Effects of Neuromodulation in Laryngeal Dystonia

Focal Dystonia Clinical Trial

Official title:

The Effects of Neuromodulation on Phonatory Function in Laryngeal Dystonia

Clinical Trial Details — Status: Recruiting

Administrative data

• NCT number: NCT05095740
• Other study ID #: 2020P003531
• Secondary ID: K24DC018603
• Status: Recruiting
• Phase: N/A
• Start date: June 10, 2021
• Est. completion date: May 31, 2026

Study information

• Verified date: September 2023
• Source: MGH Institute of Health Professions
• Contact: Caitlin Koehler, Lab Manager
• Phone: 617-643-6564
• Email: brainrecoverylab[@]mghihp.edu
• Is FDA regulated: No
• Study type: Interventional

Clinical Trial Summary

Laryngeal dystonia (LD) causes excessive vocal fold abduction (opening) or adduction (closing) leading to decreased voice quality, job prospects, self-worth and quality of life. Individuals with LD often experience episodic breathy voice, decreased ability to sustain vocal fold vibration, frequent pitch breaks and in some cases, vocal tremor. While neuroimaging investigations have uncovered both cortical organization and regional connectivity differences in structures in parietal, primary somatosensory and premotor cortices of those with LD, there remains a lack of understanding regarding how the brains of those with LD function to produce phonation and how these might differ from those without LD. Intervention options for people with LD are limited to general voice therapy techniques and Botulinum Toxin (Botox) injections to the posterior cricoarytenoid (PCA) and/or TA (thyroarytenoid) often bilaterally, to alleviate muscle spasms in the vocal folds. However, the effects of injections are short-lived, uncomfortable, and variable. To address this gap, the aim of this study is to investigate the effectiveness of repetitive transcranial magnetic stimulation (rTMS), a non-invasive neuromodulation technique, in assessing cortical excitability and inhibition of laryngeal musculature. Previous work conducted by the investigator has demonstrated decreased intracortical inhibition in those with adductor laryngeal dystonia (AdLD) compared to healthy controls. The investigators anticipate similar findings in individuals with with other forms of LD, where decreased cortical inhibition will likely be noted in the laryngeal motor cortex. Further, following low frequency (inhibitory) rTMS to the laryngeal motor brain area, it is anticipated that there will be a decrease in overactivation of the TA muscle. To test this hypothesis, a proof-of-concept, randomized study to down-regulate cortical motor signal to laryngeal muscles will be compared to those receiving an equal dose of sham rTMS. Previous research conducted by the investigator found that a single session of the proposed therapy produced positive phonatory changes in individuals with AdLD and justifies exploration in LD.

Description:

The cause of LD is largely unknown and there are no treatments that produce long-term benefits. The investigators' long-term goal is to elucidate the pathophysiology of laryngeal dystonia as a crucial step towards the development of sensitive testing and novel interventions to treat this devastating disease. Neuroimaging studies have suggested that LD is associated with abnormal patterns of activation and excessive plasticity in sensorimotor areas in the brain, however, an understanding of the cortical excitability in this disorder is lacking. This information is important because it provides a more comprehensive understanding of the pathophysiology of the disorder, opening potential investigation into novel tests or treatments. The investigators have begun to address this gap in knowledge by developing a novel transcranial magnetic stimulation (TMS) paradigm to assess intracortical excitability and inhibition of targeted laryngeal muscles. Although similar paradigms have been fruitful for explicating the neural mechanisms of dystonia in the limbs, to our knowledge TMS has not been used to assess pathophysiology in laryngeal dystonia, thus similarities and differences in brain state between the limb and laryngeal dystonias could not be assessed. The investigators' current NIDCD project (R01DC015216) with which this proposed project synergizes, uses TMS and functional neuroimaging in people with LD and focal hand dystonia to determine the brain excitability and connectivity, distinctive of, and common to the two disorders. This approach is based on the investigators' recently completed NIDCD grant (R21DC012344) which supported the development of a valid and reliable TMS method to determine the cortical representation and excitability of the thyroarytenoid, a muscle affected in LD. Utilizing this approach, the investigators have recently demonstrated that people with LD have reduced intracortical inhibition compared to healthy controls. These results provide a compelling basis for the clinical application of this finding to determine if an intervention that increases intracortical inhibition can produce clinical improvements.

