Targeted alpha-therapy:cell survival determination in melanoma tumours using Monte Carlo calculations.

Pashaeinejad, Masoumeh, Physics, Faculty of Science, UNSW

January 2006

This study investigates the Monte Carlo calculations of cell survival in metastatic subcutaneous melanoma cancer tumours. To achieve this goal, a Monte Carlo program called SLAB.FOR was developed by Prof. David Charlton. The program randomly places alphas from 213Bi in the medium, which is a cancer cell sized micro dosimeter with a SiO2 converter on the top and Si as the sensitive volume. Then the Monte Carlo program calculates the energy deposited by alphas and their chord length and also the dose deposited in the sensitive volume. To be able to use this program, some information was taken from phase one of a clinical trial conducted by the Centre of Experimental Radiation Oncology (CERO) in 2001. During the course of this study the administered activities on tumours with different diameters are determined. Using this information the number of alpha particles going through each m3 of the tumour was found. Based on this number, the program SLAB.FOR was run for different administered activities in the tumours. The output of the program yielded the energy deposited and the number of hits by the alpha particles as they go through the tumours. The output data was also used to calculate the cell survival values, energy and hit distribution probabilities. The cell survival values were then used to plot the cell survival curves. They were plotted against dose, number of hits and injected activity per volume of the tumours. These data were also used to plot the energy and hit distribution probability curves. Our results show that survival is dependent on the diameter of the cell and decreases when the dose deposited in the tumour increases. The survival also has a relationship with the number of hits that a cell receives and it also depends on the injected activity to the volume. The survival decreases as the number of hits and injected activity increases. Our results confirmed what was stated in the clinical trial conducted by the Centre of Experimental Radiation Oncology (CERO) in 2001.

Radiationtherapy

targeted alpha therapy

Microfluidics-Based Separation of Actinium-225 From Radium-225 for Medical Applications

Davern, Sandra, O’Neil, David, Hallikainen, Hannah, O’Neil, Kathleen, Allman, Steve, Millet, Larry, Retterer, Scott, Doktycz, Mitchel, Standaert, Robert, Boll, Rose, Van Cleve, Shelley, DePaoli, David, Mirzadeh, Saed

13 August 2019

Separation of 225Ra (t1/2 = 15 d) from its daughter isotope 225Ac (t1/2 = 10 d) is necessary to obtain pure 225Ac for cancer alpha-therapy. In this study, microscale separation of 225Ra from its daughter 225Ac using BioRad AG50X4 cation exchange resin was achieved with good reproducibility across microdevices, and ≥90% purity was achieved for 225Ac, which is comparable to conventional chromatography. These results indicate the potential for greater use of microfluidics for biomedical radiochemistry. The modularity of the system and its compatibility with different resins allows for quick and easy adaptation to the various needs of a separation campaign.

actinium-225

ion chromatography

microfluidics

radium-225

targeted-alpha-therapy

Chemistry

LANTHANIDE-BASED CORE-SHELL NANOPARTICLES AS MULTIFUNCTIONAL PLATFORMS FOR TARGETED RADIONUCLIDE THERAPY AND MULTIMODAL MOLECULAR IMAGING

Toro-Gonzalez, Miguel

01 January 2018

Lanthanide phosphate (LnPO4) and lanthanide vanadate (LnVO4) nanoparticles (NPs) are promising platforms for theranostic applications because of their chemical stability, low solubility, low toxicity, and unique luminescence and magnetic properties. Motivated by the high radiation resistance and ability to host actinides of naturally occurring lanthanide-based compounds, LnPO4 and LnVO4 NPs were studied as radionuclide carriers for targeted radionuclide therapy using in vivoα-generators, 223Ra, 225Ac, and 227Th. The implementation of these radionuclides has shown potential for the treatment of micrometastases and solid tumors as well as challenges in the retention of decay daughters at the target site to minimize unwanted radiotoxicity. LnPO4 and LnVO4 core-shell NPs doped with either 156Eu, a “cocktail” of 85, 89Sr and 156Eu, or in vivo α-generators 223Ra, 225Ac, and 227Th were synthesized in aqueous media. In vitro retention of radionuclides was investigated by dialyzing the radionuclide-doped NPs suspensions against deionized water and quantifying the activity in dialysate aliquots over time. The crystal structure, morphology, physical stability, luminescence and magnetic properties were evaluated. Partial retention of 156Eu (~70–95%) and 85, 89Sr (>80%) was evidenced in LnPO4 core NPs, while 227Th and decay daughters were quantitatively retained in LaPO4 core + 2 shells NPs (>99%). Gd0.8Eu0.2VO4 and GdVO4 core-shell NPs showed partial retention of 223Ra (~75%), 225Ac (75–95%), 227Th (>96%), and decay daughters. Radionuclide retention was influenced by the lanthanide concentration, crystal structure, and number of shells. The partial retention of radionuclides in both LnPO4 and LnVO4 core-shell NPs may enhance the treatment efficacy while minimizing unwanted toxicity. LnVO4 core and core-shell NPs have potential as carriers of short-lived radionuclides for both diagnostic and therapeutic applications. Emission intensities were higher for LnVO4 with respect to LnPO4 NPs, whereas no significant difference was observed in the magnetic susceptibilities. GdVO4 core NPs displayed enhancement of the signal intensity in T1-weighted images. This work evidences the promising application of both LnPO4 and LnVO4 NPs as platforms for targeted radionuclide therapy and multimodal molecular imaging.

