Did the speech of patients with Myasthenia Gravis decline over 4 years?

Ayres, Annelise; Padovani, Marina Martins Pereira; Olchik, Maira Rozenfeld; Kieling, Maiara Laís Mallmann; Santos, Vanessa Brzoskowski dos; Rothe-Neves, Rui; Behlau, Mara

doi:10.1590/2317-1782/20232023055en

ABSTRACT

Purpose

To compare the speech and voice patterns of myasthenia gravis (MG) patients over four years, and correlate the results with clinical aspects of the disease.

Methods

Data was collected for 4 years. The clinical assessment tools included the Quantitative Myasthenia Gravis (QMG) score, the Myasthenia Gravis Foundation of America (MGFA) clinical classification, and the Myasthenia Gravis Quality of Life 15-item Scale (MG-QoL). To assess speech, the recorded speaking tasks were analyzed acoustically and given auditory-perceptual ratings. Sex (equal distribution) and age (p=0.949) were used as matching criteria in the final sample, which consisted of 10 individuals in the MG group (MGG) and 10 individuals in the control group (CG).

Results

After 4 years, the MG participants presented stable health status, increased mild and moderate dysarthria (from 40% to 90% of the subjects), and a significant deterioration in the respiration, phonation, and articulation subsystems. The acoustic analysis showed a decline in articulatory patterns (speech rate p=0.047, articulation rate p=0.007, mean syllable duration p=0.007) and vocal quality (increased jitter p=0.022). In the follow-up comparison, there was a significant difference between the phonation variables (shimmer and harmonic-to-noise ratio) of the MGG and CG.

Conclusion

The MG patients presented a decline in speech over four years and an increase in mild and moderate dysarthria. Despite presenting stable health status, their respiratory, phonatory, and articulatory subsystems worsened. There was no correlation between speech patterns and clinical characteristics of the disease (severity and motor scale).

Speech; Voice; Dysarthria; Speech Acoustics; Myasthenia Gravis

RESUMO

Objetivo

Comparar o padrão de fala e voz de indivíduos com Miastenia Gravis (MG) em um intervalo de quatro anos e correlacionar com aspectos clínicos da doença.

Método

A coleta de dados foi realizada ao longo de 4 anos. A avaliação clínica foi composta pelo Quantitative Myasthenia Gravis Score (QMGS), pela Myasthenia Gravis Foundation of America Classification (MGFA) e pela escala de qualidade de vida para Miastenia Gravis (MG-QOL). A avaliação da fala foi composta por gravação de tarefas, análise perceptivo-auditiva e análise acústica. A amostra final foi composta por 10 indivíduos em MG e 10 indivíduos no grupo controle (GC), pareados por sexo (distribuição igualitária) e idade (p=0,949).

Resultados

Após 4 anos, os indivíduos com MG apresentaram estabilidade clínica, aumento do diagnóstico de disartria leve e moderada (de 40% para 90% dos sujeitos) e diminuição significativa no desempenho dos subsistemas da fala: respiração, fonação e articulação. Na análise acústica, houve declínio do padrão articulatório (taxa de fala p=0,047, taxa de articulação p=0,007, duração média das sílabas p=0,007) e qualidade vocal (jitter aumentado p=0,022). Houve diferença significativa nas variáveis fonatórias (shimmer e harmonic-to-noise ratio) entre os grupos MG e GC na comparação do seguimento.

Conclusão

Indivíduos com MG apresentaram declínio no padrão de fala em um intervalo de quatro anos, com aumento no número de disártricos (leve e moderado). Mesmo com a estabilidade da doença, houve piora dos subsistemas respiratório, fonatório e articulatório. Não houve correlação entre o padrão de fala e as características clínicas da doença (gravidade e escala motora).

Fala; Voz; Disartria; Acústica da Fala; Miastenia Grave

INTRODUCTION

Myasthenia gravis (MG) is an autoimmune disease caused by pathogenic antibodies at the neuromuscular junction and impaired neuromuscular transmissions(¹1 Juel VC, Massey JM. Myasthenia gravis. Orphanet J Rare Dis. 2007;2(1):44. PMid:17986328.

2 Meriggioli MN, Sanders DB. Autoimmune myasthenia gravis: emerging clinical and biological heterogeneity. Lancet Neurol. 2009;8(5):475-90. PMid:19375665.-³3 Jayam Trouth A, Dabi A, Solieman N, Kurukumbi M, Kalyanam J. Myasthenia Gravis: a review. Autoimmune Dis. 2012;2012:874680. http://dx.doi.org/10.1155/2012/874680 PMid:23193443.
http://dx.doi.org/10.1155/2012/874680... ). Although MG is an uncommon disease, the prevalence rate has increased over the past few years. Recent studies estimate a prevalence of 20 per 100,000 population in the US, 5.35 to 35 per 100,000 individuals worldwide, and an annual incidence ranging from 0.3 to 2.8 per 100,000 individuals(⁴4 Deenen JCW, Horlings CGC, Verschuuren JJGM, Verbeek ALM, van Engelen BGM. The epidemiology of neuromuscular disorders: a comprehensive overview of the literature. J Neuromuscul Dis. 2015;2(1):73-85. http://dx.doi.org/10.3233/JND-140045 PMid:28198707.
http://dx.doi.org/10.3233/JND-140045... ).

The main clinical manifestations of MG are weakness and fluctuating fatigue in the skeletal muscles which worsens with exercise and improves with rest. This weakness can cause varying degrees of ocular symptoms (diplopia and ptosis) and bulbar symptoms (dysarthria, dysphagia, difficulty chewing, weakness in the facial muscles, and poor breathing)(²2 Meriggioli MN, Sanders DB. Autoimmune myasthenia gravis: emerging clinical and biological heterogeneity. Lancet Neurol. 2009;8(5):475-90. PMid:19375665.,³3 Jayam Trouth A, Dabi A, Solieman N, Kurukumbi M, Kalyanam J. Myasthenia Gravis: a review. Autoimmune Dis. 2012;2012:874680. http://dx.doi.org/10.1155/2012/874680 PMid:23193443.
http://dx.doi.org/10.1155/2012/874680... ,⁵5 Montero-Odasso M. Dysphonia as first symptom of late-onset myasthenia gravis. J Gen Intern Med. 2006;21(6):C4-6. PMid:16808732.). Dysarthria is a common MG symptom. The prevalence of motor speech disorder as an early symptom ranges from 6 to 27%, and affects approximately 60% of patients as the disease progresses(⁶6 Mao VH, Abaza M, Spiegel JR, Mandel S, Hawkshaw M, Heuer RJ, et al. Laryngeal Myasthenia Gravis: report of 40 cases. J Voice. 2001;15(1):122-30. PMid:12269627.

