Abstract
To acquire and maintain precise movement controls over a lifespan, changes in the physical and physiological characteristics of muscles must be compensated for adaptively. The cerebellum plays a crucial role in such adaptation. Changes in muscle characteristics are not always symmetrical. For example, it is unlikely that muscles that bend and straighten a joint will change to the same degree. Thus, different (i.e., asymmetrical) adaptation is required for bending and straightening motions. To date, little is known about the role of the cerebellum in asymmetrical adaptation. Here, we investigate the cerebellar mechanisms required for asymmetrical adaptation using a bi-hemispheric cerebellar neuronal network model (biCNN). The bi-hemispheric structure is inspired by the observation that lesioning one hemisphere reduces motor performance asymmetrically. The biCNN model was constructed to run in real-time and used to control an unstable two-wheeled balancing robot. The load of the robot and its environment were modified to create asymmetrical perturbations. Plasticity at parallel fiber-Purkinje cell synapses in the biCNN model was driven by error signal in the climbing fiber (cf) input. This cf input was configured to increase and decrease its firing rate from its spontaneous firing rate (approximately 1 Hz) with sensory errors in the preferred and non-preferred direction of each hemisphere, as demonstrated in the monkey cerebellum. Our results showed that asymmetrical conditions were successfully handled by the biCNN model, in contrast to a single hemisphere model or a classical non-adaptive proportional and derivative controller. Further, the spontaneous activity of the cf, while relatively small, was critical for balancing the contribution of each cerebellar hemisphere to the overall motor command sent to the robot. Eliminating the spontaneous activity compromised the asymmetrical learning capabilities of the biCNN model. Thus, we conclude that a bi-hemispheric structure and adequate spontaneous activity of cf inputs are critical for cerebellar asymmetrical motor learning.
Highlights
Development, aging, and injuries are common conditions that prevent the neural centers governing the muscles from being rigid and hard-wired
The benefit of using the bi-hemispheric cerebellar neuronal network model (biCNN) model in this control scenario is clearly recognized by comparing the RSE with the one achieved by using only the proportional and derivative (PD) controller (Figures 6A,D, lines labeled as “PD”)
At the end of the experiment (Figures 6G,H), the PD output was severely affected by the external perturbation, whereas the biCNN model output increased its amplitude by 60%
Summary
Development, aging, and injuries are common conditions that prevent the neural centers governing the muscles from being rigid and hard-wired. The cerebellum is one example of a neural center where adaptation is crucial. Adaptation in the cerebellum has been widely studied in eye movements such as smooth pursuit (Belknap and Noda, 1987; Stone and Lisberger, 1990), the vestibuloocular reflex (VOR) (Lisberger et al, 1994; Ito, 1998; Hirata and Highstein, 2001; Blazquez et al, 2003; Broussard and Kassardjian, 2004), and saccades (Hopp and Fuchs, 2004; Kojima et al, 2010) because these adaptations can be evoked under experimental conditions. VOR gain, defined as eye velocity divided by head velocity during head turn, can be tuned up using a visual-vestibular mismatch stimulus (Melvill Jones et al, 1988; Paige and Sargent, 1991; Kassardjian et al, 2005; Anzai et al, 2010). The vertical VOR gain can be increased in the up direction (i.e., downward head turn) and decreased in the down direction (i.e., upward head turn) simultaneously in monkeys
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