lanthanide phosphate

lanthanide vanadate

multifunctional nanoparticles

targeted alpha therapy

radionuclides

in vivo α-generators

Nanoscience and Nanotechnology

Nuclear Engineering

New technologies for At-211 targeted alpha-therapy research using Rn-211 and At-209

Crawford, Jason Raymond

30 August 2016

The most promising applications for targeted alpha-therapy with astatine-211 (At-211) include treatments of disseminated microscopic disease, the major medical problem for cancer treatment. The primary advantages of targeted alpha-therapy with At-211 are that the alpha-particle radiation is densely ionizing, translating to high relative biological effectiveness (RBE), and short-range, minimizing damage to surrounding healthy tissues. In addition, theranostic imaging with I-123 surrogates has shown promise for developing new therapies with At-211 and translating them to the clinic. Currently, Canada does not have a way of producing At-211 by conventional methods because it lacks alpha-particle accelerators with necessary beam energy and intensity. The work presented here was aimed at studying the Rn-211/At-211 generator system as an alternative production strategy by leveraging TRIUMF's ability to produce rare isotopes. Recognizing that TRIUMF provided production opportunities for a variety of astatine isotopes, this work also originally hypothesized and evaluated the use of At-209 as a novel isotope for preclinical Single Photon Emission Computed Tomography (SPECT) with applications to At-211 therapy research. At TRIUMF's Isotope Separator and Accelerator (ISAC) facility, mass separated ion beams of short­-lived francium isotopes were implanted into NaCl targets where Rn-211 or At-209 were produced by radioactive decay, in situ. This effort required methodological developments for safely relocating the implanted radioactivity to the radiochemistry laboratory for recovery in solution. For multiple production runs, Rn-211 was quantitatively transferred from solid NaCl to solution (dodecane) from which At-211 was efficiently extracted and evaluated for clinical applicability. This validated the use of dodecane for capturing Rn-211 as an elegant approach to storing and shipping Rn-211/At-211 in the future. Po-207 contamination (also produced by Rn-211 decay) was removed using a granular tellurium (Te) column before proceeding with biomolecule labelling. Although the produced quantities were small, the pure At-211 samples demonstrated these efforts to have a clear path of translation to animal studies. For the first time in history, SPECT/CT was evaluated for measuring At-209 radioactivity distributions using high energy collimation. The spectrum detected for At-209 by the SPECT camera presented several photopeaks (energy windows) for reconstruction. The 77-90 Po X­-ray photopeak reconstructions were found to provide the best images overall, in terms of resolution/contrast and uniformity. Collectively, these experiments helped establish guidelines for determining the optimal injected radioactivity, depending on scan parameters. Moreover, At-209-based SPECT demonstrated potential for pursuing image-­based dosimetry in mouse tumour models, in the future. Simultaneous SPECT imaging with At-209 and I-123 was demonstrated to be feasible, supporting the future evaluation of At-209 for studying/validating I-123 surrogates for clinical image-based At-211 dosimetry. This work also pursued a novel strategy for labelling cancer targeting peptides with At-211, using octreotate (TATE, a somatostatin analogue for targeting tumour cells, mostly neuroendocrine tumours) prepared with or without N-terminus PEGylation (PEG2), followed by conjugation with a closo-decaborate linking moiety (B10) for attaching At-211. Binding affinity and in vivo biodistributions for the modified peptides were determined using iodine surrogates. The results indicated that B10-PEG2-TATE retained target binding affinity but that the labelling reaction with iodine degraded this binding affinity significantly, and although having high in vivo stability, no I-123-B10-PEG2-TATE tumour uptake was observed by SPECT in a mouse tumour model positive for the somatostatin receptor (sstr2a). This suggested that further improvements are required for labelling. A new method for producing At-211 at TRIUMF is established, and At-209-­based SPECT imaging is now demonstrated as a new preclinical technology to measure astatine biodistributions in vivo for developing new radiopharmaceuticals with At-211. Combined with the theranostic peptide labelling efforts with iodine, these efforts provide a foundation for future endeavours with At-211-­based alpha-therapy at TRIUMF. All procedures were performed safely and rapidly, suitable for preclinical evaluations. All animal studies received institutional ethics approval from the University of British Columbia (UBC). / Graduate

Astatine-211

Astatine-209

Radon-211

Radiotherapy

nuclear medicine

theranostics

SPECT

tumour

medical imaging

medical isotope production

internal radionuclide therapy

targeted alpha therapy

ion beam implantation

spallation

alpha-decay