7 David Neal G, Clarke LR. Neuromuscular disorders. Otolaryngol Clin North Am. 1987;20(1):195-201. PMid:3550594.-⁸8 Ayres A, Winckler PB, Jacinto-Scudeiro LA, Rech RS, Padovani MMP, Jotz GP, et al. Speech characteristics in individuals with myasthenia gravis: a case control study. Logoped Phoniatr Vocol. 2022;47(1):35-42. PMid:33106062.). Dysarthria in MG is of the flaccid type, and is caused by fatigue and muscle weakness in speech organs such as the vocal folds, tongue, palate, and pharyngeal constrictors(⁵5 Montero-Odasso M. Dysphonia as first symptom of late-onset myasthenia gravis. J Gen Intern Med. 2006;21(6):C4-6. PMid:16808732.,⁶6 Mao VH, Abaza M, Spiegel JR, Mandel S, Hawkshaw M, Heuer RJ, et al. Laryngeal Myasthenia Gravis: report of 40 cases. J Voice. 2001;15(1):122-30. PMid:12269627.,⁹9 Duffy J. Motor speech disorders: substrates, differential diagnosis, and management. 4. ed. Cidade: Elsevier; 2013.).

The main complaints are hoarseness, vocal fatigue, poor pitch control and decreased loudness and projection(⁵5 Montero-Odasso M. Dysphonia as first symptom of late-onset myasthenia gravis. J Gen Intern Med. 2006;21(6):C4-6. PMid:16808732.,⁶6 Mao VH, Abaza M, Spiegel JR, Mandel S, Hawkshaw M, Heuer RJ, et al. Laryngeal Myasthenia Gravis: report of 40 cases. J Voice. 2001;15(1):122-30. PMid:12269627.,⁹9 Duffy J. Motor speech disorders: substrates, differential diagnosis, and management. 4. ed. Cidade: Elsevier; 2013.). Auditory-perceptual ratings have highlighted voice alterations such as hypernasality, poor pitch control, vocal fatigue, intermittent aphonia, stridor, a breathy or harsh vocal quality, irregular distribution of energy along the vocal tract, articulatory imprecision and breaks in verbal fluidity(⁵5 Montero-Odasso M. Dysphonia as first symptom of late-onset myasthenia gravis. J Gen Intern Med. 2006;21(6):C4-6. PMid:16808732.,⁶6 Mao VH, Abaza M, Spiegel JR, Mandel S, Hawkshaw M, Heuer RJ, et al. Laryngeal Myasthenia Gravis: report of 40 cases. J Voice. 2001;15(1):122-30. PMid:12269627.,⁸8 Ayres A, Winckler PB, Jacinto-Scudeiro LA, Rech RS, Padovani MMP, Jotz GP, et al. Speech characteristics in individuals with myasthenia gravis: a case control study. Logoped Phoniatr Vocol. 2022;47(1):35-42. PMid:33106062.

9 Duffy J. Motor speech disorders: substrates, differential diagnosis, and management. 4. ed. Cidade: Elsevier; 2013.

10 Ortiz KZ, Carrillo L. Comparação entre as análises auditiva e acústica nas disartrias. Rev Soc Bras Fonoaudiol. 2008;13(4):325-31. http://dx.doi.org/10.1590/S1516-80342008000400005
http://dx.doi.org/10.1590/S1516-80342008...

11 Liu WB, Xia Q, Men LN, Wu ZK, Huang RX. Dysphonia as a primary manifestation in myasthenia gravis (MG): a retrospective review of 7 cases among 1520 MG patients. J Neurol Sci. 2007;260(1–2):16-22. PMid:17466337.-¹²12 Konstantopoulos K, Christou YP, Vogazianos P, Zamba-Papanicolaou E, Kleopa KA. A quantitative method for the assessment of dysarthrophonia in myasthenia gravis. J Neurol Sci. 2017;377:42-6. PMid:28477705.).

The findings of acoustic analyses have shown a higher mean fundamental frequency, a higher mean fundamental frequency of the vibrating vocal folds, disturbance in jitter and shimmer values and the harmonic-to-noise ratio (HNR), higher mean duration of the silent interval between syllables during oral diadochokinetic tasks, and unstable spectrographic tracings characterized by absent harmonics at high frequencies(⁵5 Montero-Odasso M. Dysphonia as first symptom of late-onset myasthenia gravis. J Gen Intern Med. 2006;21(6):C4-6. PMid:16808732.,⁶6 Mao VH, Abaza M, Spiegel JR, Mandel S, Hawkshaw M, Heuer RJ, et al. Laryngeal Myasthenia Gravis: report of 40 cases. J Voice. 2001;15(1):122-30. PMid:12269627.,⁸8 Ayres A, Winckler PB, Jacinto-Scudeiro LA, Rech RS, Padovani MMP, Jotz GP, et al. Speech characteristics in individuals with myasthenia gravis: a case control study. Logoped Phoniatr Vocol. 2022;47(1):35-42. PMid:33106062.

9 Duffy J. Motor speech disorders: substrates, differential diagnosis, and management. 4. ed. Cidade: Elsevier; 2013.

10 Ortiz KZ, Carrillo L. Comparação entre as análises auditiva e acústica nas disartrias. Rev Soc Bras Fonoaudiol. 2008;13(4):325-31. http://dx.doi.org/10.1590/S1516-80342008000400005
http://dx.doi.org/10.1590/S1516-80342008...

11 Liu WB, Xia Q, Men LN, Wu ZK, Huang RX. Dysphonia as a primary manifestation in myasthenia gravis (MG): a retrospective review of 7 cases among 1520 MG patients. J Neurol Sci. 2007;260(1–2):16-22. PMid:17466337.-¹²12 Konstantopoulos K, Christou YP, Vogazianos P, Zamba-Papanicolaou E, Kleopa KA. A quantitative method for the assessment of dysarthrophonia in myasthenia gravis. J Neurol Sci. 2017;377:42-6. PMid:28477705.).

So far, few longitudinal studies have addressed MG symptoms and possible complications resulting from myasthenic exacerbation and crisis. One longitudinal study(¹³13 Harris L, Graham S, MacLachlan S, Exuzides A, Jacob S. A retrospective longitudinal cohort study of the clinical burden in myasthenia gravis. BMC Neurol. 2022;22(1):172. PMid:35534810.) involving more than 1,000 English patients showed that, for most participants, serious disease-related events such as myasthenic exacerbation, myasthenic crisis or hospitalization had occurred in the first 2 to 3 years after diagnosis. This data suggests that treatment efficiency was achieved after this period. In addition, there was no difference between all-cause mortality scores in the MG group and controls during follow-up.

However, persistent symptoms like dysarthria are expected, even in patients with a stable health status. Yet the relationship between the pathophysiology of MG and speech disorders is still inconclusive. No longitudinal monitoring of speech in MG patients has produced evidence in the literature.

