Explainable Machine Learning Predictions of Perceptual Sensitivity for Retinal Prostheses.
Galen Nicholas PogoncheffZuying HuAriel RokemMichael BeyelerPublished in: medRxiv : the preprint server for health sciences (2023)
To provide appropriate levels of stimulation, retinal prostheses must be calibrated to an individual's perceptual thresholds ('system fitting'), despite thresholds varying drastically across subjects, across electrodes within a subject, and over time. Although previous work has identified electrode-retina distance and impedance as key factors affecting thresholds, an accurate predictive model is still lacking. To address these challenges, we 1) fitted machine learning (ML) models to a large longitudinal dataset with the goal of predicting individual electrode thresholds and deactivation as a function of stimulus, electrode, and clinical parameters ('predictors') and 2) leveraged explainable artificial intelligence (XAI) to reveal which of these predictors were most important. Our models accounted for up to 77% of the perceptual threshold response variance and enabled predictions of whether an electrode was deactivated in a given trial with F1 and AUC scores of up to 0.740 and 0.913, respectively. Deactivation and threshold models identified novel predictors of perceptual sensitivity, including subject age, time since blindness onset, and electrode-fovea distance. Our results demonstrate that routinely collected clinical measures and a single session of system fitting might be sufficient to inform an XAI-based threshold prediction strategy, which may transform clinical practice in predicting visual outcomes.
Keyphrases
- machine learning
- artificial intelligence
- carbon nanotubes
- working memory
- big data
- solid state
- diabetic retinopathy
- deep learning
- clinical practice
- optical coherence tomography
- clinical trial
- optic nerve
- randomized controlled trial
- study protocol
- type diabetes
- magnetic resonance imaging
- adipose tissue
- magnetic resonance
- computed tomography
- gold nanoparticles
- dna methylation
- weight loss