Your search keyword '"Brüningk, Sarah"' showing total 2 results

1. A Century of Fractionated Radiotherapy: How Mathematical Oncology Can Break the Rules.

Author

Ghaderi, Nima, Jung, Joseph, Brüningk, Sarah C., Subramanian, Ajay, Nassour, Lauren, and Peacock, Jeffrey

Subjects

RADIOTHERAPY, ONCOLOGY, RADIATION doses, CANCER treatment, FRACTIONS

Abstract

Radiotherapy is involved in 50% of all cancer treatments and 40% of cancer cures. Most of these treatments are delivered in fractions of equal doses of radiation (Fractional Equivalent Dosing (FED)) in days to weeks. This treatment paradigm has remained unchanged in the past century and does not account for the development of radioresistance during treatment. Even if under-optimized, deviating from a century of successful therapy delivered in FED can be difficult. One way of exploring the infinite space of fraction size and scheduling to identify optimal fractionation schedules is through mathematical oncology simulations that allow for in silico evaluation. This review article explores the evidence that current fractionation promotes the development of radioresistance, summarizes mathematical solutions to account for radioresistance, both in the curative and non-curative setting, and reviews current clinical data investigating non-FED fractionated radiotherapy. [ABSTRACT FROM AUTHOR]

Published

2022

2. Quantification of Differential Response of Tumour and Normal Cells to Microbeam Radiation in the Absence of FLASH Effects.

Author

Steel, Harriet, Brüningk, Sarah C., Box, Carol, Oelfke, Uwe, and Bartzsch, Stefan H.

Subjects

*IN vitro studies, *DOSE-response relationship (Radiation), *CELL survival, *CELL lines, *RADIOTHERAPY

Abstract

Simple Summary: This study compares the capabilities of normal and tumour cells to divide after receiving spatially fractionated radiotherapy. For this treatment, a minority of cells (here ∼20%) receive very large, peak doses, whereas the remaining cells are spared and receive only a small valley dose. We show that tumour and normal cells respond differently to this treatment, and that spatially fractionated radiotherapy may have a greater effect on tumour than normal cells. Our work was conducted using laboratory equipment, rather than specialized synchrotron facilities implying that the observed response is present at conventional dose rates and hence purely an effect of the spatial fractionation of the treatment. Microbeam radiotherapy (MRT) is a preclinical method of delivering spatially-fractionated radiotherapy aiming to improve the therapeutic window between normal tissue complication and tumour control. Previously, MRT was limited to ultra-high dose rate synchrotron facilities. The aim of this study was to investigate in vitro effects of MRT on tumour and normal cells at conventional dose rates produced by a bench-top X-ray source. Two normal and two tumour cell lines were exposed to homogeneous broad beam (BB) radiation, MRT, or were separately irradiated with peak or valley doses before being mixed. Clonogenic survival was assessed and compared to BB-estimated surviving fractions calculated by the linear-quadratic (LQ)-model. All cell lines showed similar BB sensitivity. BB LQ-model predictions exceeded the survival of cell lines following MRT or mixed beam irradiation. This effect was stronger in tumour compared to normal cell lines. Dose mixing experiments could reproduce MRT survival. We observed a differential response of tumour and normal cells to spatially fractionated irradiations in vitro, indicating increased tumour cell sensitivity. Importantly, this was observed at dose rates precluding the presence of FLASH effects. The LQ-model did not predict cell survival when the cell population received split irradiation doses, indicating that factors other than local dose influenced survival after irradiation. [ABSTRACT FROM AUTHOR]

Published

2021