Abstract
Stuttering is a neurodevelopmental disorder characterized by impaired production of coordinated articulatory movements needed for fluent speech. It is currently unknown whether these abnormal production characteristics reflect disruptions to brain mechanisms underlying the acquisition and/or execution of speech motor sequences. To dissociate learning and control processes, we used a motor sequence learning paradigm to examine the behavioral and neural correlates of learning to produce novel phoneme sequences in adults who stutter (AWS) and neurotypical controls. Participants intensively practiced producing pseudowords containing non-native consonant clusters (e.g., "gvasf") over two days. The behavioral results indicated that although the two experimental groups showed comparable learning trajectories, AWS performed significantly worse on the task prior to and after speech motor practice. Using functional magnetic resonance imaging (fMRI), the authors compared brain activity during articulation of the practiced words and a set of novel pseudowords (matched in phonetic complexity). FMRI analyses revealed no differences between AWS and controls in cortical or subcortical regions; both groups showed comparable increases in activation in left-lateralized brain areas implicated in phonological working memory and speech motor planning during production of the novel sequences compared to the practiced sequences. Moreover, activation in left-lateralized basal ganglia sites was negatively correlated with in-scanner mean disfluency in AWS. Collectively, these findings demonstrate that AWS exhibit no deficit in constructing new speech motor sequences but do show impaired execution of these sequences before and after they have been acquired and consolidated.
Highlights
Stuttering is a neurodevelopmental disorder affecting children into adulthood with devastating social effects that impede speech communication
FMRI analyses revealed no differences between adults who stutter (AWS) and controls in cortical or subcortical regions; both groups showed comparable increases in activation in left-lateralized brain areas implicated in phonological working memory and speech motor planning during production of the novel sequences compared to the practiced sequences
Our first set of analyses examined, at the behavioral level, whether participants showed evidence of incremental speech motor sequence learning over the course of the training phase by examining the time course of improvement in each of the three performance measures—mean error rates, utterance durations, and reaction time (RT)—over the two days of speech motor practice
Summary
Stuttering is a neurodevelopmental disorder affecting children into adulthood with devastating social effects that impede speech communication. The presenting clinical signs of the disorder include involuntary repetitions and prolongations of phonemes, syllables, or words, as well as involuntary silent pauses (Bloodstein & Ratner, 2008). Researchers still have a relatively poor understanding of the neural deficits underlying the disorder (see CraigMcQuaide et al, 2014, for a review). Neural correlates of speech motor sequence learning. Motor sequence learning: Learning how to plan and execute an appropriate order of discrete actions. Motor chunks: Cohesive action units composed of frequently occurring subsequences of movements. Functional magnetic resonance imaging (fMRI): Imaging that measures changes in blood oxygenation levels that occur in response to neural firing, allowing precise localization of brain activity. Consonant clusters: Consonant sequences at the start or end of a syllable
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