This study aims to understand how people use different types of feedback to control their speech. When an individual speaks, the brain relies on several systems at the same time, such as sensory systems that monitor an individuals own voice and the movements of their speech muscles, and a motor system that builds and reads out learned motor patterns. The investigators are studying how these systems work together and how they differ across individuals. Investigators will test 90 adults between 18 and 50 years old, including people who stutter, people with dyslexia, and people with typical speech and reading development. Participants will complete several short speech tasks in which the sounds they hear or the movements of their jaw or larynx are briefly changed. These responses will be used to measure each person's speech motor skills and to estimate the settings of a computer model called "SimpleDIVA," which simulates how the brain controls speech. Participants will also complete an MRI scan so investigators can measure the structure and connectivity of different brain regions. These measures will help investigators understand how individual differences in the brain relate to the speech motor control skills we observe. Participants will also complete sessions with noninvasive brain stimulation (transcranial current stimulation, or tCS) to examine how stimulation of specific areas of the brain affects responses during the speech tasks. The knowledge gained from this study will help researchers understand why speech motor skills vary across people and how differences in neural function may contribute to conditions such as stuttering and dyslexia.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
BASIC_SCIENCE
Masking
SINGLE
Enrollment
90
Participants in Arms 1 and 2 will repeat consonant/vowel/consonant (/CVC/) words containing the vowel "eh" between two consonants that they hear over headphones. As they speak, vocal output from the participant will be transduced via a microphone and then played back to the participant over headphones at an undetectable delay. On a subset of (perturbed) trials, F0 or F1 in the auditory feedback presented to the participant will be shifted relative to their vocal output. On the remaining (baseline) trials, auditory feedback will be unaltered. During each behavioral session, participants will complete 80 unperturbed trials, 40 trials that involve an F0 perturbation, and 40 trials that involve an F1 perturbation.
Participants in Arms 1 and 2 will repeat /CVC/ words containing the vowel "eh" between two consonants that they hear over headphones. As they speak, vocal output from the participant will be transduced via a microphone and then played back to the participant over headphones at an undetectable delay. On a subset of (perturbed) trials, F0 or F1 in the auditory feedback presented to the participant will be shifted relative to their vocal output. On the remaining (baseline) trials, auditory feedback will be unaltered. During each session, participants will complete 50 unperturbed trials, 50 trials that involve an F0 perturbation, and 50 trials that involve an F1 perturbation.
Participants in Arms 1 and 2 will repeat /CVC/ words containing the vowel "eh" between two consonants that they hear over headphones. As they speak, vocal output from the participant will be transduced via a microphone and then played back to the participant over headphones at an undetectable delay. Over the course of each protocol, the first formant (F1) in the auditory feedback presented to the participant will be shifted relative to their vocal output. Trials will be organized in four phases: an initial baseline phase in which auditory feedback is unaltered, a ramp phase over which the formant of auditory feedback is gradually shifted to a maximum level, a hold phase in which the feedback shift is held at its maximum level, and then an after-effect phase in which feedback returns to normal. Four trials will be performed in each phase.
Participants in Arm 1 and 2 will repeat /CVC/ words containing the vowel "eh" between two consonants that they hear over headphones. As they speak, vocal output from the participant will be transduced via a microphone and then played back to the participant over headphones at an undetectable delay. As they speak the fundamental frequency (F0) in the auditory feedback presented to the participant will be shifted relative to their vocal output. Trials will be organized in four phases: an initial baseline phase in which auditory feedback is unaltered, a ramp phase over which the formant of auditory feedback is gradually shifted to a maximum level, a hold phase in which the feedback shift is held at its maximum level, and then an after-effect phase in which feedback returns to normal.
Participants in Arms 1 and 2 will repeat /CVC/ words containing the vowel "eh" between two consonants that they hear over headphones. While they speak, speech-shaped masking noise will be presented to participants at 85 dB. On a subset of trials (word productions), movements of the jaw will be perturbed (restricted) by the rapid inflation of a balloon placed between the upper and lower teeth shortly after voice onset. On another subset of trials, the position of the larynx will be perturbed by the rapid inflation of a balloon placed against the laryngeal prominence. During the remaining (unperturbed) trials, both balloons will remain deflated.
