Trans Tasman Radiation Oncology Group: Development of the Assessment of New Radiation Oncology Technology and Treatments (ANROTAT) Framework

Gillian M. Duchesne; Mel Grand; Tomas Kron; Annette Haworth; June Corry; Michael Jackson; Michael Ng; Deidre Besuijen; Hannah E. Carter; Andrew Martin; Deborah Schofield; Val Gebski; Joan Torony; Olga Kovacev; Rowena Amin; Bryan Burmeister

doi:10.1111/1754-9485.12255

Trans Tasman Radiation Oncology Group: Development of the Assessment of New Radiation Oncology Technology and Treatments (ANROTAT) Framework

Gillian M. Duchesne^*, Mel Grand, Tomas Kron, Annette Haworth, June Corry, Michael Jackson, Michael Ng, Deidre Besuijen, Hannah E. Carter, Andrew Martin, Deborah Schofield, Val Gebski, Joan Torony, Olga Kovacev, Rowena Amin, Bryan Burmeister

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

12 Citations (Scopus)

Abstract

Introduction: The study aim was to develop a generic framework to derive the parameters to populate health-economic models for the rapid evaluation of new techniques and technologies in radiation oncology.

Methods: A draft framework was developed through horizon scanning for relevant technologies, literature review to identify framework models, and a workshop program with radiation oncology professionals, biostatisticians, health economists and consumers to establish the Framework's structure. It was tested using four clinical protocols, comparing intensity modulated with 3D conformal therapy (post-prostatectomy, anal canal and nasopharynx) and image-guided radiation therapy techniques with off-line review of portal imaging (in the intact prostate).

Results: The draft generic research framework consisted of five sequential stages, each with a number of components, and was assessed as to its suitability for deriving the evidence needed to populate the decision-analytic models required for the health-economic evaluations. A final Framework was established from this experience for use by future researchers to provide evidence of clinical efficacy and cost-utility for other novel techniques. The four clinical treatment sites tested during the project were considered suitable to use in future evaluations.

Conclusions: Development of a generic research framework to predict early and long-term clinical outcomes, combined with health-economic data, produced a generally applicable method for the rapid evaluation of new techniques and technologies in radiation oncology. Its application to further health technology assessments in the radiation oncology sector will allow further refinement and support its generalisability.

Original language	English
Pages (from-to)	363-370
Number of pages	8
Journal	Journal of Medical Imaging and Radiation Oncology
Volume	59
Issue number	3
DOIs	https://doi.org/10.1111/1754-9485.12255
Publication status	Published - 1 Jun 2015
Externally published	Yes

Keywords

framework
health technology assessment
health-economic evaluation
radiation oncology techniques
radiation oncology technologies

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10.1111/1754-9485.12255

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Duchesne, G. M., Grand, M., Kron, T., Haworth, A., Corry, J., Jackson, M., Ng, M., Besuijen, D., Carter, H. E., Martin, A., Schofield, D., Gebski, V., Torony, J., Kovacev, O., Amin, R., & Burmeister, B. (2015). Trans Tasman Radiation Oncology Group: Development of the Assessment of New Radiation Oncology Technology and Treatments (ANROTAT) Framework. Journal of Medical Imaging and Radiation Oncology, 59(3), 363-370. https://doi.org/10.1111/1754-9485.12255

@article{7490c376d1e240888fc096a476725fb7,

title = "Trans Tasman Radiation Oncology Group: Development of the Assessment of New Radiation Oncology Technology and Treatments (ANROTAT) Framework",

abstract = "Introduction: The study aim was to develop a generic framework to derive the parameters to populate health-economic models for the rapid evaluation of new techniques and technologies in radiation oncology. Methods: A draft framework was developed through horizon scanning for relevant technologies, literature review to identify framework models, and a workshop program with radiation oncology professionals, biostatisticians, health economists and consumers to establish the Framework's structure. It was tested using four clinical protocols, comparing intensity modulated with 3D conformal therapy (post-prostatectomy, anal canal and nasopharynx) and image-guided radiation therapy techniques with off-line review of portal imaging (in the intact prostate). Results: The draft generic research framework consisted of five sequential stages, each with a number of components, and was assessed as to its suitability for deriving the evidence needed to populate the decision-analytic models required for the health-economic evaluations. A final Framework was established from this experience for use by future researchers to provide evidence of clinical efficacy and cost-utility for other novel techniques. The four clinical treatment sites tested during the project were considered suitable to use in future evaluations. Conclusions: Development of a generic research framework to predict early and long-term clinical outcomes, combined with health-economic data, produced a generally applicable method for the rapid evaluation of new techniques and technologies in radiation oncology. Its application to further health technology assessments in the radiation oncology sector will allow further refinement and support its generalisability.",

keywords = "framework, health technology assessment, health-economic evaluation, radiation oncology techniques, radiation oncology technologies",

author = "Duchesne, {Gillian M.} and Mel Grand and Tomas Kron and Annette Haworth and June Corry and Michael Jackson and Michael Ng and Deidre Besuijen and Carter, {Hannah E.} and Andrew Martin and Deborah Schofield and Val Gebski and Joan Torony and Olga Kovacev and Rowena Amin and Bryan Burmeister",

year = "2015",

month = jun,

day = "1",

doi = "10.1111/1754-9485.12255",

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volume = "59",

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journal = "Journal of Medical Imaging and Radiation Oncology",

