Optimal design and patient selection for interventional trials using radiogenomic biomarkers: A REQUITE and Radiogenomics consortium statement

Dirk De Ruysscher; Gilles Defraene; Bram L T Ramaekers; Philippe Lambin; Erik Briers; Hilary Stobart; Tim Ward; Søren M. Bentzen; Tjeerd Van Staa; David Azria; Barry Rosenstein; Sarah Kerns; Catharine West

doi:10.1016/j.radonc.2016.11.003

Optimal design and patient selection for interventional trials using radiogenomic biomarkers: A REQUITE and Radiogenomics consortium statement

Dirk De Ruysscher^*, Gilles Defraene, Bram L T Ramaekers, Philippe Lambin, Erik Briers, Hilary Stobart, Tim Ward, Søren M. Bentzen, Tjeerd Van Staa, David Azria, Barry Rosenstein, Sarah Kerns, Catharine West

^*Corresponding author for this work

Research output: Contribution to journal › Review article › peer-review

Abstract

The optimal design and patient selection for interventional trials in radiogenomics seem trivial at first sight. However, radiogenomics do not give binary information like in e.g. targetable mutation biomarkers. Here, the risk to develop severe side effects is continuous, with increasing incidences of side effects with higher doses and/or volumes. In addition, a multi-SNP assay will produce a predicted probability of developing side effects and will require one or more cut-off thresholds for classifying risk into discrete categories. A classical biomarker trial design is therefore not optimal, whereas a risk factor stratification approach is more appropriate. Patient selection is crucial and this should be based on the dose–response relations for a specific endpoint. Alternatives to standard treatment should be available and this should take into account the preferences of patients. This will be discussed in detail.

Original language	English
Pages (from-to)	440-446
Number of pages	7
Journal	Radiotherapy and Oncology
Volume	121
Issue number	3
DOIs	https://doi.org/10.1016/j.radonc.2016.11.003
Publication status	Published - 12 Dec 2016

Keywords

Biomarkers
Patient selection
Radiogenomics
Trial design

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10.1016/j.radonc.2016.11.003

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De Ruysscher, D., Defraene, G., Ramaekers, B. L. T., Lambin, P., Briers, E., Stobart, H., Ward, T., Bentzen, S. M., Van Staa, T., Azria, D., Rosenstein, B., Kerns, S., & West, C. (2016). Optimal design and patient selection for interventional trials using radiogenomic biomarkers: A REQUITE and Radiogenomics consortium statement. Radiotherapy and Oncology, 121(3), 440-446. https://doi.org/10.1016/j.radonc.2016.11.003

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abstract = "The optimal design and patient selection for interventional trials in radiogenomics seem trivial at first sight. However, radiogenomics do not give binary information like in e.g. targetable mutation biomarkers. Here, the risk to develop severe side effects is continuous, with increasing incidences of side effects with higher doses and/or volumes. In addition, a multi-SNP assay will produce a predicted probability of developing side effects and will require one or more cut-off thresholds for classifying risk into discrete categories. A classical biomarker trial design is therefore not optimal, whereas a risk factor stratification approach is more appropriate. Patient selection is crucial and this should be based on the dose–response relations for a specific endpoint. Alternatives to standard treatment should be available and this should take into account the preferences of patients. This will be discussed in detail.",

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De Ruysscher, D, Defraene, G, Ramaekers, BLT, Lambin, P, Briers, E, Stobart, H, Ward, T, Bentzen, SM, Van Staa, T, Azria, D, Rosenstein, B, Kerns, S & West, C 2016, 'Optimal design and patient selection for interventional trials using radiogenomic biomarkers: A REQUITE and Radiogenomics consortium statement', Radiotherapy and Oncology, vol. 121, no. 3, pp. 440-446. https://doi.org/10.1016/j.radonc.2016.11.003

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T2 - A REQUITE and Radiogenomics consortium statement

AU - De Ruysscher, Dirk

AU - Defraene, Gilles

AU - Ramaekers, Bram L T

AU - Lambin, Philippe

AU - Briers, Erik

AU - Stobart, Hilary

AU - Ward, Tim

AU - Bentzen, Søren M.

AU - Van Staa, Tjeerd

AU - Azria, David

AU - Rosenstein, Barry

AU - Kerns, Sarah

AU - West, Catharine

PY - 2016/12/12

Y1 - 2016/12/12

N2 - The optimal design and patient selection for interventional trials in radiogenomics seem trivial at first sight. However, radiogenomics do not give binary information like in e.g. targetable mutation biomarkers. Here, the risk to develop severe side effects is continuous, with increasing incidences of side effects with higher doses and/or volumes. In addition, a multi-SNP assay will produce a predicted probability of developing side effects and will require one or more cut-off thresholds for classifying risk into discrete categories. A classical biomarker trial design is therefore not optimal, whereas a risk factor stratification approach is more appropriate. Patient selection is crucial and this should be based on the dose–response relations for a specific endpoint. Alternatives to standard treatment should be available and this should take into account the preferences of patients. This will be discussed in detail.

AB - The optimal design and patient selection for interventional trials in radiogenomics seem trivial at first sight. However, radiogenomics do not give binary information like in e.g. targetable mutation biomarkers. Here, the risk to develop severe side effects is continuous, with increasing incidences of side effects with higher doses and/or volumes. In addition, a multi-SNP assay will produce a predicted probability of developing side effects and will require one or more cut-off thresholds for classifying risk into discrete categories. A classical biomarker trial design is therefore not optimal, whereas a risk factor stratification approach is more appropriate. Patient selection is crucial and this should be based on the dose–response relations for a specific endpoint. Alternatives to standard treatment should be available and this should take into account the preferences of patients. This will be discussed in detail.

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KW - Patient selection

KW - Radiogenomics

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VL - 121

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JO - Radiotherapy and Oncology

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IS - 3

ER -

Optimal design and patient selection for interventional trials using radiogenomic biomarkers: A REQUITE and Radiogenomics consortium statement

Abstract

Keywords

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