Distinct neural architectures underlie motor skill acquisition and transfer in human sensorimotor cortex

Motor learning typically emerges from repetitive practice but can also arise through transfer or generalization, where improvements extend to untrained actions. While training-based (training effect) and transfer/generalization-based (transfer effect) learning often result in comparable motor performance, little is known about the extent to which they share similar neural underpinnings or if they are two separate phenomena that rely on distinct cortical architecture. Here, we employed between-subject multivariate decoding of hyperaligned functional data obtained with high-field (7 Tesla) magnetic resonance imaging to characterize the universal neural codes underlying the training and transfer effects, and compared their resultant motor engrams in the sensorimotor cortex. We found that both learning mechanisms have reliable neural representations that are shared across individual brains, highlighting similar representational geometry despite idiosyncratic functional topographies. While their codes are embedded in overlapping cortical areas, the training effect has a more stable representation centered in the primary sensorimotor cortex, indicative of execution-level learning. In contrast, transfer effects elicited more abstract, variable codes in adjacent premotor and postcentral areas, suggesting flexible recombination of motor chunks. Moreover, the resultant cortical engrams shaped by them are particularly distinct in the left inferior part of the precentral sulcus, and in the right side of the superior part of the precentral sulcus, postcentral gyrus and postcentral sulcus. Our findings support the notion that motor skill learning is hierarchically organized in the sensorimotor cortex, and extend current models by revealing how training and transfer encode distinct, mechanism-dependent, and high-dimensional representations embedded in a neural code that is shared across brains.