Aim 1: Determine the phonatory effects of 5-days of daily rTMS vs sham in people with LD. The effects of rTMS on phonatory function will be measured using (a) auditory-perceptual assessment (b) acoustic analysis including smoothed cepstral peak prominence (CPPS) of running speech and sustained vowel, and (c) patient self-ratings of vocal effort (response to voice demand). (H1) The investigators will observe large favorable intervention effect sizes in measures of phonatory function following rTMS compared to sham.

Aim 2: Determine the neurophysiologic changes associated with 5 days of rTMS vs sham in people with LD. The intervention effects on TMS-measured neurophysiology including intracortical excitatory and inhibitory measures from the laryngeal motor cortex will be assessed pre and post intervention. (H2) The investigators will observe significant decreases in cortical excitability [motor evoked potential (MEP)] and/or increases in inhibition [cortical silent period (cSP)] following rTMS compared to sham.

Aim 3: Explore characteristics associated with responders vs non-responders to rTMS in people with LD. This exploratory aim will stratify participants as responders or non-responders based on each person's acoustic (CPPS) changes. A multivariate regression will explore factors associated with positive response to intervention. (H3) Certain factors such as age, time since symptom onset, clinical severity, and/or baseline cortical excitability and inhibition will be associated with treatment responsiveness.

Procedures: Qualified participants will provide informed consent and receive on-site screening to determine eligibility. On Day 1, baseline (Pre) acoustic, perceptual and patient-reported assessments of voice production and TMS-measured neurophysiology will be performed. Participants will then receive the first rTMS intervention. On Day 2, 3 and 4, participants will receive rTMS (real or sham) intervention solely, with no testing. On Day 5, the same acoustic, perceptual, patient-reported and neurophysiologic assessments will be performed after rTMS intervention. At least 3 months after Post1, participants will cross-over to receive the other intervention (rTMS or Sham). The timing of the assessments in the cross-over phase of the experiment, Pre2 and Post2, will mirror the timing of Pre1 and Post1 in the first phase.

TMS Neurophysiology Assessment. Participants will have the vocalization area tested. Topical anesthesia will first be applied to the anterior neck skin followed by a superficial injection of 1% lidocaine with 1:100,000 epinephrine. The target muscles are bilateral TA muscles. A 30 mm, 27 gauge needle loaded with a pair of fine-wire hooked electrodes will be inserted into each TA muscle by an experienced otolaryngologist following standard procedures for laryngeal EMG. Using a percutaneous approach, the needle will be passed through the cricothyroid membrane at an angle off midline but medial to the ipsilateral inferior tubercle, to directly enter the TA muscle while avoiding the airway. During insertion, the electrodes are connected to an audio monitor to monitor muscle activity in real-time during placement. After the TA placement is confirmed, the needle is removed leaving the fine-wires in the TA muscles. The two pairs of fine-wire electrodes will be connected to the amplifier and acquired with the same setup that are reported in the investigators' previous study. electrode locations will be confirmed by increased EMG activity with sustained phonation and Valsalva maneuver. The TMS testing intensity threshold will be determined by finding the minimum intensity required to elicit a cortical silent period (cSP) during constant phonation of /i/ (to elicit contraction from the TA muscles) as a measure of cortical inhibition. The TMS 'hotspot' will be the corresponding location on the cortex when cSP is induced with the TMS testing intensity threshold. TMS hotspot location and 30 trials of fine-wire electrodes electromyogram (EMG) cSP response from TA muscle will be recorded. The cSP reflects GABAB receptor mediated inhibitory processes within cortical motor areas. Ten trials motor evoked potential (MEP) will also be evoked with the participants as rest as a measure of cortical excitability. EMG area under the curve will be calculated for a time-equivalent period of pre-stimulus activity. A frameless stereotactic neuro-navigation system will be used to enhance the reliability and recording of stimulus locations. To ensure safety, an investigator will screen each participant to determine appropriateness for TMS and that all safety parameters are met. Processing will occur according to previously published methods. The investigator performing the excitability assessment will be blind to group designation.

