TY - JOUR
T1 - Combining hypoxia-activated prodrugs and radiotherapy in silico
T2 - impact of treatment scheduling and the intra-tumoural oxygen landscape
AU - Hamis, Sara
AU - Kohandel, Mohammad
AU - Dubois, Ludwig J.
AU - Yaromina, Ala
AU - Lambin, Philippe
AU - Powathil, Gibin G.
N1 - SH was supported by the Medical Research Council [grant code MR/R017506/1] and Swansea University PhD Research Studentship. URLs: https://mrc.ukri.org/ and https://www.swansea.ac.uk/ MK acknowledges the financial support from the Canadian Institutes of Health Research (CIHR). URL: https://cihr-irsc.gc.ca LJD, AY and PL acknowledge financial support from European Research Council (ERC) advanced grant (ERC-ADG-2015, n 694812 – Hypoximmuno) and EUROSTARS (COMPACT 12053). URLs: https://erc.europa.eu/ and https://www.eurostars-eureka.eu The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
PY - 2020/8/3
Y1 - 2020/8/3
N2 - Hypoxia-activated prodrugs (HAPs) present a conceptually elegant
approach to not only overcome, but better yet, exploit intra-tumoural
hypoxia. Despite being successful in vitro and in vivo,
HAPs are yet to achieve successful results in clinical settings. It has
been hypothesised that this lack of clinical success can, in part, be
explained by the insufficiently stringent clinical screening selection
of determining which tumours are suitable for HAP treatments. Taking a
mathematical modelling approach, we investigate how tumour properties
and HAP-radiation scheduling influence treatment outcomes in simulated
tumours. The following key results are demonstrated in silico: (i) HAP and ionising radiation (IR) monotherapies may attack tumours in dissimilar, and complementary, ways. (ii) HAP-IR scheduling may impact treatment efficacy. (iii) HAPs may function as IR treatment intensifiers. (iv) The spatio-temporal intra-tumoural oxygen landscape may impact HAP efficacy. Our in silico
framework is based on an on-lattice, hybrid, multiscale cellular
automaton spanning three spatial dimensions. The mathematical model for
tumour spheroid growth is parameterised by multicellular tumour spheroid
(MCTS) data.
AB - Hypoxia-activated prodrugs (HAPs) present a conceptually elegant
approach to not only overcome, but better yet, exploit intra-tumoural
hypoxia. Despite being successful in vitro and in vivo,
HAPs are yet to achieve successful results in clinical settings. It has
been hypothesised that this lack of clinical success can, in part, be
explained by the insufficiently stringent clinical screening selection
of determining which tumours are suitable for HAP treatments. Taking a
mathematical modelling approach, we investigate how tumour properties
and HAP-radiation scheduling influence treatment outcomes in simulated
tumours. The following key results are demonstrated in silico: (i) HAP and ionising radiation (IR) monotherapies may attack tumours in dissimilar, and complementary, ways. (ii) HAP-IR scheduling may impact treatment efficacy. (iii) HAPs may function as IR treatment intensifiers. (iv) The spatio-temporal intra-tumoural oxygen landscape may impact HAP efficacy. Our in silico
framework is based on an on-lattice, hybrid, multiscale cellular
automaton spanning three spatial dimensions. The mathematical model for
tumour spheroid growth is parameterised by multicellular tumour spheroid
(MCTS) data.
U2 - 10.1371/journal.pcbi.1008041
DO - 10.1371/journal.pcbi.1008041
M3 - Article
SN - 1553-734X
VL - 16
JO - PLoS Computational Biology
JF - PLoS Computational Biology
IS - 8
M1 - e1008041
ER -