Beyond deep versus superficial: true laminar inference with MEG

Neural dynamics at the laminar level are critical components of cortical computations, but in humans, non-invasive methods to study these dynamics have been limited to coarse distinctions between deep and superficial layers. Here, we demonstrate that high-precision magnetoencephalography (hpMEG) can achieve laminar inference by localizing sources across all six cortical laminae. Using a multilayer source reconstruction approach, we systematically assess the limits of hpMEGs depth resolution, and show that laminar precision is achievable under optimal signal-to-noise ratios and co-registration accuracy. Our simulations reveal that accurate source reconstruction depends critically on aligning dipole orientations with the underlying cortical columnar structure, and that regional variations in cortical anatomy influence reconstruction fidelity. These findings position hpMEG as a powerful tool for investigating laminar-specific neural dynamics in cognition and behavior, and offer new opportunities to bridge invasive electrophysiology and human neuroimaging.