摘要: Large-scale electrophysiological recordings now allow simultaneous monitoring of thousands of neurons across multiple brain regions, revealing structured variability in neural population activity. Understanding how these collective patterns emerge from microscopic neural interactions requires models that are scalable, predictive, and interpretable. Statistical physics provides principled frameworks to address this complexity, including maximum-entropy models that offer transparent descriptions of collective neural activity in small populations, but remain largely limited to pairwise interactions and modest system sizes. Here, we use Restricted Boltzmann Machines (RBMs) to model the activity of ∼1500–2000 simultaneously recorded neurons from the Allen Institute Visual Behavior Neuropixels dataset, spanning multiple cortical and subcortical regions of the mouse brain. RBMs are energy-based models that extend the maximum-entropy framework through latent variables, enabling the capture of higher-order dependencies while allowing explicit extraction of effective synaptic networks, including interactions beyond pairwise. Recent advances in efficient Markov Chain sampling and training enable accurate learning of these models at this scale. We show that RBMs reproduce the complex statistics of neural recordings with high accuracy. Generated samples match empirical pairwise and higher-order correlations, as well as global statistics such as the distribution of population activity. Beyond accurate data reconstruction, the inferred parameters provide direct access to effective interactions between neurons, revealing dominant coordination patterns in population activity. These couplings exhibit clear anatomical structure: neurons within visual cortical areas form coherent blocks of stronger interactions, consistent with shared engagement during visually driven behavior, whereas cross-area couplings are weaker and more diffuse. Furthermore, despite not being trained to reproduce temporal dependencies, Markov Chain Monte Carlo simulations of the model accurately reproduce the global neural relaxation dynamics. These results establish RBMs as scalable tools to extract interpretable statistical structure from large-scale neural recordings, linking collective neural activity to the organization of brain regions and task-related behavior.