Abstract
The cerebellum is thought to mediate sensorimotor adaptation through the acquisition of internal models of the body-environment interaction. These representations can be of two types, identified as forward and inverse models. The first predicts the sensory consequences of actions, while the second provides the correct commands to achieve desired state transitions. In this paper, we propose a composite architecture consisting of multiple cerebellar internal models to account for the adaptation performance of humans during sensorimotor learning. The proposed model takes inspiration from the cerebellar microcomplex circuit, and employs spiking neurons to process information. We investigate the intrinsic properties of the cerebellar circuitry subserving efficient adaptation properties, and we assess the complementary contributions of internal representations by simulating our model in a procedural adaptation task. Our simulation results suggest that the coupling of internal models enhances learning performance significantly (compared with independent forward and inverse models), and it allows for the reproduction of human adaptation capabilities. Furthermore, we provide a computational explanation for the performance improvement observed after one night of sleep in a wide range of sensorimotor tasks. We predict that internal model coupling is a necessary condition for the offline consolidation of procedural memories.
Highlights
The cerebellum plays a prominent role in motor control, movement coordination, and context-dependent sensorimotor adaptation (Ito, 2002; Fine et al, 2002; Ito, 2006)
We investigate the intrinsic properties of the cerebellar circuitry subserving efficient adaptation properties, and we assess the complementary contributions of internal representations by simulating our model in a procedural adaptation task
Prior to the execution of the main series of simulations, we verified that learning in forward predictor cerebellar models would result in accurate estimates of future sensory outcomes of motor commands, and that adaptation in inverse correctors could significantly improve the accuracy of motor command execution
Summary
The cerebellum plays a prominent role in motor control, movement coordination, and context-dependent sensorimotor adaptation (Ito, 2002; Fine et al, 2002; Ito, 2006). Inverse internal models work in the opposite direction, by estimating the motor commands that lead to desired state updates (Contreras-Vidal et al, 1997; Schweighofer et al, 1998; Kawato, 1999; Sethu Vijayakumar and Schaal, 2005). Both forward and inverse models depend on the dynamics of the motor system and must adapt to contextual changes as well as motor apparatus modifications (Lalazar and Vaadia, 2008). Experimental evidence from behavioural, functional imaging, and neurophysiological studies suggests that the cerebellum can acquire and store internal models mediating procedural learning (Bell et al, 1997; Miall, 1998; Wolpert et al, 1998; Eskandar and Assad, 1999; Kawato et al, 2003; Ito, 2005; Pasalar et al, 2006; Mulliken et al, 2008)
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