rTMS. Inhibitory (1 Hz) rTMS (1200 pulses, biphasic waveform) will be delivered to the same left hemisphere laryngeal motor cortical 'hotspot' established with the TMS testing on Day 1. The left laryngeal cortex was selected due to the bilateral nature of control of the laryngeal muscles, and findings of no difference between left and right sided cSP. Neuronavigation (Brainsight®, Rogue Research Inc. Quebec, Canada) will be used to enhance rigor by tracking stimulation location in the cortex and coil position as the stimulation target. Subject will receive approximately 20 minutes of FDA-approved rTMS treatment at 0.9 x resting motor threshold at 1 Hz with a 70-mm figure-eight TMS coil connected to 5Magstim rapid magnetic stimulator. This treatment is within the range for total pulses performed in previous studies in subjects with other dystonias in a single day. The same target will be used for the rTMS intervention over the 5 days and for the post-intervention assessments. Sham rTMS stimulation will be delivered with a sham coil that produces similar sound and sensory stimulation to the scalp but does not deliver a stimulating pulse. Sham stimulation will help deter mine whether the changes following rTMS are due to placebo effect.

Recruitment information / eligibility

• Status: Recruiting
• Enrollment: 60
• Est. completion date: May 31, 2026
• Est. primary completion date: May 2025
• Accepts healthy volunteers: Accepts Healthy Volunteers
• Gender: All
• Age group: 21 Years to 85 Years

Eligibility

Inclusion Criteria:

• Age range is 21-85 years

• Diagnosis of Laryngeal Dystonia (LD)

• Subject is able to give informed consent

• Symptoms at worst severity if receiving botulinum toxin injections

• Subject has signed the consent form

Exclusion Criteria:

• Other forms of dystonia

• Vocal fold pathology or paralysis

• Essential tremor

• Laryngeal cancer or other neurologic conditions with medications affecting the central nervous system

• History of laryngeal surgery

• Adults lacking the ability to consent or complete the assessments and intervention

• Seizure in the last 2 years

• Contraindications to rTMS

Related Conditions & MeSH terms

• Dysphonia
• Dystonia
• Dystonic Disorders
• Focal Dystonia
• Laryngeal Dystonia

Intervention

Device:
• repetitive transcranial magnetic stimulation (rTMS)
Repetitive transcranial magnetic stimulation used to regulate the contribution of the laryngeal motor cortex to voice production and laryngeal motor muscle activation.
• sham rTMS
Repetitive transcranial magnetic stimulation used to a cortical area not associated with change in outcomes at an intensity substantially lower than that of the established threshold.

Locations

Country	Name	City	State
United States	Teresa J Kimberley	Boston	Massachusetts

Sponsors (2)

Lead Sponsor	Collaborator
MGH Institute of Health Professions	National Institute on Deafness and Other Communication Disorders (NIDCD)

Country where clinical trial is conducted

United States, 

References & Publications (16)

Ali SO, Thomassen M, Schulz GM, Hosey LA, Varga M, Ludlow CL, Braun AR. Alterations in CNS activity induced by botulinum toxin treatment in spasmodic dysphonia: an H215O PET study. J Speech Lang Hear Res. 2006 Oct;49(5):1127-46. doi: 10.1044/1092-4388(2006/081). — View Citation

Baylor CR, Yorkston KM, Eadie TL. The consequences of spasmodic dysphonia on communication-related quality of life: a qualitative study of the insider's experiences. J Commun Disord. 2005 Sep-Oct;38(5):395-419. doi: 10.1016/j.jcomdis.2005.03.003. — View Citation

