Guillermo Sánchez-Garrido Campos scite author profile

Transcranial direct-current stimulation (tDCS) is a non-invasive brain stimulation technique consisting in the application of weak electric currents on the scalp. Although previous studies have demonstrated the clinical value of tDCS for modulating sensory, motor, and cognitive functions, there are still huge gaps in the knowledge of the underlying physiological mechanisms. To define the immediate impact as well as the after effects of tDCS on sensory processing, we first performed electrophysiological recordings in primary somatosensory cortex (S1) of alert mice during and after administration of S1-tDCS, and followed up with immunohistochemical analysis of the stimulated brain regions. During the application of cathodal and anodal transcranial currents we observed polarity-specific bidirectional changes in the N1 component of the sensory-evoked potentials (SEPs) and associated gamma oscillations. On the other hand, 20 min of cathodal stimulation produced significant after-effects including a decreased SEP amplitude for up to 30 min, a power reduction in the 20–80 Hz range and a decrease in gamma event related synchronization (ERS). In contrast, no significant changes in SEP amplitude or power analysis were observed after anodal stimulation except for a significant increase in gamma ERS after tDCS cessation. The polarity-specific differences of these after effects were corroborated by immunohistochemical analysis, which revealed an unbalance of GAD 65–67 immunoreactivity between the stimulated versus non-stimulated S1 region only after cathodal tDCS. These results highlight the differences between immediate and after effects of tDCS, as well as the asymmetric after effects induced by anodal and cathodal stimulation.

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Immediate and long-term effects of transcranial direct-current stimulation in the mouse primary somatosensory cortex

Sánchez-León

Cordones

Ammann

et al. 2020

Preprint

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AbstractTranscranial direct-current stimulation (tDCS) is a non-invasive brain stimulation technique consisting in the application of weak electric currents on the scalp. Although previous studies have demonstrated the clinical value of tDCS for modulating sensory, motor, and cognitive functions, there are still huge gaps in the knowledge of the underlying physiological mechanisms. To define the immediate impact as well as the after-effects of tDCS on sensory processing, we first performed electrophysiological recordings in primary somatosensory cortex (S1) of alert mice during and after administration of S1-tDCS, and followed up with immunohistochemical analysis of the stimulated brain regions. During the application of cathodal and anodal transcranial currents we observed polarity-specific bidirectional changes in the N1 component of the sensory-evoked potentials (SEPs) and associated gamma oscillations. Regarding the long-term effects observed after 20 min of tDCS, cathodal stimulation produced significant after-effects including a decreased SEP amplitude for up to 30 min, a power reduction in the 20-80 Hz range and a decrease in gamma event related synchronization (ERS). In contrast, no significant long-term changes in SEP amplitude or power analysis were observed after anodal stimulation except for a significant increase in gamma ERS after tDCS cessation. The polarity-specific differences of these long-term effects were corroborated by immunohistochemical analysis, which revealed an unbalance of GAD 65-67 immunoreactivity between the stimulated vs. non-stimulated S1 region only after cathodal tDCS. These results highlight the differences between immediate and long-term effects of tDCS, as well as the asymmetric long-term changes induced by anodal and cathodal stimulation.Significance StatementHere we provide a first glimpse at the immediate and long-term impact of tDCS on neural processing in alert animals. The obtained results highlight the complexity of tDCS-associated effects, which include both bidirectional as well as asymmetrical modulation depending on the polarity of the stimulation. This asymmetry suggests the implication of different mechanisms underlying the long-term effects induced by anodal and cathodal transcranial currents. Identifying and defining these effects and its associated mechanisms is crucial to help design effective protocols for clinical applications.

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Somatodendritic orientation determines tDCS-induced neuromodulation of Purkinje cell activity in awake mice

Sánchez-León

Campos

Fernández

et al. 2023

Preprint

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Transcranial direct-current stimulation (tDCS) is a promising non-invasive neuromodulatory technique being proposed for treating neurologic disorders. However, there is a lack of knowledge about how externally applied currents affect neuronal spiking activity in cerebellar circuits in vivo. In this study, we observe a heterogeneous polarity modulation of the firing rate of Purkinje cells (PC) and non-PC in the mouse cerebellar cortex. Using a combination of juxtacellular labeling and high-density Neuropixels recordings, we demonstrate that the apparently heterogeneous effects of tDCS on PC activity can be fully explained by taking into account the somatodendritic orientation relative to the electric field. Our findings emphasize the importance of considering neuronal orientation and morphological aspects to increase the predictive power of tDCS computational models and optimize desired effects in basic and clinical human applications.

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Role of neuronal orientation on cerebellar transcranial direct-current stimulation (cb-tDCS) effects in awake mice

Campos¹,

Sánchez-López²,

León³

et al. 2023

Brain Stimulation

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Characterisation of immediate effects of tDCS on glutamatergic and GABaergic optogenetic response in the somatosensory cortex of awake mouse

Rodríguez¹,

Álvarez²,

Cano³

et al. 2023

Brain Stimulation

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