Specificity or generalization? Neural mechanisms for perceptual learning with variability

Our visual system is equipped with a powerful plasticity mechanism, perceptual learning, which serves to improve perception of consistent inputs. However, the signals the visual system receives are extremely variable. How variability affects perceptual learning is unclear. In VarPL, we ask how the visual system tackles the challenge of variability for learning: variability could impair perceptual learning, or, like in language and motor learning, result in the ability to generalize from trained to new materials. To create effective training programs, e.g. for clinical applications, it is crucial to know how to reap the benefits of variability, or, conversely, to overcome the challenges variability poses. Yet, the neural mechanisms by which the visual system copes with variability are unknown, hampering this endeavor. To close this gap, we pursued and established a new theory, derived from the architecture of cortex: we hypothesize that perceptual learning is not limited to early visual areas, as traditionally envisaged. Instead, learning flexibly occurs at a ‘sweet spot’ along the visual hierarchy whose functional properties match the variability in the given environment. To test this theory, we investigated the role of stimulus variability during training. We hypothesized that variability during multi-day training pushes plasticity to higher brain areas in the visual processing hierarchy, whose tuning properties support generalization. While previous studies in visual learning have shied away from variability, we actively explored its role, and unraveled previously unknown flexibility of the visual system that provides a path forward to application of perceptual learning in applied settings, e.g. for vision restoration.

To test our hypothesis, we have developed novel training paradigms to prompt generalizable learning. With these new paradigms, we have been able to determine under which conditions learning is specific, and when it generalizes beyond the training material. For example, we have characterized effects of stimulus variability during training on generalization along several visual feature dimensions. We have also determined whether beyond stimulus features, learning is also specific for effectors, e.g. the kind of movement with which the task is executed. With the use of functional Magnetic Resonance Imaging (fMRI) and electrophysiology, we map out the brain areas that underlie these behavioral effects. To this end, we also work on improving fMRI data acquisition and analysis protocols. We have so far published four papers in international peer-reviewed journals and presented our results at several international conferences, including SfN and VSS, the two major outlets for neuroscience and vision research. We have also successfully disseminated our results to the public, e.g. through press releases and articles in magazines for lay audiences.

VarPL has established variability as a fundamental organizing principle of learning, enabling a reconceptualization of perceptual learning as generalizable. This way, we hope to enable the development of rehabilitation programs for visual impairments like macular degeneration or after brain lesions. Finally, understanding generalization may further the development of learning algorithms, which still lack our flexibility to generalize.