Participants in Arm 1 will receive continuous anodal tCS targeting posterior superior temporal gyrus (pSTG) during a 20-minute reflexive auditory feedback task during one session and stimulation targeting ventral somatosensory cortex (vSSC) during the same task in another session. The tCS stimulation will ramp up to its maximum value (2 milliamperes) over the first 30 s of the session and will be maintained at that level throughout the remainder of the session.
Participants in Arm 2 will receive continuous anodal tCS targeting left ventral premotor cortex (vPMC) during a 20-minute reflexive auditory feedback task during one session and stimulation targeting right vPMC during the same task in another session. The tCS stimulation will ramp up to its maximum value (2 milliamperes) over the first 30 s of the session and will be maintained at that level throughout the remainder of the session.
Participants in Arm 1 will receive Sham tCS stimulation targeting the pSTG or vSSC during a 20-minute reflexive auditory feedback task. During the minute prior to training onset, the tCS stimulator will ramp up to 2 milliamperes and then back down to 0 for the remainder of the session.
Participants in Arm 1 will receive Sham tCS stimulation targeting left or right vPMC during a 20-minute reflexive auditory feedback task. During the minute prior to training onset, the tCS stimulator will ramp up to 2 milliamperes and then back down to 0 for the remainder of the session.
Boston University
Boston, Massachusetts, United States
Reflexive compensatory response
The amount of compensation to induced F0 and F1 perturbations will be calculated by finding the maximum deviation of the perturbed variable (F0 or F1) from baseline, dividing it by the perturbation size, and then averaging that across all trials of that perturbation.
Time frame: Day 1 and Day 2
Adaptive compensatory response
The adaptive compensatory response to persistent F0 and F1 perturbations will be calculated by subtracting the mean F0/F1 from the baseline phase from the mean during the after-effect phase, then dividing by the perturbation size to obtain percent adaptation.
Time frame: Day 1 and Day 2
Stuttering Severity
The composite score of the Stuttering Severity Instrument, 4th Edition, and the frequency of stuttering-like dysfluencies will be used to identify correlations between stuttering severity and other outcome measures in persons who stutter.
Time frame: Baseline
Dyslexia Severity
A mean composite score from subtests of the Test of Word Reading Efficiency and the Woodcock Reading Mastery Test will be used to identify correlations between dyslexia severity and other outcome measures in persons with dyslexia.
Time frame: Baseline
Verbal and Nonverbal Intelligence
The composite score from the Kaufman Brief Intelligence Test for each participant will be used to identify correlations between intelligence and other outcome measures.
Time frame: Baseline
Receptive Vocabulary
The score from the Picture Vocabulary Test (PVT) from the NIH Toolbox for each participant will be used to identify correlations between receptive vocabulary and other outcome measures.
Time frame: Baseline
Brain region volume
Volume (mm\^3) will be extracted for subcortical regions of interest (ROIs). ROIs will be delineated and volume measures extracted using FreeSurfer's standard structural MRI processing pipeline.
Time frame: Day 2
Brain region area
Area (mm\^2) will be extracted for cortical regions of interest (ROIs). ROIs will be delineated and area measures extracted using FreeSurfer's standard structural MRI processing pipeline.
Time frame: Day 2
Brain region cortical thickness
Cortical thickness (mm) will be extracted for cortical regions of interest (ROIs). ROIs will be delineated and cortical thickness extracted using FreeSurfer's standard structural MRI processing pipeline.
Time frame: Day 2
Brain region cortical gyrification
Local gyrification index (a unitless measure of the ratio of pial surface and external surface in an area) will be extracted for cortical regions of interest (ROIs). ROIs will be delineated and cortical thickness extracted using FreeSurfer's standard structural MRI processing pipeline.
Time frame: Day 2
Brain region functional connectivity
Functional connectivity between pairs of brain ROIs will be estimated from resting state functional MRI using the CONN functional connectivity toolbox.
Time frame: Day 2
Brain region structural connectivity
Structural connectivity between pairs of brain ROIs will be estimated from diffusion-weighted MRI using components of the FSL Diffusion Toolbox and the MRtrix software package.
Time frame: Day 2
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