Heterogeneity in Tumor Microvascular Response to Radiation

Overview

Journal Int J Radiat Oncol Biol Phys

Specialties Oncology
Radiology

Date 1990 Mar 1

PMID 2318688

Citations 16

Authors

M W Dewhirst

R Oliver

C Y Tso

C Gustafson

T Secomb

J F Gross

Affiliations

Soon will be listed here.

Abstract

Viable hypoxic cells have reduced radiosensitivity and could be a potential cause for treatment failure with radiotherapy. The process of reoxygenation, which may occur after radiation exposure, could increase the probability for control. However, incomplete or insufficient reoxygenation may still be a potential cause for local treatment failure. One mechanism that has been thought to be responsible for reoxygenation is an increase in vascular prominence after radiation. However, the effect is known to be heterogeneous. In this study, tumor microvascular hemodynamics and morphologies were studied using the R3230 Ac mammary adenocarcinoma transplanted in a dorsal flap window chamber of the Fischer-344 rat. Measurements were made before and after (at 24 and 72 hr) 5-Gy radiation exposure to assess microvascular changes and to explore possible explanations for the heterogeneity of the effect. There was considerable heterogeneity between tumors prior to radiation. Vascular densities ranged from 67 to 3000 vessels/mm3 and median vessel diameters from 22 to 85 microns. Pretreatment perfusion values varied by a factor of six. In irradiated tumors, conjoint increases in both vascular density and perfusion occurred in most tumors, although the degree of change was variable from one individual to the next. The degree of change in density was inversely related to median pretreatment diameter. Relative change in flow, as predicted by morphometric measurements, overestimated observed changes in flow measured hemodynamically. These results support that heterogeneity in tumor vascular effects from radiation are somewhat dependent on pretreatment morphology as well as relative change in morphology. Since changes in flow could not be completely explained by morphometric measurements, however, it is likely that radiation induced changes in pressure and/or viscosity contribute to the overall effect. Further work in this laboratory will investigate these hypotheses.

Citing Articles

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PMID: 37870204 PMC: 10700240. DOI: 10.1002/advs.202304886.

Endothelial cell death after ionizing radiation does not impair vascular structure in mouse tumor models.

Kaeppler J, Chen J, Buono M, Vermeer J, Kannan P, Cheng W EMBO Rep. 2022; 23(9):e53221.

PMID: 35848459 PMC: 9442312. DOI: 10.15252/embr.202153221.

Quantitative diffuse reflectance spectroscopy of short-term changes in tumor oxygenation after radiation in a matched model of radiation resistance.

Diaz P, Jenkins S, Alhallak K, Semeniak D, Griffin R, Dings R Biomed Opt Express. 2018; 9(8):3794-3804.

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Application of a Novel Murine Ear Vein Model to Evaluate the Effects of a Vascular Radioprotectant on Radiation-Induced Vascular Permeability and Leukocyte Adhesion.

Ashcraft K, Roy Choudhury K, Birer S, Hendargo H, Patel P, Eichenbaum G Radiat Res. 2018; 190(1):12-21.

PMID: 29671690 PMC: 6488037. DOI: 10.1667/RR14896.1.

The Impact of Radiation on the Tumor Microenvironment: Effect of Dose and Fractionation Schedules.

Arnold K, Flynn N, Raben A, Romak L, Yu Y, Dicker A Cancer Growth Metastasis. 2018; 11:1179064418761639.

PMID: 29551910 PMC: 5846913. DOI: 10.1177/1179064418761639.