Small-scale dosimetry for alpha particle 241Am source cell irradiation and estimation of γ-H2AX foci distribution in prostate cancer cell line PC3

Emma Mellhammar; Magnus Dahlbom; Oskar Vilhelmsson-Timmermand; Sven-Erik Strand

doi:10.1186/s40658-022-00475-x

Small-scale dosimetry for alpha particle ²⁴¹Am source cell irradiation and estimation of γ-H2AX foci distribution in prostate cancer cell line PC3

EJNMMI Phys. 2022 Jul 19;9(1):46. doi: 10.1186/s40658-022-00475-x.

Authors

Emma Mellhammar¹, Magnus Dahlbom², Oskar Vilhelmsson-Timmermand^{3

4}, Sven-Erik Strand⁵

Affiliations

¹ Department of Clinical Sciences Lund, Oncology, Lund University, Barngatan 4, 221 85, Lund, Sweden. emma.mellhammar@med.lu.se.
² Department of Molecular and Medical Pharmacology, David Geffen School of Medicine at UCLA, Los Angeles, CA, USA.
³ Department of Clinical Sciences Lund, Oncology, Lund University, Barngatan 4, 221 85, Lund, Sweden.
⁴ Imaging Chemistry and Biology, Kings Collage London, London, UK.
⁵ Department of Clinical Sciences Lund, Medical Radiation Physics, Lund University, Lund, Sweden.

Abstract

Background: The development of new targeted alpha therapies motivates improving alpha particle dosimetry. For alpha particles, microscopic targets must be considered to estimate dosimetric quantities that can predict the biological response. As double-strand breaks (DSB) on DNA are the main cause of cell death by ionizing radiation, cell nuclei are relevant volumes necessary to consider as targets. Since a large variance is expected of alpha particle hits in individual cell nuclei irradiated by an uncollimated alpha-emitting source, the damage induced should have a similar distribution. The induction of DSB can be measured by immunofluorescent γ-H2AX staining. The cell γ-H2AX foci distribution and alpha particle hits distribution should be comparable and thereby verify the necessity to consider the relevant dosimetric volumes.

Methods: A Monte Carlo simulation model of an ²⁴¹Am source alpha particle irradiation setup was combined with two versions of realistic cell nuclei phantoms. These were generated from DAPI-stained PC3 cells imaged with fluorescent microscopy, one consisting of elliptical cylinders and the other of segmented mesh volumes. PC3 cells were irradiated with the ²⁴¹Am source for 4, 8 and 12 min, and after 30 min fixated and stained with immunofluorescent γ-H2AX marker. The detected radiation-induced foci (RIF) were compared to simulated RIF.

Results: The mesh volume phantom detected a higher mean of alpha particle hits and energy imparted (MeV) per cell nuclei than the elliptical cylinder phantom, but the mean specific energy (Gy) was very similar. The mesh volume phantom detected a slightly larger variance between individual cells, stemming from the more extreme and less continuous distribution of cell nuclei sizes represented in this phantom. The simulated RIF distribution from both phantoms was in good agreement with the detected RIF, although the detected distribution had a zero-inflated shape not seen in the simulated distributions. An estimate of undetected foci was used to correct the detected RIF distribution and improved the agreement with the simulations.

Conclusion: Two methods to generate cell nuclei phantoms for Monte Carlo dosimetry simulations were tested and generated similar results. The simulated and detected RIF distributions from alpha particle-irradiated PC3 cells were in good agreement, proposing the necessity to consider microscopic targets in alpha particle dosimetry.

Keywords: Alpha particles; Monte Carlo simulation; PC3; Small-scale dosimetry; γ-H2AX.

Abstract

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