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Applications of interpretable deep learning in neuroimaging: A comprehensive review

Lindsay Munroe, Mariana da Silva, Faezeh Heidari, Irina Grigorescu, Simon Dahan, Emma C. Robinson, Maria Deprez, Po‐Wah So

2024Imaging Neuroscience19 citationsDOIOpen Access PDF

Abstract

Clinical adoption of deep learning models has been hindered, in part, because the "black-box" nature of neural networks leads to concerns regarding their trustworthiness and reliability. These concerns are particularly relevant in the field of neuroimaging due to the complex brain phenotypes and inter-subject heterogeneity often encountered. The challenge can be addressed by interpretable deep learning (iDL) methods that enable the visualisation and interpretation of the inner workings of deep learning models. This study systematically reviewed the literature on neuroimaging applications of iDL methods and critically analysed how iDL explanation properties were evaluated. Seventy-five studies were included, and ten categories of iDL methods were identified. We also reviewed five properties of iDL explanations that were analysed in the included studies: biological validity, robustness, continuity, selectivity, and downstream task performance. We found that the most popular iDL approaches used in the literature may be sub-optimal for neuroimaging data, and we discussed possible future directions for the field.

Topics & Concepts

NeuroimagingDeep learningComputer scienceArtificial intelligenceRobustness (evolution)TrustworthinessDeep neural networksField (mathematics)Cognitive scienceData scienceMachine learningPsychologyNeuroscienceChemistryGenePure mathematicsBiochemistryMathematicsComputer securityExplainable Artificial Intelligence (XAI)Machine Learning in HealthcareFunctional Brain Connectivity Studies
Applications of interpretable deep learning in neuroimaging: A comprehensive review | Litcius