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Clinical Trial Summary

In motor learning, it is essential to consider that movements are produced by the cooperation and combination of many brain structures and are influenced by the emotions to which individuals are subjected. Several neural circuits have been identified that closely link the emotional system and the motion control system. Stress is a physiological or psychological response to internal or external stressors. In principle, it has an adaptive role. However, the neuroendocrine and autonomic response generated by stress can affect cognitive processes such as memory. In addition, it has been shown to influence motor learning, especially the execution of skills in the early stages of learning. Understanding how movement, emotions and interactions are regulated is significant because of the large number of movements humans perform. Of these, manual tasks represent precise movements that require the integration of many elements by the nervous system to perform these tasks successfully. It is still unknown how acute stress influence the way manual tasks are learned. On the other hand, motor imagery (MI) is a cognitive process that is an important contributor to how movements are planned and executed. Its use has been recommended to improve movement learning and task execution. For an MI program to be effective and individualized, it is imperative to know this ability. However, it is also still unknown how acute stress can affect our motor imagery ability. The main objective of this study is to determine and quantify the effects of acute stress in the learning of a precise manual task not previously trained on four parameters of fine motor control: trajectory error, timing error, timing accuracy, and task accuracy. On the other hand, the aim is to determine if the capacity of internal visual, external visual, and kinesthetic imagery, and the temporal congruence between movement execution and imagery varies when we are subjected to acute stress. It is expected that non-anxious, non-stressed participants who are not induced with acute stress will show better motor performance on the fine motor task and better motor imagery ability and temporal congruence. In contrast, it is expected that participants without anxiety and stress who are induced with acute stress will show poorer motor performance on the fine motor task, and poorer motor imagery ability and temporal congruence.


Clinical Trial Description

In order to meet the study objectives of determining and quantifying the effects of acute stress on learning a precise manual task and on motor imagery ability, this study will be conducted. The development of the study will take place in a conditioned room belonging to the University of Alcalá, the Complutense University of Madrid, the European University of Madrid, or Claude Bernard University Lyon 1. The study may also be carried out in other Spanish and international university centers, subject to the consent and permission of the respective centres. The study will be carried out by all national and international laws, regulations, and recommendations. The study design will be longitudinal, experimental, randomized, and double-blind, as specified in the present registry. The study population will be composed of participants who are undergraduate and postgraduate students at the university centers where the study will be carried out, from which they will be recruited. All participants included in the study must meet the study selection criteria and participate voluntarily after reading the information sheet and signing the informed consent form. The study will consist of two intervention groups, in which the Maastricht Acute Stress Test (MAST) protocol will be performed: one group will perform the acute stress induction protocol (MAST stress) and the other group will perform the no stress induction control protocol (MAST control). Each group will consist of a minimum number of 30 subjects to be able to study the desired effect. After each participant freely chooses to participate in the study, an initial questionnaire will be administered to ensure that they meet the criteria for inclusion in the study. At this point, they will be coded by assigning them a number, which will serve to identify each participant throughout the study. Participants will take the State-Trait Anxiety Inventory (STAI), one of the most widely used instruments for the self-reported assessment of anxiety and equivalent to a measure of stress, as it considers the amount of stressful stimulus. Thus, the two components of anxiety will be assessed: state anxiety and trait anxiety. Participants with scores indicative of state or trait anxiety will be excluded from the study, and those with scores indicating neither trait anxiety nor state anxiety will be included. Included participants will be randomized through sealed envelopes stratified by gender to one of two experimental groups: MAST stress, or MAST control. They will also take the Edinburgh Handedness Inventory (EHI) to determine the participant's laterality, and the Movement Imagery Questionnaire-3 (MIQ-3) to measure internal visual, external visual, kinaesthetic imagery capacity. At the same time of MIQ-3, the experimenter will record the execution and imagery times were recorded (for subsequent calculation of the time discrepancy between executed and imagery as a measure of temporal congruence between them). Depending on the group to which they have been assigned, they will perform the corresponding MAST protocol (stress or control). MAST stress is a non-invasive protocol to induce acute stress in the laboratory that combines components of psychological stress (evaluative social threat, uncontrollability, and unpredictability) and physical stress (sensation of pain through intense cold). The MAST control is a homologous protocol to the stress protocol but has no psychological or physical stressor components. After MAST protocol, participants will learn a precise manual task with the non-dominant hand. The task will consist of going over a 127 mm circumference on a graphics tablet at a rate of 2 seconds per lap, which will be set by a metronome using a wireless pen that will leave no trace of ink but will store the data in the MATLAB program via the graphics tablet. Thus, data from the acquisition and short-term retrieval of the task will be recorded. Afterward, there will be a 20-minute break during which participants will perform the MIQ-3 and the experimenter will record the execution and imagery times again. Finally, the task data will be collected to record the long-term retrieval of the manual task. In addition, during all experiments, electrodermal activity and heart rate variability will be recorded using the Empatica E4 physiological variable measurement wristband. This measurement of physiological variables will serve to confirm that a significant emotional effect has been generated and to test motor imagery processes since both acute stress and motor imagery produce activation of the autonomic nervous system. The analysis and processing of data from MATLAB version R2020b, and the Empatica E4 wristband will be performed using RStudio software and Kubios HRV software (for HRV analysis). First, appropriate statistical analyses will be performed to see if the data are distributed according to a standard curve through the Shapiro-Wilk test and to assess the influence of sex and age. Subsequently, the descriptive analysis of the relative and absolute frequencies for the qualitative variables of gender and age will be carried out, and their homogeneity will be tested using the Chi-square test. The descriptive analysis of the quantitative variables of trajectory error, timing error, timing accuracy, task accuracy, electrodermal activity, heart rate variability, kinaesthetic, internal visual, and external visual imagery, and discrpenacy times will also be carried out. If the variable conforms to the normal, the mean, range, and standard deviation shall be calculated. If it does not conform to the normal, non-parametric tests will be performed. Comparative analysis will be performed using mixed ANOVA to see the differences in the mean values respective to motor control (trajectory error, timing error, timing accuracy, and task accuracy). A further ANOVA analysis will take place for imagery ability and discrepancy times, comparing the results obtained at the two respective points during the experiment. The effect of learning between laps will be analyzed by repeated-measures ANOVA comparing each motor control measurement parameter with respect to the lapping factor. Electrodermal activity, and heart rate variability during the measurement of imagery ability, emotional state induction, manual task acquisition, and its retrieval in the short and long term will also be studied by repeated-measures ANOVA. For hypothesis testing, a significance level of 0.05 will be set. ;


Study Design


Related Conditions & MeSH terms


NCT number NCT04912713
Study type Interventional
Source University of Alcala
Contact
Status Completed
Phase N/A
Start date June 14, 2021
Completion date September 30, 2022

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