Browsing by Author "Hogan, L"
Now showing 1 - 3 of 3
Results Per Page
Sort Options
- ItemCutting edge rare earth radiometals: prospects for cancer theranostics(Springer Nature, 2022-08-26) Sadler, AWE; Hogan, L; Fraser, BH; Rendina, LMWith recent advances in novel approaches to cancer therapy and imaging, the application of theranostic techniques in personalised medicine has emerged as a very promising avenue of research inquiry in recent years. Interest has been directed towards the theranostic potential of Rare Earth radiometals due to their closely related chemical properties which allow for their facile and interchangeable incorporation into identical bifunctional chelators or targeting biomolecules for use in a diverse range of cancer imaging and therapeutic applications without additional modification, i.e. a “one-size-fits-all” approach. This review will focus on recent progress and innovations in the area of Rare Earth radionuclides for theranostic applications by providing a detailed snapshot of their current state of production by means of nuclear reactions, subsequent promising theranostic capabilities in the clinic, as well as a discussion of factors that have impacted upon their progress through the theranostic drug development pipeline. In light of this interest, a great deal of research has also been focussed towards certain under-utilised Rare Earth radionuclides with diverse and favourable decay characteristics which span the broad spectrum of most cancer imaging and therapeutic applications, with potential nuclides suitable for α-therapy (149Tb), β−-therapy (47Sc, 161Tb, 166Ho, 153Sm, 169Er, 149Pm, 143Pr, 170Tm), Auger electron (AE) therapy (161Tb, 135La, 165Er), positron emission tomography (43Sc, 44Sc, 149Tb, 152Tb, 132La, 133La), and single photon emission computed tomography (47Sc, 155Tb, 152Tb, 161Tb, 166Ho, 153Sm, 149Pm, 170Tm). For a number of the aforementioned radionuclides, their progression from ‘bench to bedside’ has been hamstrung by lack of availability due to production and purification methods requiring further optimisation. Conclusions In order to exploit the potential of these radionuclides, reliable and economical production and purification methods that provide the desired radionuclides in high yield and purity are required. With more reactors around the world being decommissioned in future, solutions to radionuclide production issues will likely be found in a greater focus on linear accelerator and cyclotron infrastructure and production methods, as well as mass separation methods. Recent progress towards the optimisation of these and other radionuclide production and purification methods has increased the feasibility of utilising Rare Earth radiometals in both preclinical and clinical settings, thereby placing them at the forefront of radiometals research for cancer theranostics. © 2022 The Author(s) . Open Access under a Creative Commons Attribution 4.0 International License.
- ItemSP-103 - Scandium-47 and lutetium-177 radiolabelling and stability studies of 1st and 2nd generation DOTA-triphenylphosphonium ligands – potential radionuclide theranostics for treatment of glioblastoma multi-forme(Elsevier, 2021-05-17) Wyatt, NA; Hogan, L; Pellegrini, PA; Roberts, MP; Hall, A; Smith, N; Hemzal, E; Hill, L; Howell, NR; Middleton, RJ; Safavi-Naeini, M; Rendina, LM; Fraser, BHScandium-47 has emerged as a promising radioisotope for targeted radionuclide tumor therapy. This is due, to a significant extent, from the combination of low energy / short range β- emission, the availability of a “perfect theranostic pair” with Sc-44 for companion PET imaging, the potential to form highly stable radiometal complexes, and the availability of suitable γ emissions for companion SPECT imaging. Sc-47 also has a shorter half-life (3.35 d) than the chemically similar Lu-177 (6.7 d) which is significant given recent in vitro research that suggests longer lived isotopes require more initial radioactivity to have the same effect upon cell viability [3]. The shorter half-life of Sc-47 also suggests it may be more suitable for smaller biological vectors (with shorter biological half-lives) such as small molecules and low MW peptides. One area of clinical treatment where Sc-47 can have impact and where improvements in patient outcomes and survival rates remain stubbornly low is glioblastoma multiforme (GBM). GBM is the most common and aggressive form of malignant brain tumor and represents around 60% of all adult brain tumors with a global incidence of <10 per 100,000 persons. The prognosis for GBM patients is poor with a -ear survival rate of 37%, 5 year rate of 5% and a median survival time of 10 months. The current standard of treatment is resection of the tumor followed by radiation therapy and chemotherapy. Given this poor prognosis there is a clear and unmet need for improved classes of treatment. Although significant progress has been made towards bringing GBM targeted radionuclide therapies to the clinic, the efforts to date have not included utilizing Sc-44/ Sc-47. Given this we are developing and evaluating Sc-44/Sc-47 and Lu-177/Ga-68 radiolabelled triphenylphosphonium (TPP) functionalised DOTA ligands (1st and 2nd generation) as potential theranostics for GBM. Described herein is our work on comparing the radiolabelling efficiency (Sc-47 vs. Lu-177) and stability studies (PBS pH 7.4, rat plasma) for our 1st and 2nd generation DOTA-TPP ligands. The presence of an additional carbonyl group in the 2nd generation DOTATPP ligand was anticipated to increase the number of donor atoms around the radiometal and affect radiolabelling reaction conditions and, more importantly, increase radiometal complex stability. Copyright © 2021 Elsevier Inc.
- ItemSynthesis and in vivo evaluation of [123I]melanin-targeted agents(American Chemical Society, 2015-08-15) Roberts, MP; Nguyen, VH; Ashford, ME; Berghofer, PJ; Wyatt, NA; Krause-Heuer, AM; Pham, TQ; Taylor, SR; Hogan, L; Jiang, CD; Fraser, BH; Lengkeek, NA; Matesic, L; Grégoire, MC; Denoyer, D; Hicks, RJ; Katsifis, A; Greguric, IThis study reports the synthesis, [123I]radiolabeling, and biological profile of a new series of iodinated compounds for potential translation to the corresponding [131I]radiolabeled compounds for radionuclide therapy of melanoma. Radiolabeling was achieved via standard electrophilic iododestannylation in 60–90% radiochemical yield. Preliminary SPECT imaging demonstrated high and distinct tumor uptake of all compounds, as well as high tumor-to-background ratios compared to the literature compound [123I]4 (ICF01012). The most favorable compounds ([123I]20, [123I]23, [123I]41, and [123I]53) were selected for further biological investigation. Biodistribution studies indicated that all four compounds bound to melanin containing tissue with low in vivo deiodination; [123I]20 and [123I]53 in particular displayed high and prolonged tumor uptake (13% ID/g at 48 h). [123I]53 had the most favorable overall profile of the cumulative uptake over time of radiosensitive organs. Metabolite analysis of the four radiotracers found [123I]41 and [123I]53 to be the most favorable, displaying high and prolonged amounts of intact tracer in melanin containing tissues, suggesting melanin specific binding. Results herein suggest that compound [123I]53 displays favorable in vivo pharmacokinetics and stability and hence is an ideal candidate to proceed with further preclinical [131I] therapeutic evaluation. ©2015, American Chemical Society