Network structure influences the strength of learned neural representations.
Ari E KahnKarol P SzymulaEdda B HaggertyNathaniel NyemaGeoffrey K AguirreDanielle S BassettPublished in: bioRxiv : the preprint server for biology (2023)
Human experience is built upon sequences of discrete events. From those sequences, humans build impressively accurate models of their world. This process has been referred to as graph learning, a form of structure learning in which the mental model encodes the graph of event-to-event transition probabilities [1], [2], typically in medial temporal cortex [3]-[6]. Recent evidence suggests that some network structures are easier to learn than others [7]-[9], but the neural properties of this effect remain unknown. Here we use fMRI to show that the network structure of a temporal sequence of stimuli influences the fidelity with which those stimuli are represented in the brain. Healthy adult human participants learned a set of stimulus-motor associations following one of two graph structures. The design of our experiment allowed us to separate regional sensitivity to the structural, stimulus, and motor response components of the task. As expected, whereas the motor response could be decoded from neural representations in postcentral gyrus, the shape of the stimulus could be decoded from lateral occipital cortex. The structure of the graph impacted the nature of neural representations: when the graph was modular as opposed to lattice-like, BOLD representations in visual areas better predicted trial identity in a held-out run and displayed higher intrinsic dimensionality. Our results demonstrate that even over relatively short timescales, graph structure determines the fidelity of event representations as well as the dimensionality of the space in which those representations are encoded. More broadly, our study shows that network context influences the strength of learned neural representations, motivating future work in the design, optimization, and adaptation of network contexts for distinct types of learning over different timescales.
Keyphrases
- working memory
- convolutional neural network
- resting state
- functional connectivity
- endothelial cells
- neural network
- clinical trial
- induced pluripotent stem cells
- mental health
- machine learning
- pluripotent stem cells
- deep learning
- study protocol
- randomized controlled trial
- network analysis
- young adults
- phase ii
- amino acid
- genetic diversity