Spatial Metrics of Tumour Vascular Organisation Predict Radiation Efficacy in a Computational Model: e1004712

Intratumoural heterogeneity is known to contribute to poor therapeutic response. Variations in oxygen tension in particular have been correlated with changes in radiation response in vitro and at the clinical scale with overall survival. Heterogeneity at the microscopic scale in tumour blood vessel...

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Veröffentlicht in:	PLoS computational biology 2016-01, Vol.12 (1)
Hauptverfasser:	Scott, Jacob G, Fletcher, Alexander G, Anderson, Alexander RA, Maini, Philip K
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Schlagworte:	Experiments Funding Hypotheses Hypoxia Mathematical models NMR Nuclear magnetic resonance Partial differential equations Patients Radiation therapy Software Studies Tumors
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creator	Scott, Jacob G Fletcher, Alexander G Anderson, Alexander RA Maini, Philip K
description	Intratumoural heterogeneity is known to contribute to poor therapeutic response. Variations in oxygen tension in particular have been correlated with changes in radiation response in vitro and at the clinical scale with overall survival. Heterogeneity at the microscopic scale in tumour blood vessel architecture has been described, and is one source of the underlying variations in oxygen tension. We seek to determine whether histologic scale measures of the erratic distribution of blood vessels within a tumour can be used to predict differing radiation response. Using a two-dimensional hybrid cellular automaton model of tumour growth, we evaluate the effect of vessel distribution on cell survival outcomes of simulated radiation therapy. Using the standard equations for the oxygen enhancement ratio for cell survival probability under differing oxygen tensions, we calculate average radiation effect over a range of different vessel densities and organisations. We go on to quantify the vessel distribution heterogeneity and measure spatial organization using Ripley's L function, a measure designed to detect deviations from complete spatial randomness. We find that under differing regimes of vessel density the correlation coefficient between the measure of spatial organization and radiation effect changes sign. This provides not only a useful way to understand the differences seen in radiation effect for tissues based on vessel architecture, but also an alternate explanation for the vessel normalization hypothesis.
doi_str_mv	10.1371/journal.pcbi.1004712
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subjects	Experiments Funding Hypotheses Hypoxia Mathematical models NMR Nuclear magnetic resonance Partial differential equations Patients Radiation therapy Software Studies Tumors
title	Spatial Metrics of Tumour Vascular Organisation Predict Radiation Efficacy in a Computational Model: e1004712
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