Therefore, the null hypothesis of this study was that there would be no change in the speech or voice patterns of MG patients over a 4-year period, given their stable status. The alternative hypothesis was that there would be changes over the 4-year period. The primary objective was to compare the speech and voice patterns of MG patients during the research period. The secondary objective was to correlate the voice and speech findings with clinical aspects of the disease (e.g., motor speech scales, age, education, and duration of illness), quality of life, and self-perception of speech changes.

METHODS

Study design

This was a longitudinal study. It was approved by the ethics committee of the Hospital de Clínicas de Porto Alegre (application number 120399), in compliance with the Declaration of Helsinki. All participants signed an informed consent form before assessments.

Participants

Via telephone, MG patients who participated in a previous study(⁸8 Ayres A, Winckler PB, Jacinto-Scudeiro LA, Rech RS, Padovani MMP, Jotz GP, et al. Speech characteristics in individuals with myasthenia gravis: a case control study. Logoped Phoniatr Vocol. 2022;47(1):35-42. PMid:33106062.) were invited to participate in the new investigation. These individuals were follow-up outpatients at the tertiary referral clinic for neuromuscular diseases at the Hospital de Clínicas de Porto Alegre (HCPA), in Brazil. The study included native speakers of Brazilian Portuguese (age ≥ 18 years) with an MG diagnosis confirmed by electromyography and/or acetylcholine/MuSK/anti-striated muscle antibodies. Patients were excluded if they had a history of neurological events or smoking, sensory or motor disorders that could affect test performance, systemic diseases and/or structural alterations that affect the voice and/or speech, or benefitted from speech-language rehabilitation during the study period.

Sex and age were used as matching criteria to select a healthy control group (CG) with no correlation of familiarity. There was no test robust enough to assess the tasks under conditions of normality, so a control group was used to determine if variations detected during assessment were normal. All participants (MG and CG) spoke Brazilian Portuguese as their native language.

Baseline data were collected from February 2017 to December 2018. The second data collection phase occurred 4 years later (from September 2021 to December 2021). The initial sample consisted of 38 MG patients. There was a loss of 73.6% after the first assessment because 2.6% (1) died, 5.2% (2) moved to another city, 2.6% (1) declined enrollment, 26.3% (10) missed the evaluation and 36.8% (14) could not be reached via telephone. Sex and age were used as matching criteria for the final sample of 10 MG patients and 10 controls (CG).

There was no significant difference between the ages of MG Group (MGG) (follow-up) and CG (p=0.949). The mean time between the baseline assessment and follow-up was 50 months (±5 months). The baseline and follow-up data from MGG showed no significant difference in the motor speech or MG-related quality-of-life scores. Regarding speech self-perception, there was significant improvement (Table 1). A descriptive analysis of the clinical variables per MG subject, at baseline and follow-up, is presented in Chart 1.

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Table 1
Sociodemographic data of the case and control groups

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Chart 1
Description of the clinical variables of MG patients

Study procedure

The medical records of the MG patients were searched to collect clinical and sociodemographic data from their last hospital appointment before our study (e.g., age, sex, education, duration of illness, currently prescribed medication, surgical history, disease staging, motor symptoms, number of hospital admissions, COVID-19 history).

All participants were evaluated individually in a quiet, designated room at HCPA. The same trained administrator facilitated each visit. It took an average of 30 minutes for the MG subjects to complete the speech tasks and the following questionnaires:

Myasthenia Gravis Quality of Life 15-item Scale (MG-QoL): a self-perception questionnaire specifically designed to assess the quality of life of MG patients. The score for each of the 15 items varies from 0 to 60 points. The higher the score, the worse the quality of life(¹⁴14 Burns TM, Grouse CK, Conaway MR, Sanders DB. Construct and concurrent validation of the MG-QOL15 in the practice setting. Muscle Nerve. 2010;41(2):219-26. PMid:19941339.,¹⁵15 Mourão AM, Barbosa LSM, Comini-Frota ER, Freitas DS, Gomez RS, Burns TM, et al. Clinical profile of patients with myasthenia gravis followed at the University Hospital, Federal University of Minas Gerais. Rev Assoc Med Bras. 2015;61(2):156-60. PMid:26107366.).
Radboud Oral Motor Inventory for Parkinson's Disease (ROMP): a self-perception questionnaire focused on speech, swallowing, and saliva complications. Only the 7-item domain of speech was used in our assessment. The score ranges from 7 to 28 points, and a lower score means fewer speech complaints(¹⁶16 Kalf JG, Borm GF, de Swart BJ, Bloem BR, Zwarts MJ, Munneke M. Reproducibility and validity of patient-rated assessment of speech, swallowing, and saliva control in Parkinson’s disease. Arch Phys Med Rehabil. 2011;92(7):1152-8. PMid:21704797.,¹⁷17 Presotto M, Olchik MR, Kalf JG, Rieder CRM. Translation, linguistic and cultural adaptation, reliability and validity of the Radboud Oral Motor Inventory for Parkinson’s Disease - ROMP questionnaire. Arq Neuropsiquiatr. 2018;76(5):316-23. PMid:29898078.).
The Quantitative Myasthenia Gravis (QMG) score: a clinical scale used as an MG outcome measure, with a maximum score of 39 points. It consists of 13 items. A higher score indicates more severe disease(¹⁸18 Benatar M, Sanders DB, Burns TM, Cutter GR, Guptill JT, Baggi F, et al. Recommendations for myasthenia gravis clinical trials. Muscle Nerve. 2012;45(6):909-17. PMid:22581550.,¹⁹19 Oliveira EF, Valério BCO, Cavalcante V, Urbano JJ, Silva AS, Polaro MN, et al. Quantitative Myasthenia Gravis Score: a Brazilian multicenter study for translation, cultural adaptation and validation. Arq Neuropsiquiatr. 2017;75(7):457-63. PMid:28746433.).

● The Myasthenia Gravis Foundation of America (MGFA) classification: a clinical classification that groups patients into five progressively severe classes. Class I is characterized by “any ocular muscle weakness” with preserved strength in other muscles. Class V is defined by “intubation, with or without mechanical ventilation, except when used during routine postoperative management”(²⁰20 Jaretzki A 3rd, Barohn RJ, Ernstoff RM, Kaminski HJ, Keesey JC, Penn AS, et al. Myasthenia gravis: recommendations for clinical research standards. Task Force of the Medical Scientific Advisory Board of the Myasthenia Gravis Foundation of America. Neurology. 2000;55(1):16-23. PMid:10891897.).

