Your search keyword '"Galea, Joseph M."' showing total 5 results

1. Cerebellar Transcranial Direct Current Stimulation (ctDCS)

Author

Grimaldi, Giuliana, Argyropoulos, Georgios P., Bastian, Amy, Cortes, Mar, Davis, Nicholas J., Edwards, Dylan J., Ferrucci, Roberta, Fregni, Felipe, Galea, Joseph M., Hamada, Masahi, Manto, Mario, Miall, R. Chris, Morales-Quezada, Leon, Pope, Paul A., Priori, Alberto, Rothwell, John, Tomlinson, S. Paul, and Celnik, Pablo

Subjects

safety, language, learning, Neuronal Plasticity, cerebellum, Cerebellar Ataxia, Motor Cortex, Reviews, emotion, modeling, Transcranial Direct Current Stimulation, ctDCS, motor, working memory, cognitive, nervous system, plasticity, Animals, Humans, direct current stimulation, transcranial

Abstract

The cerebellum is critical for both motor and cognitive control. Dysfunction of the cerebellum is a component of multiple neurological disorders. In recent years, interventions have been developed that aim to excite or inhibit the activity and function of the human cerebellum. Transcranial direct current stimulation of the cerebellum (ctDCS) promises to be a powerful tool for the modulation of cerebellar excitability. This technique has gained popularity in recent years as it can be used to investigate human cerebellar function, is easily delivered, is well tolerated, and has not shown serious adverse effects. Importantly, the ability of ctDCS to modify behavior makes it an interesting approach with a potential therapeutic role for neurological patients. Through both electrical and non-electrical effects (vascular, metabolic) ctDCS is thought to modify the activity of the cerebellum and alter the output from cerebellar nuclei. Physiological studies have shown a polarity-specific effect on the modulation of cerebellar-motor cortex connectivity, likely via cerebellar-thalamocortical pathways. Modeling studies that have assessed commonly used electrode montages have shown that the ctDCS-generated electric field reaches the human cerebellum with little diffusion to neighboring structures. The posterior and inferior parts of the cerebellum (i.e., lobules VI-VIII) seem particularly susceptible to modulation by ctDCS. Numerous studies have shown to date that ctDCS can modulate motor learning, and affect cognitive and emotional processes. Importantly, this intervention has a good safety profile; similar to when applied over cerebral areas. Thus, investigations have begun exploring ctDCS as a viable intervention for patients with neurological conditions.

Published

2016

2. Individual differences in explicit and implicit visuomotor learning and working memory capacity

Author

Christou, Antonios I., Miall, R. Chris, McNab, Fiona, and Galea, Joseph M.

Abstract

The theoretical basis for the association between high working memory capacity (WMC) and enhanced visuomotor adaptation is unknown. Visuomotor adaptation involves interplay between explicit and implicit systems. We examined whether the positive association between adaptation and WMC is specific to the explicit component of adaptation. Experiment 1 replicated the positive correlation between WMC and adaptation, but revealed this was specific to the explicit component of adaptation, and apparently driven by a sub-group of participants who did not show any explicit adaptation in the correct direction. A negative correlation was observed between WMC and implicit learning. Experiments 2 and 3 showed that when the task restricted the development of an explicit strategy, high WMC was no longer associated with enhanced adaptation. This work reveals that the benefit of high WMC is specifically linked to an individual’s capacity to use an explicit strategy. It also reveals an important contribution of individual differences in determining how adaptation is performed.

Published

2016

3. Cerebellar Transcranial Direct Current Stimulation (ctDCS): A Novel Approach to Understanding Cerebellar Function in Health and Disease

Author

Grimaldi, Giuliana, Argyropoulos, Georgios P, Bastian, Amy, Cortes, Mar, Davis, Nicholas J, Edwards, Dylan J, Ferrucci, Roberta, Fregni, Felipe, Galea, Joseph M, Hamada, Masahi, Manto, Mario, Miall, R Chris, Morales-Quezada, Leon, Pope, Paul A, and Priori, Alberto

Subjects

cognitive, safety, language, learning, cerebellum, plasticity, emotion, direct current stimulation, modeling, ctDCS, transcranial, motor, working memory

Abstract

The cerebellum is critical for both motor and cognitive control. Dysfunction of the cerebellum is a component of multiple neurological disorders. In recent years, interventions have been developed that aim to excite or inhibit the activity and function of the human cerebellum. Transcranial direct current stimulation of the cerebellum (ctDCS) promises to be a powerful tool for the modulation of cerebellar excitability. This technique has gained popularity in recent years as it can be used to investigate human cerebellar function, is easily delivered, is well tolerated, and has not shown serious adverse effects. Importantly, the ability of ctDCS to modify behavior makes it an interesting approach with a potential therapeutic role for neurological patients. Through both electrical and non-electrical effects (vascular, metabolic) ctDCS is thought to modify the activity of the cerebellum and alter the output from cerebellar nuclei. Physiological studies have shown a polarity-specific effect on the modulation of cerebellar–motor cortex connectivity, likely via cerebellar–thalamocortical pathways. Modeling studies that have assessed commonly used electrode montages have shown that the ctDCS-generated electric field reaches the human cerebellum with little diffusion to neighboring structures. The posterior and inferior parts of the cerebellum (i.e., lobules VI-VIII) seem particularly susceptible to modulation by ctDCS. Numerous studies have shown to date that ctDCS can modulate motor learning, and affect cognitive and emotional processes. Importantly, this intervention has a good safety profile; similar to when applied over cerebral areas. Thus, investigations have begun exploring ctDCS as a viable intervention for patients with neurological conditions.

Published

2016

4. Delineating Cerebellar Mechanisms In Dyt11

Author

Sadnicka, Anna, Galea, Joseph M., Chen, Jui-Cheng, Warner, Thomas T., Bhatia, Kailash P., Rothwell, John C., and Edwards, Mark J.

Abstract

BACKGROUND: Recent research has highlighted the role of the cerebellum in the pathophysiology of myoclonus-dystonia syndrome as a result of mutations in the ɛ-sarcoglycan gene (DYT11). Specifically, a cerebellar-dependent saccadic adaptation task is dramatically impaired in this patient group. OBJECTIVES: The objective of this study was to investigate whether saccadic deficits coexist with impairments of limb adaptation to provide a potential mechanism linking cerebellar dysfunction to the movement disorder within symptomatic body regions. METHODS: Limb adaptation to visuomotor (visual feedback rotated by 30°) and forcefield (force applied by robot to deviate arm) perturbations were examined in 5 patients with DYT11 and 10 aged-matched controls. RESULTS: Patients with DYT11 successfully adapted to both types of perturbation. Modelled and averaged summary metrics that captured adaptation behaviors were equivalent to the control group across conditions. CONCLUSIONS: DYT11 is not characterized by a uniform deficit in adaptation. The previously observed large deficit in saccadic adaption is not reflected in an equivalent deficit in limb adaptation in symptomatic body regions. We suggest potential mechanisms at the root of this discordance and identify key research questions that need future study.

5. No consistent effect of cerebellar transcranial direct current stimulation on visuomotor adaptation

Author

Jalali, Roya, Miall, R. Chris, and Galea, Joseph M.