The primary aims of this research project are (1) to further refine and test a neural model of the brain interactions underlying learning and production of speech sounds called the DIVA model, (2) to develop and test a novel computational model of spasmodic dysphonia based on this model.
These aims will be pursued by combining neuroimaging, computational modeling, and large-sample data analysis to investigate fluent and disordered speech production. The proposed studies focus on the interactions between cortical (motor, auditory, and somatosensory) and subcortical (cerebellum, basal ganglia, and thalamus) structures during feedforward and feedback speech motor control processes. The findings from this research will be integrated into a single, improved version of the DIVA model, ensuring a unified theoretical account. This model will be implemented in computer software and simulated on the same tasks as speakers in associated functional magnetic resonance imaging (fMRI) experiments. Primary Aim 1 is addressed by two studies that seek to improve the mapping between functional modules in the DIVA model and neural substrates. In the first study, functional magnetic resonance imaging (fMRI) and diffusion tensor imaging (DTI) will be used to differentiate the contributions of distinct cerebellar regions to speech motor control. Findings will be used to improve the representation of cerebellar regions in the DIVA model. In the second study, functional and anatomical data pooled from several previous studies will be used to provide a highly reliable assessment of brain regions involved in different aspects of speech as well as the variability in these regions across the population. This information will be used to improve neuroanatomical localization of speech mechanisms in the DIVA model and to create a neuro-mechanistic atlas that relates speech motor processes to precisely defined anatomical locations. Primary Aim 2 is addressed by two studies designed to improve our understanding of the neural mechanisms underlying the voicing disorder spasmodic dysphonia (SD). First, a model of vocal fold dynamics will be incorporated within the DIVA model, and simulations of voicing and stress control will be performed to verify model performance. Second, fMRI and DTI will be used in combination with the SD model to test several hypotheses concerning the primary pathophysiology in SD and differentiate it from secondary consequences of the disorder. This project's approach of integrating large-scale neural network modeling and neuroimaging will provide a clearer, more mechanistic account of the neural processes underlying normal and dysfluent speech. The findings from this project will help guide speech language pathologists to make more informed decisions about possible therapies or drug treatments to apply to patients with SD or other speech motor disorders and, in the longer term, guide development of new therapies and treatments for these patients.
This project will improve our understanding of how the brain controls speech production and how this control is disrupted in spasmodic dysphonia. The outcome of this research is expected to significantly accelerate the development of treatments for voicing and other speech motor disorders, which would profoundly impact the quality of life of millions of people.
|Terband, H; Maassen, B; Guenther, F H et al. (2014) Auditory-motor interactions in pediatric motor speech disorders: neurocomputational modeling of disordered development. J Commun Disord 47:17-33|
|Guenther, Frank H (2014) Auditory feedback control is involved at even sub-phonemic levels of speech production. Lang Cogn Process 29:44-45|
|Civier, Oren; Bullock, Daniel; Max, Ludo et al. (2013) Computational modeling of stuttering caused by impairments in a basal ganglia thalamo-cortical circuit involved in syllable selection and initiation. Brain Lang 126:263-78|
|Niziolek, Caroline A; Guenther, Frank H (2013) Vowel category boundaries enhance cortical and behavioral responses to speech feedback alterations. J Neurosci 33:12090-8|
|Golfinopoulos, Elisa; Tourville, Jason A; Bohland, Jason W et al. (2011) fMRI investigation of unexpected somatosensory feedback perturbation during speech. Neuroimage 55:1324-38|
|Patel, Rupal; Niziolek, Caroline; Reilly, Kevin et al. (2011) Prosodic adaptations to pitch perturbation in running speech. J Speech Lang Hear Res 54:1051-9|
|Golfinopoulos, E; Tourville, J A; Guenther, F H (2010) The integration of large-scale neural network modeling and functional brain imaging in speech motor control. Neuroimage 52:862-74|
|Bohland, Jason W; Bullock, Daniel; Guenther, Frank H (2010) Neural representations and mechanisms for the performance of simple speech sequences. J Cogn Neurosci 22:1504-29|
|Civier, Oren; Tasko, Stephen M; Guenther, Frank H (2010) Overreliance on auditory feedback may lead to sound/syllable repetitions: simulations of stuttering and fluency-inducing conditions with a neural model of speech production. J Fluency Disord 35:246-79|
|Brumberg, Jonathan S; Nieto-Castanon, Alfonso; Kennedy, Philip R et al. (2010) Brain-Computer Interfaces for Speech Communication. Speech Commun 52:367-379|
Showing the most recent 10 out of 30 publications