View clinical trials related to EEG.
Filter by:Concept of action simulation; It is an internal representation of motor programs that does not involve explicit movement. Motor imagery method (MI) or movement observation (HG) method are considered two separate action simulation methods that activate motor regions in the brain. Both methods remain a popular and effective tool for improving motor learning. Research has shown that clinicians working in rehabilitation settings are aware of the needs of patients, athletes, etc. are recommended as methods that participants can use to improve their motor skills. Motor imagery training is a dynamic mental process in which a movement is mentally visualized without any visible movement or any voluntary motor muscle activation. Movement observation training is a method that involves internal, real-time motor simulation of movements in which the observer visually perceives movements performed by another. Mirror neurons, located primarily in the rostral part of the inferior parietal lobe and the ventral premotor cortex, are activated both when an action is physically performed and when the action is observed being performed by another person. Studies using neuroimaging techniques have provided support for this theory by showing that many areas known to be active during action simulation, such as the dorsal pre-motor cortex, supplementary motor area, superior parietal lobe, and intraparietal sulcus, are indeed active during both HG and MI. There is evidence in the literature that MI and HG also trigger sympathetic nervous system activation. There may be changes in respiration, heart rate and skin temperature, as well as an increase in electrodermal activity. EEG is an inexpensive, noninvasive, and simple examination that can be used to evaluate neurophysiological functions by measuring electrical activity. Understanding the mechanism of beta rhythms is important because they are associated with conscious thinking, logical thinking, memory and problem solving, whereas suppression of beta waves contributes to depression and cognitive decline. This study will investigate the effectiveness of exercising or watching or imagining exercise on brain functions.
In this randomized double-blind trial, we investigated whether externally induced left-hemispheric frontoparietal theta synchronization by multi-electrode online theta (6Hz) transcranial alternating current stimulation (tACS) would enhance the influence of a working memory training on negative symptoms of schizophrenia.
In the world, 230 million surgeries are performed per year and a significant part is performed in patients over 65 years of age. These patients are more labile, especially from the neurocognitive point of view with a high risk to develop neurocognitive complications, such as postoperative delirium. Recent studies have linked this type of complication with an overdose of general anesthetics during surgery. For this reason, in recent years, the use of brain function monitors during the intraoperative period has been recommended to adapt the dosage of the drugs to each patient and thus to avoid overdosing of general anesthetics. However, to date, the available monitors that process the electroencephalographic signal are not able to adequately discriminate gradual changes in anesthetic depth. Also, no systematic studies have been performed that analyze changes that occur in the electroencephalogram (EEG) signal secondary to increases in complications from general anesthetics. Thus, the investigators design this study with the main aim to determine the changes in electroencephalographic patterns induced by a stepped increase of propofol until the burst suppression is reached.
Electroencephalographic recordings (EEG) present an opportunity to monitor changes in human brain electrical activity during changing states of consciousness during general anesthesia. The investigators aim to determine if EEG-guided anaesthesia using the Masimo Sedline Root monitor will result in different anaesthetic requirements, different anaesthetic depth, and emergence characteristics in children under 16 years of age. 200 children under 16 years undergoing routine general anaesthesia under sevoflurane will be randomized to either EEG monitoring or routine care. We will compare the anaesthetic requirements, the patient state index, number of episodes of burst suppression and the incidence and severity of emergence delrium between the two groups.
The main objective of this project is: 1. To assess the influence of physical fatigue on brain functioning during a balance and reaction time task in a healthy population. In a later stage, these experiments could be carried out in a clinical context (e.g. in an ankle sprain population). The researchers will use a randomized, placebo controlled, counter-balanced, cross-over design. Twenty healthy subjects will visit the lab 3 times. On the first visit (familiarisation trial), the investigators will collect the participants' characteristics. The participants will also be familiarized to the procedures and materials of the experiment during this first visit. The second and third visit contain the experimental setup and will proceed as follows: first, the participants will fill in a pre-test checklist, a mental fatigue scale (M-VAS) and motivation scale. In the mean time a little blood will be collected from the ear lobe to determine lactate and glucose levels; also, blood pressure will be checked. Next, the subjects will carry out a Y-balance test and a balance reaction-time test. Session rate of perceived exertion (SRPE) is measured to indicate how fatigued the participants feel due to the test battery; also, M-VAS is collected once more, as well blood lactate, glucose and blood pressure. These measures are followed by either a physical fatigue inducing task (Modified 30 seconds Wingate protocol) or time-matched control task (sitting on the bike without pedalling). Afterwards, researchers will collect blood lactate, glucose and blood pressure two times more; participants have to fill in M-VAS (2x), perform the same Y-balance test and balance reaction time test, and fill in the SRPE scale one more time. Heart frequency and EEG will be measured continuously during the trials.
Objective of the study The main objectives of this project are: 1. To assess the influence of mental fatigue on a return-to-play test battery in healthy population 2. To assess the influence of mental fatigue on brain functioning during a balance and reaction time task in healthy population In a later stage, these experiments could be carried out in a clinical context (e.g. in an ankle sprain population). The researchers will use a randomized, placebo controlled, counter-balanced, cross-over design. Thirteen healthy subjects will visit the lab 3 times. On the first visit (familiarisation trial), the investigators will collect the participants' characteristics. The participants will also be familiarized to the procedures and materials of the experiment during this first visit. The second and third visit contain the experimental setup and will proceed as follows: first, the participants will fill in a mental fatigue scale (M-VAS) and motivation scale. Next, the subjects will carry out a functional test battery (hop test, vertical jump test, Y-balance test, and a balance reaction-time test). Session rate of perceived exertion (RPE) is measured to indicate how fatigued the participants feel because of the test battery; also, M-VAS is collected once more. Then, a short cognitive task (Flanker task) is followed by either a long intensive cognitive task (90 minutes Stroop task) or control task (90 minutes documentary). Afterwards, participants have to carry out the Flanker task, fill in M-VAS (2x), perform the same test battery, fill in session RPE and one final fatigue scale (Nasa TLX). Heart frequency and EEG will be measured continuously during the trials.
The goal of this study is to monitor the brain using electroencephalography (EEG) while transcranial direct current stimulation (tDCS) is being administered, as a potential pathway to determine neurophysiological markers capable of forecasting the intensity of a subject's response to tDCS.