An Acer Aspire One 725-0899 computer, a KARSECT HT-9 headset microphone coupled to an Andrea PureAudio adapter and Audacity software were used to record and collect the speech samples from both groups. With the microphone positioned at 5 cm distance, the voice samples were recorded at 44.1 kHz with 16-bit resolution(²¹21 Rusz J, Tykalova T, Ramig LO, Tripoliti E. Guidelines for speech recording and acoustic analyses in dysarthrias of movement disorders. Mov Disord Off J Mov Disord Soc. 2021;36(4):803-14. PMid:33373483.). The following tasks were tested: maximum phonation time (MPT) – with the vowel /a/ sustained as long as possible after a deep inhalation, diadochokinetic (DDK) syllable rate - /pataka/, pitch variation – with the diphthong /iu/ produced several times in a single breath, automatic sequence (numbers 20 to 30), sentence imitation using 2 intonation patterns - “It rained a lot this weekend.” (statement), “Is she going on vacation?” (question) and “Today is my lucky day.”(exclamation), and spontaneous speech elicited by the question “ Which route did you take to get here?”. Patients were instructed to reply at their habitual pace and loudness.

Auditory-perceptual and acoustic analysis

For the auditory-perceptual analysis of voice and speech, all audio files were edited and normalized using PRAAT software, version 6.1.11, and played for 3 blinded examiners. These speech-language therapists are members of the FONAD research group and have at least 5 years of experience evaluating and planning therapy for dysarthria. Prior training was carried out with audio files not used in the study. The Fleiss Kappa test was used to measure agreement, resulting in a score of k≥0.90 (excellent) for the variable of dysarthria. After listening to all the audio files once in random order, a consensus-based evaluation was performed. Upon request, audio files could be replayed. The speech subsystems (phonation, articulation, respiration, resonance and prosody) were analyzed based on the definitions described by Duffy(⁹9 Duffy J. Motor speech disorders: substrates, differential diagnosis, and management. 4. ed. Cidade: Elsevier; 2013.). The authors used a severity scale of 0 to 4 for motor speech changes (0 = normal, 1 = mild dysarthria, 2 = moderate dysarthria, or 3 = severe dysarthria).

Praat(²²22 Boersma PWD. Praat: doing phonetics by computer [Internet]. 2022 [cited 2023 March 27]. Available from: https://www.praat.org.
https://www.praat.org... ) version 6.1.11 was used for the acoustic analysis. The following parameters of the prepared audio files were assessed, based on Rusz et al.(²³23 Rusz J, Cmejla R, Ruzickova H, Ruzicka E. Quantitative acoustic measurements for characterization of speech and voice disorders in early untreated Parkinson’s disease. J Acoust Soc Am. 2011;129(1):350-67. PMid:21303016.) and Vogel and Maruff(²⁴24 Vogel AP, Maruff P. Comparison of voice acquisition methodologies in speech research. Behav Res Methods. 2008;40(4):982-7. PMid:19001389.):

Phonation - sustained vowel /a/: jitter (rap), shimmer (local), fundamental frequency (F₀), standard deviation of F₀, HNR.
Articulation – DDK rate /pataka/ and spontaneous speech (MPT, speech rate, articulation rate, average syllable duration (ASD)).
Respiration - sustained vowel /a/: MPT.
Resonance - diphthong /iu/: the ratio between the 2nd vowel formant frequency of /i/ and the 2nd vowel formant frequency of /u/.

● Prosody – statement, exclamation, and question imitation: variations in frequency and intensity.

A specific automatic script(²⁵25 Jong NH, Wempe T. Praat script to detect syllable nuclei and measure speech rate automatically. Behav Res Methods. 2009;41(2):385-90. PMid:19363178.) was used for the articulation tasks to detect syllable nuclei in intensity peaks and automatically measure the diadochokinetic and spontaneous speech rates.

Statistical Analysis

Descriptive data analysis was used to describe variable distributions. Absolute and relative frequencies were used to analyze categorical variables, and mean and standard deviation were used to analyze quantitative variables. The Wilcoxon signed-rank test was used to compare baseline and follow-up data from MGG. A bootstrap hypothesis test (Pearson's correlation coefficient) was used to analyze clinical variables and the follow-up results of MGG. Another bootstrap hypothesis test (Student's t-test) was used to compare the follow-up data from MGG and CG, and equalize independent sample means. The McNemar Test was used to compare the results of the auditory-perceptual assessment. Statistical significance was set at p<0.05. Results were statistically analyzed using version 18.0 of the Statistical Package for the Social Sciences (SPSS).

RESULTS

A comparison between the baseline and follow-up MG data showed improvement in MPT after 4 years. This finding may be associated with the respiratory and prosody subsystems, since more significant variations in fundamental frequency were associated with statement sentences. However, there was a decline in articulatory performance. Patients produced fewer syllables per second, shorter syllable duration averages during spontaneous speech, and abnormal jitter thresholds (Table 2). There was a higher number of voices diagnosed with mild or moderate dysarthria due to altered phonation and articulation. This matched the articulatory and phonatory subsystem disruptions detected during follow-up (Table 3).

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Table 2
Comparison between the acoustic variables of the baseline and follow-up MGG

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Table 3
Auditory-perceptual analysis of MG patients

There was a statistical difference between the shimmer (local) and HNR thresholds of both follow-up groups. This suggests more significant irregularity in vocal fold vibration and a higher level of phonatory noise in the case group (Table 4).

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Table 4
Comparison between the follow-up acoustic variables of MGG and CG

No significant correlations were found between the acoustic findings and the clinical variables of the MGG (Table 5). The results suggest no relationship between clinical characteristics and a decline in speech patterns.

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Table 5
Correlation between clinical variables and follow-up data from the MG group

DISCUSSION

This study investigated the speech and voice patterns of MG patients after a four-year interval and correlated the results with clinical aspects of the disease. This longitudinal study confirmed our alternative hypothesis. Although the MG patients presented a stable health status, there was a decline in speech performance and an increase in the number of participants diagnosed with mild or moderate dysarthria.

The auditory-perceptual analysis results showed worse respiration, phonation, and articulation. The acoustic analysis also detected a significant increase in jitter thresholds (phonation), a reduced number of syllables per second, and a shorter mean syllable duration during spontaneous speech (articulation). The respiratory results were more difficult to interpret since the auditory-perceptual analysis revealed an increase in participants with speech pattern alterations. Still, an objective measurement of MPT showed improvement between baseline and follow-up performance. Regarding prosody, in particular statement sentences, there was more frequency variation during follow-up.

There were no differences between the clinical scale and MG classifications. This was expected because of the pathophysiology of the disease(¹1 Juel VC, Massey JM. Myasthenia gravis. Orphanet J Rare Dis. 2007;2(1):44. PMid:17986328.,³3 Jayam Trouth A, Dabi A, Solieman N, Kurukumbi M, Kalyanam J. Myasthenia Gravis: a review. Autoimmune Dis. 2012;2012:874680. http://dx.doi.org/10.1155/2012/874680 PMid:23193443.
http://dx.doi.org/10.1155/2012/874680... ,¹³13 Harris L, Graham S, MacLachlan S, Exuzides A, Jacob S. A retrospective longitudinal cohort study of the clinical burden in myasthenia gravis. BMC Neurol. 2022;22(1):172. PMid:35534810.). However, the speech results were different. Phonatory and articulatory performances worsened, albeit mainly to a mild degree. Therefore, it is reasonable to hypothesize that speech intelligibility was not significantly affected, especially not with shorter utterances (sentences). There was no significant correlation between the acoustic analysis and the clinical variables in MGG.

