BACKGROUND AND PURPOSE: The addition of gold nanoparticles (GNPs) to tumours leads to an increase in dose due to their high density and energy absorption coefficient, making it a potential radiosensitiser. However, experiments have observed radiosensitisations significantly larger than the increase in dose alone, including at megavoltage energies where gold's relative energy absorption is lowest. This work investigates whether GNPs create dose inhomogeneities on a sub-cellular scale which combine with non-linear dose dependence of cell survival to be the source of radiosensitisation at megavoltage energies. MATERIALS AND METHODS: Monte Carlo simulations were carried out to calculate dose in the vicinity of a single GNP on the nanoscale. The effect of this nanoscale dose distribution was then modelled for MDA-MB-231 cells exposed to 2 nm GNPs, and compared to experimental results. RESULTS: Dramatic dose inhomogeneities occur around GNPs exposed to megavoltage radiation. When analysed using the Local Effect Model, these inhomogeneities lead to significant radiosensitisation, in agreement with experimental results. CONCLUSIONS: This work suggests that GNP radiosensitisation is driven by inhomogeneities in dose on the nanoscale, rather than changes in dose over the entire cell, which may contribute to the similar radiosensitisation observed in megavoltage and kilovoltage experiments. The short range of these inhomogeneities and the variation in enhancement in different cells suggests sub-cellular localisation is important in determining GNP radiosensitisation.
BACKGROUND AND PURPOSE: The addition of gold nanoparticles (GNPs) to tumours leads to an increase in dose due to their high density and energy absorption coefficient, making it a potential radiosensitiser. However, experiments have observed radiosensitisations significantly larger than the increase in dose alone, including at megavoltage energies where gold's relative energy absorption is lowest. This work investigates whether GNPs create dose inhomogeneities on a sub-cellular scale which combine with non-linear dose dependence of cell survival to be the source of radiosensitisation at megavoltage energies. MATERIALS AND METHODS: Monte Carlo simulations were carried out to calculate dose in the vicinity of a single GNP on the nanoscale. The effect of this nanoscale dose distribution was then modelled for MDA-MB-231 cells exposed to 2 nm GNPs, and compared to experimental results. RESULTS: Dramatic dose inhomogeneities occur around GNPs exposed to megavoltage radiation. When analysed using the Local Effect Model, these inhomogeneities lead to significant radiosensitisation, in agreement with experimental results. CONCLUSIONS: This work suggests that GNP radiosensitisation is driven by inhomogeneities in dose on the nanoscale, rather than changes in dose over the entire cell, which may contribute to the similar radiosensitisation observed in megavoltage and kilovoltage experiments. The short range of these inhomogeneities and the variation in enhancement in different cells suggests sub-cellular localisation is important in determining GNP radiosensitisation.
Authors: A L McNamara; W W Y Kam; N Scales; S J McMahon; J W Bennett; H L Byrne; J Schuemann; H Paganetti; R Banati; Z Kuncic Journal: Phys Med Biol Date: 2016-07-20 Impact factor: 3.609
Authors: Ross I Berbeco; Houari Korideck; Wilfred Ngwa; Rajiv Kumar; Janki Patel; Srinivas Sridhar; Sarah Johnson; Brendan D Price; Alec Kimmelman; G Mike Makrigiorgos Journal: Radiat Res Date: 2012-11-13 Impact factor: 2.841
Authors: Casey McQuade; Ajlan Al Zaki; Yaanik Desai; Michael Vido; Timothy Sakhuja; Zhiliang Cheng; Robert J Hickey; Daniel Joh; So-Jung Park; Gary Kao; Jay F Dorsey; Andrew Tsourkas Journal: Small Date: 2014-09-29 Impact factor: 13.281
Authors: James F Hainfeld; Henry M Smilowitz; Michael J O'Connor; Farrokh Avraham Dilmanian; Daniel N Slatkin Journal: Nanomedicine (Lond) Date: 2012-12-24 Impact factor: 5.307