Bradnam LV, Stinear CM, Lewis GN, Byblow WD. Task-dependent modulation of inputs to proximal upper limb following transcranial direct current stimulation of primary motor cortex. J Neurophysiol. 2010 May;103(5):2382-9. doi: 10.1152/jn.01046.2009. Epub 2010 Mar 10. — View Citation

Chen M, Deng H, Schmidt RL, Kimberley TJ. Low-Frequency Repetitive Transcranial Magnetic Stimulation Targeted to Premotor Cortex Followed by Primary Motor Cortex Modulates Excitability Differently Than Premotor Cortex or Primary Motor Cortex Stimulation Alone. Neuromodulation. 2015 Dec;18(8):678-85. doi: 10.1111/ner.12337. Epub 2015 Aug 26. — View Citation

Chen M, Summers RL, Goding GS, Samargia S, Ludlow CL, Prudente CN, Kimberley TJ. Evaluation of the Cortical Silent Period of the Laryngeal Motor Cortex in Healthy Individuals. Front Neurosci. 2017 Mar 7;11:88. doi: 10.3389/fnins.2017.00088. eCollection 2017. — View Citation

Chen M, Summers RLS, Prudente CN, Goding GS, Samargia-Grivette S, Ludlow CL, Kimberley TJ. Transcranial magnetic stimulation and functional magnet resonance imaging evaluation of adductor spasmodic dysphonia during phonation. Brain Stimul. 2020 May-Jun;13(3):908-915. doi: 10.1016/j.brs.2020.03.003. Epub 2020 Mar 13. — View Citation

Erickson ML. Effects of voicing and syntactic complexity on sign expression in adductor spasmodic dysphonia. Am J Speech Lang Pathol. 2003 Nov;12(4):416-24. doi: 10.1044/1058-0360(2003/087). — View Citation

Gaskill CS, Awan JA, Watts CR, Awan SN. Acoustic and Perceptual Classification of Within-sample Normal, Intermittently Dysphonic, and Consistently Dysphonic Voice Types. J Voice. 2017 Mar;31(2):218-228. doi: 10.1016/j.jvoice.2016.04.016. Epub 2016 May 27. — View Citation

Hirano M, Ohala J. Use of hooked-wire electrodes for electromyography of the intrinsic laryngeal muscles. J Speech Hear Res. 1969 Jun;12(2):362-73. doi: 10.1044/jshr.1202.362. No abstract available. — View Citation

Lozeron P, Poujois A, Richard A, Masmoudi S, Meppiel E, Woimant F, Kubis N. Contribution of TMS and rTMS in the Understanding of the Pathophysiology and in the Treatment of Dystonia. Front Neural Circuits. 2016 Nov 10;10:90. doi: 10.3389/fncir.2016.00090. eCollection 2016. — View Citation

Ludlow CL, Naunton RF, Terada S, Anderson BJ. Successful treatment of selected cases of abductor spasmodic dysphonia using botulinum toxin injection. Otolaryngol Head Neck Surg. 1991 Jun;104(6):849-55. doi: 10.1177/019459989110400614. — View Citation

Murase N, Rothwell JC, Kaji R, Urushihara R, Nakamura K, Murayama N, Igasaki T, Sakata-Igasaki M, Mima T, Ikeda A, Shibasaki H. Subthreshold low-frequency repetitive transcranial magnetic stimulation over the premotor cortex modulates writer's cramp. Brain. 2005 Jan;128(Pt 1):104-15. doi: 10.1093/brain/awh315. Epub 2004 Oct 13. — View Citation

Norris SA, Morris AE, Campbell MC, Karimi M, Adeyemo B, Paniello RC, Snyder AZ, Petersen SE, Mink JW, Perlmutter JS. Regional, not global, functional connectivity contributes to isolated focal dystonia. Neurology. 2020 Oct 20;95(16):e2246-e2258. doi: 10.1212/WNL.0000000000010791. Epub 2020 Sep 10. — View Citation