The speech subsystem scores were lower than those of the first assessment(⁸8 Ayres A, Winckler PB, Jacinto-Scudeiro LA, Rech RS, Padovani MMP, Jotz GP, et al. Speech characteristics in individuals with myasthenia gravis: a case control study. Logoped Phoniatr Vocol. 2022;47(1):35-42. PMid:33106062.). Patients presented a further decline in the subsystems that were already altered at baseline. Phonation, respiration, and articulation were most affected, in the order of highest incidence. Resonance and prosody had not changed over the 4 years. Preserved resonance patterns are characteristic of the flaccid dysarthria associated with MG(⁵5 Montero-Odasso M. Dysphonia as first symptom of late-onset myasthenia gravis. J Gen Intern Med. 2006;21(6):C4-6. PMid:16808732.,⁹9 Duffy J. Motor speech disorders: substrates, differential diagnosis, and management. 4. ed. Cidade: Elsevier; 2013.,¹⁰10 Ortiz KZ, Carrillo L. Comparação entre as análises auditiva e acústica nas disartrias. Rev Soc Bras Fonoaudiol. 2008;13(4):325-31. http://dx.doi.org/10.1590/S1516-80342008000400005
http://dx.doi.org/10.1590/S1516-80342008... ). However, this aspect may change more in times of crisis and improve with clinical stabilization. Furthermore, Harris et al.(¹³13 Harris L, Graham S, MacLachlan S, Exuzides A, Jacob S. A retrospective longitudinal cohort study of the clinical burden in myasthenia gravis. BMC Neurol. 2022;22(1):172. PMid:35534810.) demonstrated that MG symptoms could further deteriorate with drug use, such as the prolonged use of corticosteroids over time. This is why it is important to record MG patients’ vocal and articulatory patterns, regardless of the resonance quality.

In addition, the percentage of patients diagnosed with dysarthria increased from 40% to 90%. We found a higher prevalence than the literature (50 to 60% throughout the course of the disease)(⁶6 Mao VH, Abaza M, Spiegel JR, Mandel S, Hawkshaw M, Heuer RJ, et al. Laryngeal Myasthenia Gravis: report of 40 cases. J Voice. 2001;15(1):122-30. PMid:12269627.

7 David Neal G, Clarke LR. Neuromuscular disorders. Otolaryngol Clin North Am. 1987;20(1):195-201. PMid:3550594.-⁸8 Ayres A, Winckler PB, Jacinto-Scudeiro LA, Rech RS, Padovani MMP, Jotz GP, et al. Speech characteristics in individuals with myasthenia gravis: a case control study. Logoped Phoniatr Vocol. 2022;47(1):35-42. PMid:33106062.).

Regarding the improvement in the MPT task and the intonation of statement sentences, our hypothesis is that there was inherent variation due to learning. Given that the clinical aspects of the disease remained stable and that the participants repeated the speech assessments, we believe familiarity may have influenced their performance. It should be noted that, despite improvement at follow-up, the MPT scores remained abnormal(⁹9 Duffy J. Motor speech disorders: substrates, differential diagnosis, and management. 4. ed. Cidade: Elsevier; 2013.,¹⁰10 Ortiz KZ, Carrillo L. Comparação entre as análises auditiva e acústica nas disartrias. Rev Soc Bras Fonoaudiol. 2008;13(4):325-31. http://dx.doi.org/10.1590/S1516-80342008000400005
http://dx.doi.org/10.1590/S1516-80342008... ,²⁶26 Padovani MMP. Vocal and speech acoustic measures, perceptual-auditory analysis and communication self-evaluation in dysarthrias. Rev Soc Bras Fonoaudiol. 2011;16:375-375. http://dx.doi.org/10.1590/S1516-80342011000300023.
http://dx.doi.org/10.1590/S1516-80342011... ). As for intonation, there is no current normative data for Brazilian Portuguese. Additionally, improved MPT and intonation of statement sentences did not assist phonatory performance in the MG patients.

When the follow-up MGG and CG were compared, there was a statistical difference regarding the control of voice intensity and the signal-to-noise ratio. The MG patients presented worse vocal quality. These were the parameters that distinguished the myasthenic patients from the controls. This finding is similar to results that other authors have described(⁸8 Ayres A, Winckler PB, Jacinto-Scudeiro LA, Rech RS, Padovani MMP, Jotz GP, et al. Speech characteristics in individuals with myasthenia gravis: a case control study. Logoped Phoniatr Vocol. 2022;47(1):35-42. PMid:33106062.

9 Duffy J. Motor speech disorders: substrates, differential diagnosis, and management. 4. ed. Cidade: Elsevier; 2013.-¹⁰10 Ortiz KZ, Carrillo L. Comparação entre as análises auditiva e acústica nas disartrias. Rev Soc Bras Fonoaudiol. 2008;13(4):325-31. http://dx.doi.org/10.1590/S1516-80342008000400005
http://dx.doi.org/10.1590/S1516-80342008... ,¹²12 Konstantopoulos K, Christou YP, Vogazianos P, Zamba-Papanicolaou E, Kleopa KA. A quantitative method for the assessment of dysarthrophonia in myasthenia gravis. J Neurol Sci. 2017;377:42-6. PMid:28477705.). These are characteristics of the phonatory progression in MG.

The DDK rate task was not sensitive enough to detect articulatory decline in MG patients. This has been a controversial test in literature. Konstantopoulos et. al.(¹²12 Konstantopoulos K, Christou YP, Vogazianos P, Zamba-Papanicolaou E, Kleopa KA. A quantitative method for the assessment of dysarthrophonia in myasthenia gravis. J Neurol Sci. 2017;377:42-6. PMid:28477705.) described a higher mean duration of silent intervals between syllables as a dysarthric feature in MG. In a previous study of ours(⁹9 Duffy J. Motor speech disorders: substrates, differential diagnosis, and management. 4. ed. Cidade: Elsevier; 2013.), the DDK rate test was also not sensitive enough to differentiate the MG patients from the controls.

