Abstract
PurposeThe aim of this systematic review was to analyse literature on artificial intelligence (AI) and radiomics, including all medical imaging modalities, for oncological and non-oncological applications, in order to assess how far the image mining research stands from routine medical application. To do this, we applied a trial phases classification inspired from the drug development process.MethodsAmong the articles we considered for inclusion from PubMed were multimodality AI and radiomics investigations, with a validation analysis aimed at relevant clinical objectives. Quality assessment of selected papers was performed according to the QUADAS-2 criteria. We developed the phases classification criteria for image mining studies.ResultsOverall 34,626 articles were retrieved, 300 were selected applying the inclusion/exclusion criteria, and 171 high-quality papers (QUADAS-2 ≥ 7) were identified and analysed. In 27/171 (16%), 141/171 (82%), and 3/171 (2%) studies the development of an AI-based algorithm, radiomics model, and a combined radiomics/AI approach, respectively, was described. A total of 26/27(96%) and 1/27 (4%) AI studies were classified as phase II and III, respectively. Consequently, 13/141 (9%), 10/141 (7%), 111/141 (79%), and 7/141 (5%) radiomics studies were classified as phase 0, I, II, and III, respectively. All three radiomics/AI studies were categorised as phase II trials.ConclusionsThe results of the studies are promising but still not mature enough for image mining tools to be implemented in the clinical setting and be widely used. The transfer learning from the well-known drug development process, with some specific adaptations to the image mining discipline could represent the most effective way for radiomics and AI algorithms to become the standard of care tools.
Highlights
The BArtificial Intelligence (AI) winter^ [1] is over
According to the scope of the review, we considered artificial intelligence (AI) and radiomics investigations aimed at relevant objectives in clinical practice: biological characterisation, risk stratification, treatment response prediction, toxicity prediction, and prognostication of a certain disease
The imaging modalities we considered were ultrasound, radiography, mammography, endoscopy, skin pictures, ocular fundus pictures, computed tomography (CT), magnetic resonance imaging (MRI), scintigraphy and positron emission tomography (PET) or PET/CT
Summary
The BArtificial Intelligence (AI) winter^ [1] is over. AI and radiomics approaches applied to medical images for the noninvasive characterisation of diseases (i.e., image mining) have. This article is part of the Topical Collection on Advanced Image Analyses (Radiomics and Artificial Intelligence). Image mining is claimed to have a potentially huge clinical relevance with the possibility to non-invasively diagnose, characterise and predict the outcome in almost all medical conditions. Despite the amount of published studies, some issues including significance, goodness, and strength of the reported results are still to be addressed. It is not clear how far image mining is from clinical practice
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