Rossi S, Hallett M, Rossini PM, Pascual-Leone A; Safety of TMS Consensus Group. Safety, ethical considerations, and application guidelines for the use of transcranial magnetic stimulation in clinical practice and research. Clin Neurophysiol. 2009 Dec;120(12):2008-2039. doi: 10.1016/j.clinph.2009.08.016. Epub 2009 Oct 14. — View Citation

Siebner HR, Filipovic SR, Rowe JB, Cordivari C, Gerschlager W, Rothwell JC, Frackowiak RS, Bhatia KP. Patients with focal arm dystonia have increased sensitivity to slow-frequency repetitive TMS of the dorsal premotor cortex. Brain. 2003 Dec;126(Pt 12):2710-25. doi: 10.1093/brain/awg282. Epub 2003 Aug 22. — View Citation

Simonyan K, Ludlow CL. Abnormal activation of the primary somatosensory cortex in spasmodic dysphonia: an fMRI study. Cereb Cortex. 2010 Nov;20(11):2749-59. doi: 10.1093/cercor/bhq023. Epub 2010 Mar 1. — View Citation

* Note: There are 16 references in all — Click here to view all references

Outcome

Type	Measure	Description	Time frame	Safety issue
Other	Forced choice paired assessment of phonatory function	If the primary or secondary assessments of objective or perceptual ratings of change fail to capture change in participants' voice between baseline and post intervention, a forced choice question will be posed to blinded raters to ask which paired voice sample represents the less severe sample and then perform a VAS ranking of how severe the voice sample sounds (0=minimal impairment, 10=severe impairment)	Day 1 (baseline), Day 5 (post intervention), and Day 12 (follow up) timepoints for both arms of the study.
Primary	Change in Objective Assessment of Phonatory Function	Participants will produce sustained /ah/ vowels, read the rainbow passage and engage in freeform conversation. This speech will be recorded and measures of cepstral peak prominence smoothed (CPPS; range: 0-100, where higher indicates stronger voice signal and correlates highly with better voice quality).	Day 1 (baseline), day 5 (post intervention), and Day 12 (follow up) timepoints for both arms of the study.
Primary	Change in Cortical Excitability (intrahemispheric inhibition)	Intrahemispheric inhibition will be measured with the cortical silent period (cSP) measured in ms	Day 1 (baseline), Day 5 (post intervention)
Secondary	Subjective Assessment of Phonatory Function	Three speech language pathologists who specialize in voice disorders and are blinded to treatment day or group, will listen to the recorded audio sentences and sustained vowels and perform an independent overall perceptual evaluation of each participant's voice for each assessment session using the rating scales from the American Speech-Language-Hearing Association recommended Consensus Auditory Perceptual Evaluation of Voice (CAPE-V). The primary measure will be the rating for Overall Severity of dysphonia, and secondary measures will include ratings for strain, roughness, breathiness, pitch and loudness. Scores closer to 0 indicate less severity and closer to 100 indicate more severely disordered. Each judge will listen to recordings of 20% of the assessments (randomly selected) twice for purposes of estimating intra-judge reliability. Ratings from the three judges will be averaged to produce one score for each perceptual parameter.	Day 1 (baseline), Day 5 (post intervention), and Day 12 (follow up) timepoints for both arms of the study.
Secondary	Self Ratings of Voice Effort	Self ratings of voice effort on a visual analog scale (VAS) after reading the sentences in Outcome 1. "Speaking required how much effort?" 0=minimal effort, 10= maximal effort	Day 1 (baseline), Day 5 (post intervention), and Day 12 (follow up) timepoints for both arms of the study.
Secondary	Secondary Objective assessment of phonatory function	In addition to the CPPS (primary measure above), the voice samples will be analyzed with the following: number of phonatory breaks (range: 0-x; were few breaks indicates a better voice quality), frequency shifts (range: 0-x Hz; where a smaller shift (closer to 0) is generally indicative of better voice quality) and the number of aperiodic segments (range: 0-x; where fewer aperiodic voice segments is generally indicative of better voice quality) will be obtained from each recording. These will be analyzed and compared over time.	Day 1 (baseline), Day 5 (post intervention), and Day 12 (follow up) timepoints for both arms of the study.

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