We have two hypotheses for this result. The first is: short tasks are easier for MG patients to execute without being affected by fatigue(²⁶26 Padovani MMP. Vocal and speech acoustic measures, perceptual-auditory analysis and communication self-evaluation in dysarthrias. Rev Soc Bras Fonoaudiol. 2011;16:375-375. http://dx.doi.org/10.1590/S1516-80342011000300023.
http://dx.doi.org/10.1590/S1516-80342011... ). The second hypothesis is that the DDK rate task is better suited to assess speech motor programming(²⁷27 Staiger A, Schölderle T, Brendel B, Bötzel K, Ziegler W. Oral motor abilities are task dependent: a factor analytic approach to performance rate. J Mot Behav. 2017;49(5):482-93. PMid:27935471.,²⁸28 Staiger A, Schölderle T, Brendel B, Ziegler W. Dissociating oral motor capabilities: evidence from patients with movement disorders. Neuropsychologia. 2017;95:40-53. PMid:27939368.). Repeated syllable tests may be more sensitive to muscle fatigue and changes in speech patterns in MG patients MG.

There were no reported changes in the quality of life for the MG patients. Another longitudinal study(²⁹29 Bozovic I, Ilic Zivojinovic J, Peric S, Kostic M, Ivanovic V, Lavrnic D, et al. Long-term outcome in patients with myasthenia gravis: one decade longitudinal study. J Neurol. 2022;269(4):2039-45. PMid:34480608.) with a significant number of patients in remission did not find any improvement in their quality of life after ten years.

Speech self-perception improved during the study period. The hypothesis is that, as the phonatory pattern slowly worsens over the years, MG patients adapt to these changes. Therefore, speech self-perception questionnaires should not be used as the only monitoring tool for dysarthria in this population, as it does not seem sensitive enough to identify changes over time.

Clinical services for MG patients lack appropriate referral networks for multidisciplinary follow-up. Frequently, MG patients are only referred to speech therapists after hospital admissions associated with a myasthenic crisis. Given that we detected speech disorders in patients with stable status, speech monitoring by therapists is important. MG patients require multidisciplinary care³⁰30 Devlin I, Williams KL, Shrubsole K. Fragmented care and missed opportunities: the experiences of adults with myasthenia gravis in accessing and receiving allied health care in Australia. Disabil Rehabil. 2023;45(15):2488-96. http://dx.doi.org/10.1080/09638288.2022.2094481. PMid:35786287.
http://dx.doi.org/10.1080/09638288.2022.... . We recommend a minimum assessment protocol that tests a sustained vowel /a/, the DDK rate using the same syllable, and spontaneous speech (minimum time of 60 seconds) to evaluate vocal quality and articulatory patterns. The auditory-perceptual analysis of speech in our research corroborated the acoustic markers.

Losing 73.6% of the initial sample may have influenced the data and impacted other analyses, such as the correlations between speech symptoms and the use and dosage of medication. The high number of sample losses demonstrates the difficulty in recruiting patients for research in low-incoming countries where outpatient follow-up is complicated and difficult due to social, economic, and educational issues. Further longitudinal studies and larger samples of this population are necessary.

CONCLUSION

The longitudinal analysis showed a decline in MG patients’ speech patterns, and a higher number of mild or moderate dysarthria diagnoses over four years. Despite having a stable health status, MG patients presented worse respiratory, phonatory, and articulatory performance. There was no correlation between speech patterns and the clinical characteristics of the disease (severity and motor scale), suggesting that the pathophysiology of the disease and speech in MG patients progress independently over time.

Study conducted at Hospital de Clínicas de Porto Alegre (HCPA) - Porto Alegre (RS), Brasil.
Financial support: Fundo de incentivo a pesquisa e eventos (FIPE) do Hospital de Clínicas de Porto Alegre (HCPA) - (GPPG-HCPA 2016-0654).

REFERENCES

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Deenen JCW, Horlings CGC, Verschuuren JJGM, Verbeek ALM, van Engelen BGM. The epidemiology of neuromuscular disorders: a comprehensive overview of the literature. J Neuromuscul Dis. 2015;2(1):73-85. http://dx.doi.org/10.3233/JND-140045 PMid:28198707.
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Montero-Odasso M. Dysphonia as first symptom of late-onset myasthenia gravis. J Gen Intern Med. 2006;21(6):C4-6. PMid:16808732.
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Mao VH, Abaza M, Spiegel JR, Mandel S, Hawkshaw M, Heuer RJ, et al. Laryngeal Myasthenia Gravis: report of 40 cases. J Voice. 2001;15(1):122-30. PMid:12269627.
⁷
David Neal G, Clarke LR. Neuromuscular disorders. Otolaryngol Clin North Am. 1987;20(1):195-201. PMid:3550594.
⁸
Ayres A, Winckler PB, Jacinto-Scudeiro LA, Rech RS, Padovani MMP, Jotz GP, et al. Speech characteristics in individuals with myasthenia gravis: a case control study. Logoped Phoniatr Vocol. 2022;47(1):35-42. PMid:33106062.
⁹
Duffy J. Motor speech disorders: substrates, differential diagnosis, and management. 4. ed. Cidade: Elsevier; 2013.
¹⁰
Ortiz KZ, Carrillo L. Comparação entre as análises auditiva e acústica nas disartrias. Rev Soc Bras Fonoaudiol. 2008;13(4):325-31. http://dx.doi.org/10.1590/S1516-80342008000400005
» http://dx.doi.org/10.1590/S1516-80342008000400005
¹¹
Liu WB, Xia Q, Men LN, Wu ZK, Huang RX. Dysphonia as a primary manifestation in myasthenia gravis (MG): a retrospective review of 7 cases among 1520 MG patients. J Neurol Sci. 2007;260(1–2):16-22. PMid:17466337.
¹²
Konstantopoulos K, Christou YP, Vogazianos P, Zamba-Papanicolaou E, Kleopa KA. A quantitative method for the assessment of dysarthrophonia in myasthenia gravis. J Neurol Sci. 2017;377:42-6. PMid:28477705.
¹³
Harris L, Graham S, MacLachlan S, Exuzides A, Jacob S. A retrospective longitudinal cohort study of the clinical burden in myasthenia gravis. BMC Neurol. 2022;22(1):172. PMid:35534810.
¹⁴
Burns TM, Grouse CK, Conaway MR, Sanders DB. Construct and concurrent validation of the MG-QOL15 in the practice setting. Muscle Nerve. 2010;41(2):219-26. PMid:19941339.
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Mourão AM, Barbosa LSM, Comini-Frota ER, Freitas DS, Gomez RS, Burns TM, et al. Clinical profile of patients with myasthenia gravis followed at the University Hospital, Federal University of Minas Gerais. Rev Assoc Med Bras. 2015;61(2):156-60. PMid:26107366.
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Kalf JG, Borm GF, de Swart BJ, Bloem BR, Zwarts MJ, Munneke M. Reproducibility and validity of patient-rated assessment of speech, swallowing, and saliva control in Parkinson’s disease. Arch Phys Med Rehabil. 2011;92(7):1152-8. PMid:21704797.
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Presotto M, Olchik MR, Kalf JG, Rieder CRM. Translation, linguistic and cultural adaptation, reliability and validity of the Radboud Oral Motor Inventory for Parkinson’s Disease - ROMP questionnaire. Arq Neuropsiquiatr. 2018;76(5):316-23. PMid:29898078.
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Oliveira EF, Valério BCO, Cavalcante V, Urbano JJ, Silva AS, Polaro MN, et al. Quantitative Myasthenia Gravis Score: a Brazilian multicenter study for translation, cultural adaptation and validation. Arq Neuropsiquiatr. 2017;75(7):457-63. PMid:28746433.
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Jaretzki A 3rd, Barohn RJ, Ernstoff RM, Kaminski HJ, Keesey JC, Penn AS, et al. Myasthenia gravis: recommendations for clinical research standards. Task Force of the Medical Scientific Advisory Board of the Myasthenia Gravis Foundation of America. Neurology. 2000;55(1):16-23. PMid:10891897.
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Rusz J, Tykalova T, Ramig LO, Tripoliti E. Guidelines for speech recording and acoustic analyses in dysarthrias of movement disorders. Mov Disord Off J Mov Disord Soc. 2021;36(4):803-14. PMid:33373483.
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Boersma PWD. Praat: doing phonetics by computer [Internet]. 2022 [cited 2023 March 27]. Available from: https://www.praat.org
» https://www.praat.org
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Rusz J, Cmejla R, Ruzickova H, Ruzicka E. Quantitative acoustic measurements for characterization of speech and voice disorders in early untreated Parkinson’s disease. J Acoust Soc Am. 2011;129(1):350-67. PMid:21303016.
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Vogel AP, Maruff P. Comparison of voice acquisition methodologies in speech research. Behav Res Methods. 2008;40(4):982-7. PMid:19001389.
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Jong NH, Wempe T. Praat script to detect syllable nuclei and measure speech rate automatically. Behav Res Methods. 2009;41(2):385-90. PMid:19363178.
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Padovani MMP. Vocal and speech acoustic measures, perceptual-auditory analysis and communication self-evaluation in dysarthrias. Rev Soc Bras Fonoaudiol. 2011;16:375-375. http://dx.doi.org/10.1590/S1516-80342011000300023
» http://dx.doi.org/10.1590/S1516-80342011000300023
²⁷
Staiger A, Schölderle T, Brendel B, Bötzel K, Ziegler W. Oral motor abilities are task dependent: a factor analytic approach to performance rate. J Mot Behav. 2017;49(5):482-93. PMid:27935471.
²⁸
Staiger A, Schölderle T, Brendel B, Ziegler W. Dissociating oral motor capabilities: evidence from patients with movement disorders. Neuropsychologia. 2017;95:40-53. PMid:27939368.
²⁹
Bozovic I, Ilic Zivojinovic J, Peric S, Kostic M, Ivanovic V, Lavrnic D, et al. Long-term outcome in patients with myasthenia gravis: one decade longitudinal study. J Neurol. 2022;269(4):2039-45. PMid:34480608.
³⁰
Devlin I, Williams KL, Shrubsole K. Fragmented care and missed opportunities: the experiences of adults with myasthenia gravis in accessing and receiving allied health care in Australia. Disabil Rehabil. 2023;45(15):2488-96. http://dx.doi.org/10.1080/09638288.2022.2094481 PMid:35786287.
» http://dx.doi.org/10.1080/09638288.2022.2094481

