Increasing human leg motor cortex excitability by transcranial high frequency random noise stimulation

Laczó, Bence; Antal, Andrea; Rothkegel, Holger; Paulus, Walter

doi:10.3233/rnn-130367

Cited by 32 publications

(33 citation statements)

References 41 publications

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“…A large cathode was used to maintain the current density of the reference electrode at a low level, as such a reference electrode was demonstrated to be functionally ineffective without compromising the effectiveness of tDCS regarding the stimulation electrode [39,40]. The anatomical landmark for bilateral M1 (leg area) was determined according to previous studies which based their peak coordinates on Transcranial magnetic stimulation (TMS)-measurements [41][42][43]. For anodal tDCS of M1, we placed the anode 1 cm behind the vertex (Cz) on the mid-sagittal line to cover both leg motor cortices.…”

Section: Transcranial Direct Current Stimulationmentioning

confidence: 99%

Cerebellar Transcranial Direct Current Stimulation Improves Maximum Isometric Force Production during Isometric Barbell Squats

Kenville

Maudrich

et al. 2020

Brain Sciences

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Maximum voluntary contraction force (MVC) is an important predictor of athletic performance as well as physical fitness throughout life. Many everyday life activities involve multi-joint or whole-body movements that are determined in part through optimized muscle strength. Transcranial direct current stimulation (tDCS) has been reported to enhance muscle strength parameters in single-joint movements after its application to motor cortical areas, although tDCS effects on maximum isometric voluntary contraction force (MIVC) in compound movements remain to be investigated. Here, we tested whether anodal tDCS and/or sham stimulation over primary motor cortex (M1) and cerebellum (CB) improves MIVC during isometric barbell squats (iBS). Our results provide novel evidence that CB stimulation enhances MIVC during iBS. Although this indicates that parameters relating to muscle strength can be modulated through anodal tDCS of the cerebellum, our results serve as an initial reference point and need to be extended. Therefore, further studies are necessary to expand knowledge in this area of research through the inclusion of different tDCS paradigms, for example investigating dynamic barbell squats, as well as testing other whole-body movements.

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Section: Transcranial Direct Current Stimulationmentioning

confidence: 99%

Cerebellar Transcranial Direct Current Stimulation Improves Maximum Isometric Force Production during Isometric Barbell Squats

Kenville

Maudrich

et al. 2020

Brain Sciences

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“…A 45-second rest period was provided between each trial to minimize any potential effects of fatigue. After completing the target-matching experiment, the subject underwent either anodal tDCS (2 mA, 10 minutes, 0.125 mA/cm 2 ) (Laczo et al, 2014;Wiethoff et al, 2014) or the control condition depending on their group allocation. All procedures were exactly identical between the two conditions (i.e., groups), except that no stimulation was provided to the subjects in the control condition (see Figure 1a).…”

Section: B Experimental Protocolmentioning

confidence: 99%

Recurrence quantification analysis of surface electromyogram supports alterations in motor unit recruitment strategies by anodal transcranial direct current stimulation

Dutta

Krishnan

Kantak

et al. 2015

RNN

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“…It is hypothesized that by the random changes in polarity homeostatic counteracting processes influencing the neuronal ion channels in the electrical field are avoided thus inhibiting adaption processes of the neuronal cell membrane and the resulting back shift to "resting state"-levels (24). High frequency tRNS (101 -640 Hz) exerts excitatory cortical effects of the motor cortex (26) and the auditory cortex (27), whereas low frequency tRNS (0.1 -100 Hz) seems to exert no significant effects on motor cortical areas (25). However, clinical effects of low-frequency tRNS applied to the auditory cortex have been shown in chronic tinnitus (28).…”

Section: Discussionmentioning

confidence: 99%

A Case Report on Red Ear Syndrome with Tinnitus Successfully Treated with Transcranial Random Noise Stimulation

Vielsmeier

et al. 2017

Pain Phys

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Background: The red ear syndrome represents a rare symptom complex consisting of auricular erythema associated with painful and burning sensations. It has been described in combination with tinnitus rarely. It has been hypothesized to be etiologically related to altered trigeminal afferent input, temporomandibular disorders, and thalamic dysfunction. Objectives: The initial objective of applying transcranial random noise stimulation (tRNS) in a case of red ear syndrome in combination with tinnitus was the alleviation of the phantom sounds. Study Design: This is a case report on the successful treatment of red ear syndrome with tinnitus by means of transcranial random noise stimulation (tRNS) and a short review on the published cases of this condition. Setting: We present the case of a 50-year-old woman reporting a simultaneous onset of constant left-sided tinnitus and feelings of warmth accompanied by an intermittent stabbing and/or oppressive pain stretching from the ipsilateral ear to the head/neck/shoulder region, occasionally accompanied by nausea/vomiting and dizziness. After failure of pharmacological treatment attempts, either because of lacking clinical effects (gabapentin, zolmitriptan, and indomethacin) or because of adverse reactions (pregabaline), the patient was offered an experimental neuromodulatory treatment with bitemporal tRNS primarily targeting the tinnitus complaints of the patient. Methods: tRNS was conducted in 2 – 3 day sessions (stimulation site: bilateral temporal cortex/2.0 mA/10 s on-and-off-ramp/offset 0 mA/20 min/random frequencies 101 – 640Hz / NeuroConn Eldith DC-Stimulator plus). Results: In 3 consecutive pain attacks repeated sessions of tRNS resulted in substantial alleviation of pain intensity and a prolongation of the interval between attacks. This was an expected finding as the proposed tRNS treatment was initially offered to the patient aiming at an alleviation of the tinnitus complaints (which remained unaffected by tRNS). Limitations: The reported data derive from compassionate use treatment in one single patient. Application of a sham condition would have been desirable, but is not possible in the context of compassionate use treatment. Nevertheless, we would consider it rather unlikely that the reported effects are purely unspecific as the patient did exclusively report symptom alleviation of pain-related parameters without affecting the tinnitus. Conclusions: This case report demonstrates the feasibility and therapeutic potential of applying neuromodulatory treatment approaches in red ear syndrome, a rare form of trigemino-autonomal headache. Therefore, it deserves detailed observation in clinical routine applications as well as controlled trials further investigating its neurobiological effects. Key words: Red ear syndrome, pain, trigemino-autonomal headache, chronic tinnitus, transcranial electrical stimulation, random noise stimulation

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Increasing human leg motor cortex excitability by transcranial high frequency random noise stimulation

Cited by 32 publications

References 41 publications

Cerebellar Transcranial Direct Current Stimulation Improves Maximum Isometric Force Production during Isometric Barbell Squats

Cerebellar Transcranial Direct Current Stimulation Improves Maximum Isometric Force Production during Isometric Barbell Squats

Recurrence quantification analysis of surface electromyogram supports alterations in motor unit recruitment strategies by anodal transcranial direct current stimulation

A Case Report on Red Ear Syndrome with Tinnitus Successfully Treated with Transcranial Random Noise Stimulation

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