulation toward the end of radiation treatment, which is believed to play a role in treatment failure for some tumor sites. A dynamic programming framework is developed to determine an optimal fractionation scheme based on a model of cell kill from radiation and tumor growth in between treatment days. We find that faster tumor growth suggests shorter overall treatment duration. In addition, the presence of accelerated repopulation suggests larger dose fractions later in the treatment to compensate for the increased tumor proliferation. We prove that the optimal dose fractions are increasing over time. Numerical simulations indicate a potential for improvement in treatment effectiveness.

Date issued

2015-12

URI

http://hdl.handle.net/1721.1/111066

Department

Massachusetts Institute of Technology. Laboratory for Information and Decision Systems

Journal

INFORMS Journal on Computing

Publisher

Institute for Operations Research and the Management Sciences (INFORMS)

Citation

Bortfeld, Thomas et al. “Optimization of Radiation Therapy Fractionation Schedules in the Presence of Tumor Repopulation.” INFORMS Journal on Computing 27, 4 (November 2015): 788–803 © 2015 Institute for Operations Research and the Management Sciences (INFORMS)

Version: Original manuscript

ISSN

1091-9856

1526-5528