Publication Dates

Publication in this collection
10 Nov 2023
Date of issue
2024

History

Received
27 Mar 2023
Accepted
31 May 2023

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] Study conducted at Hospital de Clínicas de Porto Alegre (HCPA) - Porto Alegre (RS), Brasil.

[2] Financial support: Fundo de incentivo a pesquisa e eventos (FIPE) do Hospital de Clínicas de Porto Alegre (HCPA) - (GPPG-HCPA 2016-0654).

Variables	MGG		CG	p
Variables	Baseline	Follow-up	CG	p
Age	52.50 (±17.29)	56.90 (±17.74)	56.40 (±16.60)	-
Duration of illness	10.90 (±4.87)	14.80 (±8.72)	-	-
Education	9.40 (±4.47)	10.0 (±4.87)	-	-
ROMP	14.30 (±6.48)	10.80 (±3.55)	-	0.017
MG-QOL	18.30 (±16.30)	17.70 (±18.38)	-	0.482
QMG	12.90 (±9.17)	13.20 (±6.98)	-	0.766
Male	5 (50)	5 (50)	5 (50)	-

Subject	Sex	MGC		MGFA		Thymectomy		Immunoglobulin therapy		G		AI		IM		Hospital admissions due to myasthenic crisis		Antibody	COVID history
Subject	Sex	1	2	1	2	1	2	1	2	1	2	1	2	1	2	1	2	Antibody	COVID history
001	M	0	7	2A	2A	-	-	-	-	+	-	+	+	-	+	-	-	anti -AChR +	-
002	F	19	19	1	2A	-	-	-	-	+	+	+	+	+	+	-	+	anti-MUSK - anti -AChR -	March/2021
003	F	25	26	2A	2A	-	-	-	-	-	-	+	+	-	-	-	-	no	February/2021
004	F	25	10	2B	2A	+	+	-	-	-	-	+	+	-	+	-	-	no	-
010	M	8	6	1	2A	-	-	-	-	+	-	-	+	+	+	+	-	anti -AChR +	-
012	F	2	13	2A	2A	+	+	-	-	-	-	+	+	+	-	-	-	no	-
016	F	13	19	2A	2A	+	+	-	-	-	-	+	+	-	-	-	-	anti -AChR +	-
019	M	14	9	2A	2A	+	+	+	-	-	+	+	+	+	+	-	-	anti -AChR +	-
023	M	4	5	1	1	-	-	-	-	-	-	+	+	+	+	-	-	no	-
031	M	9	19	2A	2A	-	-	-	-	+	-	+	+	-	-	-	-	anti -AChR +	July/2021