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Duchesne, GM, Grand, M, Kron, T, Haworth, A, Corry, J, Jackson, M, Ng, M, Besuijen, D, Carter, HE, Martin, A, Schofield, D, Gebski, V, Torony, J, Kovacev, O, Amin, R & Burmeister, B 2015, 'Trans Tasman Radiation Oncology Group: Development of the Assessment of New Radiation Oncology Technology and Treatments (ANROTAT) Framework', Journal of Medical Imaging and Radiation Oncology, vol. 59, no. 3, pp. 363-370. https://doi.org/10.1111/1754-9485.12255

TY - JOUR

T1 - Trans Tasman Radiation Oncology Group

T2 - Development of the Assessment of New Radiation Oncology Technology and Treatments (ANROTAT) Framework

AU - Duchesne, Gillian M.

AU - Grand, Mel

AU - Kron, Tomas

AU - Haworth, Annette

AU - Corry, June

AU - Jackson, Michael

AU - Ng, Michael

AU - Besuijen, Deidre

AU - Carter, Hannah E.

AU - Martin, Andrew

AU - Schofield, Deborah

AU - Gebski, Val

AU - Torony, Joan

AU - Kovacev, Olga

AU - Amin, Rowena

AU - Burmeister, Bryan

PY - 2015/6/1

Y1 - 2015/6/1

N2 - Introduction: The study aim was to develop a generic framework to derive the parameters to populate health-economic models for the rapid evaluation of new techniques and technologies in radiation oncology. Methods: A draft framework was developed through horizon scanning for relevant technologies, literature review to identify framework models, and a workshop program with radiation oncology professionals, biostatisticians, health economists and consumers to establish the Framework's structure. It was tested using four clinical protocols, comparing intensity modulated with 3D conformal therapy (post-prostatectomy, anal canal and nasopharynx) and image-guided radiation therapy techniques with off-line review of portal imaging (in the intact prostate). Results: The draft generic research framework consisted of five sequential stages, each with a number of components, and was assessed as to its suitability for deriving the evidence needed to populate the decision-analytic models required for the health-economic evaluations. A final Framework was established from this experience for use by future researchers to provide evidence of clinical efficacy and cost-utility for other novel techniques. The four clinical treatment sites tested during the project were considered suitable to use in future evaluations. Conclusions: Development of a generic research framework to predict early and long-term clinical outcomes, combined with health-economic data, produced a generally applicable method for the rapid evaluation of new techniques and technologies in radiation oncology. Its application to further health technology assessments in the radiation oncology sector will allow further refinement and support its generalisability.

AB - Introduction: The study aim was to develop a generic framework to derive the parameters to populate health-economic models for the rapid evaluation of new techniques and technologies in radiation oncology. Methods: A draft framework was developed through horizon scanning for relevant technologies, literature review to identify framework models, and a workshop program with radiation oncology professionals, biostatisticians, health economists and consumers to establish the Framework's structure. It was tested using four clinical protocols, comparing intensity modulated with 3D conformal therapy (post-prostatectomy, anal canal and nasopharynx) and image-guided radiation therapy techniques with off-line review of portal imaging (in the intact prostate). Results: The draft generic research framework consisted of five sequential stages, each with a number of components, and was assessed as to its suitability for deriving the evidence needed to populate the decision-analytic models required for the health-economic evaluations. A final Framework was established from this experience for use by future researchers to provide evidence of clinical efficacy and cost-utility for other novel techniques. The four clinical treatment sites tested during the project were considered suitable to use in future evaluations. Conclusions: Development of a generic research framework to predict early and long-term clinical outcomes, combined with health-economic data, produced a generally applicable method for the rapid evaluation of new techniques and technologies in radiation oncology. Its application to further health technology assessments in the radiation oncology sector will allow further refinement and support its generalisability.

KW - framework

KW - health technology assessment

KW - health-economic evaluation

KW - radiation oncology techniques

KW - radiation oncology technologies

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U2 - 10.1111/1754-9485.12255

DO - 10.1111/1754-9485.12255

M3 - Article

C2 - 25345713

AN - SCOPUS:84930476380

SN - 1754-9477

VL - 59

SP - 363

EP - 370

JO - Journal of Medical Imaging and Radiation Oncology

JF - Journal of Medical Imaging and Radiation Oncology

IS - 3

ER -

Trans Tasman Radiation Oncology Group: Development of the Assessment of New Radiation Oncology Technology and Treatments (ANROTAT) Framework

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