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Contemporary treatments for hyperfunctional voice disorders such as muscle tension dysphonia (MTD) are effective but typically do not restore voice handicap or voice function to normal thresholds. Recent reports of vibration as a voice therapy modality have been published, but many questions remain about the efficacy of this tool. The current project addresses these problems through a blinded and randomized controlled trial to investigate the efficacy of local translaryngeal vibration for MTD and the dose-response relationship of this modality when compared to treatment without vibration.
Vocal hyperfunction (VH) is the most commonly treated class of voice disorders by speech-language pathologists and voice therapy is the primary curative treatment. Patients and clinicians report that generalizing improved voicing into daily life is the most significant barrier to successful therapy. We will test if extending biofeedback into the patient's daily life using ambulatory voice monitoring will significantly improve generalization during therapy and if individual patient factors, like how easily they can modify their voice and engagement during therapy, moderate the effects of the biofeedback.
The contribution of genetic risk factors to the development of focal dystonias is evident. However, understanding of how variations in the causative gene expression lead to variations in brain abnormalities in different phenotypes of dystonia (e.g., familial, sporadic) remains limited. The research program of the investigators is set to determine the relationship between brain changes and genetic risk factors in laryngeal dystonia (or spasmodic dysphonia). The researchers use a novel approach of combined imaging genetics, next-generation DNA sequencing, and clinical-behavioral testing. The use of a cross-disciplinary approach as a tool for the discovery of the mediating neural mechanisms that bridge the gap from DNA sequence to the pathophysiology of dystonia holds a promise for the understanding of the mechanistic aspects of brain function affected by risk gene variants, which can be used reliably for the discovery of associated genes and neural integrity markers for this disorder. The expected outcome of this study may lead to better clinical management of this disorder, including its improved detection, accurate diagnosis, and assessment of the risk of developing dystonia in family members.