Responsible Radiomics Research for Faster Clinical Translation

GUIDELINES FOR IMPROVING QUALITY OF RADIOMICS ANALYSES

The complexity of the radiomics workflow increases the need to standardize computation methods (16–19). Since September 2016, about 55 researchers from 19 institutions in 8 countries have participated in the Image Biomarker Standardization Initiative (IBSI), which aims at standardizing both the computation of features and the image-processing steps required before feature extraction (e.g., image interpolation and discretization). First, a simple digital phantom with few discrete image intensities was used to standardize the computation of 172 features from 11 categories. Then, a set of CT images of a lung cancer patient was used to standardize the image-processing steps. The initiative is now reaching completion, and a consensus on image processing and computation of features was reached over time (20,21). However, more work is likely necessary to define and benchmark MRI- and PET-specific image-processing steps. Nonetheless, the standardized workflow (Fig. 1B), along with benchmark values, can serve as a calibration tool for future investigations. Ultimately, it may also lead to standardized software solutions available to the community, as the widespread use of standardized computation methods would greatly enhance the reproducibility potential of radiomics studies. It would also be desirable that the code of existing software be updated to conform with future standards to be established by the IBSI. Furthermore, it is essential to rely on supplementary material (usually allowed in most journals) to provide complete methodologic details, including the comprehensive description of image acquisition protocols, sequence of operations, image postacquisition processing, tumor segmentation, image interpolation, image resegmentation and discretization, formulas for the calculation of features, and benchmark calibrations. Table 1 provides guidelines on feature computation details to be reported in radiomics studies.

After feature extraction, statistical analysis relates features to clinical outcomes. No consensus exists about what defines “good” radiomics studies. For example, the demonstration that a newly designed feature is strongly associated with a given outcome, or that a novel radiomics method holds great potential, may be of interest if compared with the most reproducible and robust features or prognostic clinical information already used. Nonetheless, for the construction of prediction models via multivariable analysis, there are two basic requirements. First, all methodologic details and clinical information must be clearly reported or described to facilitate reproducibility and comparison with other studies and metaanalyses. Second, radiomics-based models must be tested in sufficiently large patient datasets distinct from teaching (training and validation) sets to statistically demonstrate their efficacy over conventional models (e.g., existing biomarkers, tumor volume, and cancer stage). Ideally, for optimal reproducibility potential, all data and programming code related to the study should also be made available to the community. Table 2 provides guidelines based on the “radiomics quality score” (www.radiomics.world), which can help evaluate the quality of radiomics studies. More guidelines on reproducible prognostic modeling can be found in the TRIPOD statement (transparent reporting of a multivariable prediction model for individual prognosis or diagnosis) (22).

RESPONSIBLE RESEARCH IS THE KEY

Some guiding principles already exist to help radiomics scientists further implement the responsible research paradigm into their current practice. For one, the Responsible Research and Innovation website (www.rri-tools.eu) provides useful guidelines. Furthermore, a concise set of principles for better scientific data management and stewardship—the “FAIR guiding principles” (23)—has been defined, stating that all research objects should be findable, accessible, interoperable, and reusable. Implementation of the FAIR principles within the radiomics field can facilitate its faster clinical translation. Many research tools and online repositories already implement a variety of aspects of the FAIR principles (23), and we can add two other tools of interest: the Cancer Imaging Archive (www.cancerimagingarchive.net), a service that anonymizes and hosts medical images for public download, and the Radiomics Ontology (www.bioportal.bioontology.org/ontologies/RO), a repository on the National Center for Biomedical Ontology BioPortal aiming to improve the interoperability of radiomics analyses via consistent tagging of radiomics features, segmentation algorithms, and imaging filters. This ontology could provide a standardized way of reporting radiomics data and methods, and would more concisely summarize the implementation details of a given radiomics workflow (e.g., Table 1).

To conclude, initial pioneer studies in radiomics have paved the way to an exciting field and to most promising methods for better personalizing cancer treatments. Yet, better standardization, transparency, and sharing practices in the radiomics community are required to improve the quality of published studies and to achieve a faster clinical translation. The best way to reach this goal is through responsible radiomics research, which can be summarized into three working principles that we should all try to follow as a research community: design and conduct high-quality radiomics research, write and present fully transparent radiomics research, and share data and methods.

DISCLOSURE

Alex Zwanenburg is supported by the German Federal Ministry of Education and Research (BMBF-0371N52). Martin Vallières is supported by the National Institute of Cancer (INCa project C14020NS). No other potential conflict of interest relevant to this article was reported.