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[18]F-fluoroethyl-L-tyrosine positron emission tomography for radiotherapy target delineation: Results from a Radiation Oncology credentialing program

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posted on 2024-08-20, 00:21 authored by Nathaniel Barry, ES Koh, MA Ebert, A Moore, RJ Francis, P Rowshanfarzad, GM Hassan, Sweet NgSweet Ng, M Back, B Chua, MB Pinkham, A Pullar, C Phillips, J Sia, P Gorayski, H Le, S Gill, J Croker, N Bucknell, C Bettington, F Syed, K Jung, J Chang, A Bece, C Clark, M Wada, O Cook, A Whitehead, A Rossi, A Grose, Andrew ScottAndrew Scott
Background and purpose: The [18]F-fluoroethyl-L-tyrosine (FET) PET in Glioblastoma (FIG) study is an Australian prospective, multi-centre trial evaluating FET PET for newly diagnosed glioblastoma management. The Radiation Oncology credentialing program aimed to assess the feasibility in Radiation Oncologist (RO) derivation of standard-of-care target volumes (TVMR) and hybrid target volumes (TVMR+FET) incorporating pre-defined FET PET biological tumour volumes (BTVs). Materials and methods: Central review and analysis of TVMR and TVMR+FET was undertaken across three benchmarking cases. BTVs were pre-defined by a sole nuclear medicine expert. Intraclass correlation coefficient (ICC) confidence intervals (CIs) evaluated volume agreement. RO contour spatial and boundary agreement were evaluated (Dice similarity coefficient [DSC], Jaccard index [JAC], overlap volume [OV], Hausdorff distance [HD] and mean absolute surface distance [MASD]). Dose plan generation (one case per site) was assessed. Results: Data from 19 ROs across 10 trial sites (54 initial submissions, 8 resubmissions requested, 4 conditional passes) was assessed with an initial pass rate of 77.8 %; all resubmissions passed. TVMR+FET were significantly larger than TVMR (p < 0.001) for all cases. RO gross tumour volume (GTV) agreement was moderate-to-excellent for GTVMR (ICC = 0.910; 95 % CI, 0.708–0.997) and good-to-excellent for GTVMR+FET (ICC = 0.965; 95 % CI, 0.871–0.999). GTVMR+FET showed greater spatial overlap and boundary agreement compared to GTVMR. For the clinical target volume (CTV), CTVMR+FET showed lower average boundary agreement versus CTVMR (MASD: 1.73 mm vs. 1.61 mm, p = 0.042). All sites passed the planning exercise. Conclusions: The credentialing program demonstrated feasibility in successful credentialing of 19 ROs across 10 sites, increasing national expertise in TVMR+FET delineation.

Funding

The FIG study is supported by the Medical Research Future Fund (MRFF) (Grant No. MRF1152501) , MRFF Australian Brain Cancer Mission: Innovative Trials Grant MRF9500003, Cure Brain Cancer Foundation, the Victorian Cancer Agency Centre for Research Excellence in Brain Cancer, Cyclotek and Telix Pharmaceuticals. NB gratefully acknowledges the award of the RTP scholarship from the University of Western Australia. NB is supported by a Cancer Council WA PhD Top Up Scholarship. AMS is supported by NHMRC Investigator Grant No 1177837. Special thanks to Anita and Anthony Parise for their generous contribution to brain cancer research at Sir Charles Gairdner Hospital.

History

Publication Date

2024-04-01

Journal

Physics and Imaging in Radiation Oncology

Volume

30

Article Number

100568

Pagination

8p.

Publisher

Elsevier

ISSN

2405-6316

Rights Statement

© 2024 The Author(s). Published by Elsevier B.V. on behalf of European Society of Radiotherapy & Oncology. This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/).

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