Translation of PET radiotracers for cancer imaging: recommendations from the National Cancer Imaging Translational Accelerator (NCITA) consensus meeting
Martina A. McAteer,
Daniel R. McGowan,
Gary J. R. Cook,
Hing Y. Leung,
Tony Ng,
James P. B. O’Connor,
Luigi Aloj,
Anna Barnes,
Phil J. Blower,
Kevin M. Brindle,
John Braun,
Craig Buckley,
Daniel Darian,
Paul Evans,
Vicky Goh,
David Grainger,
Carol Green,
Matt G. Hall,
Thomas A. Harding,
Catherine D. G. Hines,
Simon J. Hollingsworth,
Penny L. Hubbard Cristinacce,
Rowland O. Illing,
Martin Lee,
Baptiste Leurent,
Sue Mallett,
Radhouene Neji,
Natalia Norori,
Nora Pashayan,
Neel Patel,
Kieran Prior,
Thomas Reiner,
Adam Retter,
Alasdair Taylor,
Jasper van der Aart,
Joseph Woollcott,
Wai-Lup Wong,
Jan van der Meulen,
Shonit Punwani,
Geoff S. Higgins
Affiliations
Martina A. McAteer
Department of Oncology, University of Oxford
Daniel R. McGowan
Department of Oncology, University of Oxford
Gary J. R. Cook
School of Biomedical Engineering and Imaging Sciences, King’s College London
Hing Y. Leung
CRUK Scotland Institute
Tony Ng
School of Cancer & Pharmaceutical Sciences, King’s College London
James P. B. O’Connor
Division of Cancer Sciences, University of Manchester
Luigi Aloj
Department of Radiology, University of Cambridge
Anna Barnes
Southeast Region, Office of the Chief Scientific Officer, NHS-England
Phil J. Blower
School of Biomedical Engineering and Imaging Sciences, King’s College London
Kevin M. Brindle
Cancer Research UK Cambridge Institute, University of Cambridge
John Braun
RMH Radiotherapy Focus Group & RMH Biomedical Research Centre Consumer Group
Craig Buckley
Siemens Healthcare Limited
Daniel Darian
Siemens Healthcare Limited
Paul Evans
GE HealthCare, Pharmaceutical Diagnostics
Vicky Goh
School of Biomedical Engineering and Imaging Sciences, King’s College London
David Grainger
Medicines and Healthcare Products Regulatory Agency
Carol Green
Patient and Public Representative
Matt G. Hall
National Physical Laboratory
Thomas A. Harding
Prostate Cancer UK
Catherine D. G. Hines
GSK
Simon J. Hollingsworth
Late Development Oncology, AstraZeneca
Penny L. Hubbard Cristinacce
Division of Cancer Sciences, University of Manchester
Rowland O. Illing
Department of Surgery & Interventional Science, University College London
Martin Lee
Clinical Trial and Statistics Unit, Institute of Cancer Research
Baptiste Leurent
Department of Statistical Science, University College London
Sue Mallett
Centre for Medical Imaging, University College London
Radhouene Neji
School of Biomedical Engineering and Imaging Sciences, King’s College London
Natalia Norori
Prostate Cancer UK
Nora Pashayan
Department of Applied Health Research, University College London
Neel Patel
Department of Radiology, Churchill Hospital, Oxford University NHS Foundation Trust
Kieran Prior
Cancer Research UK
Thomas Reiner
Evergreen Theragnostics
Adam Retter
Centre for Medical Imaging, University College London
Alasdair Taylor
University Hospitals of Morecambe Bay NHS Foundation Trust, Royal Lancaster Infirmary
Jasper van der Aart
GSK Research and Development
Joseph Woollcott
Prostate Cancer UK
Wai-Lup Wong
PET CT Department, Strickland Scanner Centre Mount Vernon Hospital
Jan van der Meulen
Department of Health Services Research & Policy, London School of Hygiene & Tropical Medicine
Shonit Punwani
Centre for Medical Imaging, University College London
Abstract Background The clinical translation of positron emission tomography (PET) radiotracers for cancer management presents complex challenges. We have developed consensus-based recommendations for preclinical and clinical assessment of novel and established radiotracers, applied to image different cancer types, to improve the standardisation of translational methodologies and accelerate clinical implementation. Methods A consensus process was developed using the RAND/UCLA Appropriateness Method (RAM) to gather insights from a multidisciplinary panel of 38 key stakeholders on the appropriateness of preclinical and clinical methodologies and stakeholder engagement for PET radiotracer translation. Panellists independently completed a consensus survey of 57 questions, rating each on a 9-point Likert scale. Subsequently, panellists attended a consensus meeting to discuss survey outcomes and readjust scores independently if desired. Survey items with median scores ≥ 7 were considered ‘required/appropriate’, ≤ 3 ‘not required/inappropriate’, and 4–6 indicated ‘uncertainty remained’. Consensus was determined as ~ 70% participant agreement on whether the item was ‘required/appropriate’ or ‘not required/not appropriate’. Results Consensus was achieved for 38 of 57 (67%) survey questions related to preclinical and clinical methodologies, and stakeholder engagement. For evaluating established radiotracers in new cancer types, in vitro and preclinical studies were considered unnecessary, clinical pharmacokinetic studies were considered appropriate, and clinical dosimetry and biodistribution studies were considered unnecessary, if sufficient previous data existed. There was ‘agreement without consensus’ that clinical repeatability and reproducibility studies are required while ‘uncertainty remained’ regarding the need for comparison studies. For novel radiotracers, in vitro and preclinical studies, such as dosimetry and/or biodistribution studies and tumour histological assessment were considered appropriate, as well as comprehensive clinical validation. Conversely, preclinical reproducibility studies were considered unnecessary and ‘uncertainties remained’ regarding preclinical pharmacokinetic and repeatability evaluation. Other consensus areas included standardisation of clinical study protocols, streamlined regulatory frameworks and patient and public involvement. While a centralised UK clinical imaging research infrastructure and open access federated data repository were considered necessary, there was ‘agreement without consensus’ regarding the requirement for a centralised UK preclinical imaging infrastructure. Conclusions We provide consensus-based recommendations, emphasising streamlined methodologies and regulatory frameworks, together with active stakeholder engagement, for improving PET radiotracer standardisation, reproducibility and clinical implementation in oncology.