Variables	Baseline		Follow-up		Z	p
Variables	Mean	SD	Average	SD	Z	p
Phonation – sustained /a/ F₀
Mean	156.65	36.26	162.56	42.97	-1.070 ^b b negative ranks;	0.285
SD	12.99	15.83	10.04	14.63	-.357 ^c c positive ranks	0.721
Minimum	137.20	45.62	134.77	49.52	-0.153 ^b	0.878
Maximum	209.77	74.76	180.43	43.47	-0.459 ^c	0.646
Shimmer (local)	9.28	4.49	12.77	9.53	-0.866 ^b	0.386
Jitter (RAP)	0.33	0.33	0.64	0.75	-2.293 ^b	0.022^* * statistical significance set at p<0.05;
Articulation – diadochokinetic syllable rate
Speech rate	4.41	1.52	4.65	1.55	-0.153 ^b	0.878
Articulation rate	4.53	1.48	4.65	1.55	-0.051 ^b	0.959
Mean syllable duration	0.25	0.13	0.25	0.14	-0.051 ^c	0.959
Articulation - spontaneous speech
Speech rate	3.71	0.36	3.26	0.4	-1.988 ^c	0.047*
Articulation rate	4.84	0.53	3.85	0.47	-2.701 ^c	0.007*
Mean syllable duration	0.20	0.02	0.26	0.03	-2.701 ^b	0.007*
Respiration - sustained vowel
MPT	5.22	2.72	11.84	6.30	-2.395 ^b	0.017*
Resonance - diphthong
F₂ /i/	2219.75	578.57	2242.27	127.30	-1.682 ^b	0.093
F₂ /u/	802.92	149.12	1001.69	193.87	-1.784 ^c	0.074
F₂ /i/ / F₂ /u/	2.81	0.85	2.30	0.40	-1.478 ^b	0.139
Prosody - counting numbers
Frequency variation	349.99	82.66	359.54	108.14	-1.376 ^b	0.169
Prosody – statement
Frequency variation	71.11	31.87	122.92	61.38	-2.947 ^b	0.013*
Intensity Variation	29.35	8.16	27.36	5.72	-0.357 ^c	0.721
Prosody – question
Frequency variation	91.29	71.41	102.89	47.63	-0.764 ^b	0.445
Intensity Variation	29.30	5.39	26.44	3.79	-0.968 ^c	0.333
Prosody – exclamation
Frequency variation	118.92	86.81	116.96	67.20	-0.561 ^b	0.575
Intensity Variation	31.71	7.26	29.31	7.94	-0.663 ^c	0.050

Speech subsystem	Classification	Baseline	Follow-up	p
Speech subsystem	Classification	N (%)	N (%)	p
Phonation	Normal	2 (20)	1 (10)	1.000
	Mild dysarthria	7 (70)	6 (60)
	Moderate dysarthria	1 (10)	3 (30)
Articulation	Normal	7 (70)	3 (30)	0.219
	Mild dysarthria	2 (20)	3 (30)
	Moderate dysarthria	1 (10)	4 (40)
Respiration	Normal	6 (60)	2 (20)	0.125
	Mild dysarthria	3 (30)	6 (60)
	Moderate dysarthria	1 (10)	2 (20)
Resonance	Normal	10 (100)	8 (80)	-
Resonance	Mild dysarthria	-	2 (20)	-
Prosody	Normal	9 (90)	10 (100)	-
Prosody	Mild dysarthria	1 (10)	-	-
Dysarthria severity	Normal	6 (60)	1 (10)	0.063
	Mild dysarthria	3 (30)	6 (60)
	Moderate dysarthria	1 (10)	3 (30)

Acoustic variables	MGG	CG	t	p
Acoustic variables	Mean (SD)	Mean (SD)	t	p
Phonation - sustained vowel F₀
Mean	162.56 (±42.97)	167.51 (±48.98)	-0.240	0.813
Standard deviation	10.04 (±14.63)	10.98 (±19.57)	-0.122	0.904
Minimum	134.77 (±49.52)	137.17 (±56.91)	-0.101	0.921
Maximum	180.43 (±43.47)	183.84 (±58.36)	-0.148	0.884
Shimmer (local)	12.77 (±9.53)	5.05 (±2.58)	2.471	0.024^* * statistical significance set at p<0.05
Jitter (local)	1.09 (±1.23)	0.37 (±0.20)	1.809	0.087
HNR	12.62 (±8.32)	19.52 (±5.51)	-2.186	0.042*
Articulation - diadochokinetic syllable rate
Phonation time	6.86 (2.81)	10.55 (5.23)	-1.962	0.070
Speech rate	4.65 (1.55)	5.02 (1.25)	-0.591	0.562
Articulation rate	4.65 (1.55)	5.18 (1.23)	-0.845	0.410
Mean syllable duration	0.25 (0.14)	0.20 (0.69)	0.950	0.360
Articulation - spontaneous speech
Phonation time	28.27 (± 6.81)	31.50 (± 12.84)	-0.703	0.491
Speech rate	3.26 (± 0.41)	3.28 (± 0.57)	-0.072	0.944
Articulation rate	3.85 (± 0.47)	4.22 (± 0.67)	-1.411	0.177
Mean syllable duration	0.26 (± 0.03)	0.24 (± 0.03)	1.366	0.189
Respiration - sustained /a/
MPT	11.84 (±6.30)	15.60 (±8.30)	-1.141	0.269
Resonance – Diphthong /iu/
F₂ /i/	2242.27 (±127.30)	2222.83 (±238.10)	0.228	0.822
F₂ /u/	1001.69 (±193.87)	872.31 (±114.45)	1.817	0.086
F₂ /i/ / F₂ /u/	2.30 (±0.40)	2.5831 (±0.42)	-1.520	0.146
Prosody – Statement
Frequency variation	122.92 (±61.38)	97.76 (±48.84)	1.014	0.325
Intensity variation	27.36 (±5.72)	31.51 (±3.39)	-1.974	0.064

	Age		Duration of illness		ROMP		MGQoL		MGC		Shimmer (local)		HNR
	r	p	r	p	r	p	r	p	r	p	r	p	r	p
Age	-	-	0.403	0.248	-0.207	0.567	-0.309	0.384	0.146	0.687	0.553	0.098	-0.421	0.226
Duration of illness	0.403	0.248	-	-	-0.399	0.253	-0.476	0.164	-0.322	0.365	-0.027	0.940	0.017	0.963
ROMP	-0.207	0.567	-0.399	0.253	-	-	0.404	0.247	0.467	0.173	0.169	0.642	-0.093	0.799
MG-QoL	-0.309	0.384	-0.476	0.164	0.404	0.247	-	-	0.601	0.066	-0.388	0.268	0.528	0.117
MGC	0.146	0.687	-0.322	0.365	0.467	0.173	0.601	0.066	-	-	0.157	0.665	0.050	0.891
Shimmer (local)	0.553	0.098	-0.027	0.940	0.169	0.642	-0.388	0.268	0.157	0.665	-	-	-0.955	0.000*
HNR	-0.421	0.226	0.017	0.963	-0.093	0.799	0.528	0.117	0.050	0.891	-0.955	0.000^* * statistical significance set at p<0.05	-	-

Brasil

Brasil

Did the speech of patients with Myasthenia Gravis decline over 4 years?

Há declínio na fala de pacientes com Miastenia Gravis ao longo de 4 anos?

ABSTRACT

Purpose

Methods

Results

Conclusion

RESUMO

Objetivo

Método

Resultados

Conclusão

INTRODUCTION

METHODS

Study design

Participants

Study procedure

Auditory-perceptual and acoustic analysis

Statistical Analysis

RESULTS

DISCUSSION

CONCLUSION

REFERENCES

Publication Dates

History