RESUMO
INTRODUCTION: DFNA9 is characterized by adult-onset progressive sensorineural hearing loss (SNHL) and vestibular impairment. More than 15 years ago, genotype-phenotype correlation studies estimated the initial age of hearing deterioration in the fourth to fifth decade (ranging from 32 to 43 years). However, these analyses were based on relatively limited numbers of mainly symptomatic carriers using markedly different methodologies. The starting point for the hearing deterioration is more correctly determined with larger numbers of carriers and with a more clearly defined starting point of the hearing deterioration. AIM: The aim of this study was to determine milestone ages (start and maximal hearing deterioration, potential eligibility for hearing aids and cochlear implants based on pure-tone average [PTA]) in a large series of p.Pro51Ser COCH variant carriers. The degree of individual interaural asymmetry and the degree of variability (interquartile range) with which the hearing deterioration progresses across ages were also studied, and age-related typical audiograms (ARTA) were constructed. MATERIAL AND METHODS: One hundred eleven Belgian and Dutch p.P51S variant carriers were identified and recruited for audiological investigation. Their hearing thresholds were compared with p50th, p95th, and p97.5th percentile values of presbyacusis (ISO 7029 standards). The onset and degree of hearing deterioration were defined and assessed for each frequency and with three PTAs (PTA0.5-4 [0.5, 1, 2, and 4 kHz]; PTA4-8 [4 and 8 kHz]; and PTA6-8 [6 and 8 kHz]). The milestones ages were derived from nonlinear regression model of hearing thresholds against age, for male and female carriers separately, because of different age-referenced limits. Interaural right-left asymmetry was assessed, and variability of hearing thresholds were calculated using interquartile range. ARTAs were built with both observed data and a prediction model. RESULTS: Hearing dysfunction in p.P51S carriers begins at about 38 years of age (ranging from 28 to 43 years) on average in female and 46 years (ranging from 42 to 49 years) in male carriers (third decade: female, fifth decade: male carriers), depending on the hearing frequency and with differences in deterioration sequence between both genders. These differences, however, were mainly due to more stringent age-referenced limits for men. In contrast, predictions (ARTA) did not show any difference of phenotypic expression between genders. At about 48 to 50 years of age on average, the majority of DFNA9 patients may need conventional hearing aids (PTA ≥ 40 dB HL), whereas this is about 56 to 59 years for cochlear implants (PTA ≥ 70 dB HL). There is a high degree of individual interaural asymmetry and interindividual variability throughout all ages. CONCLUSION: This study demonstrates that the onset of sensorineural hearing deterioration starts in the third decade and probably even earlier. Regardless of differences in estimates, DFNA9 expresses similarly in male and female carriers, but male carriers are much more difficult to identify in early stages of the disease. Comprehensive assessment of the natural course of DFNA9 is of particular interest to predict the age of onset or critical period of most significant function deterioration in individual carriers of the pathogenic variant. This will help to design studies in the search for disease-modifying therapies.
Assuntos
Proteínas da Matriz Extracelular , Perda Auditiva Neurossensorial , Adulto , Audiometria de Tons Puros , Estudos Transversais , Proteínas da Matriz Extracelular/genética , Feminino , Estudos de Associação Genética , Audição , Humanos , Masculino , Pessoa de Meia-IdadeRESUMO
INTRODUCTION: DFNA9 is characterized by adult-onset hearing loss and evolution toward bilateral vestibulopathy (BVP). The genotype-phenotype correlation studies were conducted 15 years ago. However, their conclusions were mainly based on symptomatic carriers and the vestibular data exclusively derived from the horizontal (lateral) semicircular canal (SCC). The last decade was marked by the emergence of new clinical diagnostic tools, such as the video head impulse test (vHIT) and vestibular-evoked myogenic evoked potentials (VEMPs), expanding our evaluation to all six SCCs and the otolith organs (saccule and utricule). AIM: The aim of this study was to comprehensively evaluate vestibular function in the largest series presymptomatic as well as symptomatic p.P51S variant carriers, to determine which labyrinthine part shows the first signs of deterioration and which SCC function declines at first and to determine the age at which p.P51S variant carriers develop caloric areflexia on VNG and vHIT vestibulo-ocular reflex (VOR)-gain dysfunction as defined by the Barany Society criteria for BVP. MATERIAL AND METHODS: One hundred eleven p.P51S variant carriers were included. The following vestibular function tests were applied in two different centers: ENG/VNG, vHIT, and VEMPs. The following parameters were analyzed: age (years), hearing loss (pure-tone average of 0.5-4 kHz [PTA0.5-4, dB HL]), sum of maximal peak slow-phase eye velocity obtained with bi-thermal (30°C and 44°C, water irrigation; 25°C and 44°C, air irrigation) caloric test (°/s), vHIT VOR-gain on LSCC, superior SCC and posterior SCC, C-VEMP both numerical (threshold, dB nHL) and categorical (present or absent), and O-VEMP as categorical (present or absent). The age of onset of vestibular dysfunction was determined both with categorical (onset in decades using Box & Whisker plots) and numeric approach (onset in years using regression analysis). The same method was applied for determining the age at which vestibular function declined beyond the limits of BVP, as defined by the Barany Society. RESULTS: With the categorical approach, otolith function was declining first (3rd decade), followed by caloric response (5th decade) and vHIT VOR-gains (5th-6th decade). Estimated age of onset showed that the deterioration began with C-VEMP activity (31 years), followed by caloric responses (water irrigation) (35 years) and ended with vHIT VOR-gains (48-57 years). Hearing deterioration started earlier than vestibular deterioration in female carriers, which is different from earlier reports. BVP was predicted at about 53 years of age on average with VNG caloric gain (water irrigation) and between 47 and 57 years of age for the three SCCs. Loss of C-VEMP response was estimated at about 46 years of age. CONCLUSION: Former hypothesis of vestibular decline preceding hearing deterioration by 9 years was confirmed by the numeric approach, but this was less obvious with the categorical approach. Wide confidence intervals of the regression models may explain deviation of the fits from true relationship. There is a typical vestibular deterioration hierarchy in p.P51S variant carriers. To further refine the present findings, a prospective longitudinal study of the auditory and vestibular phenotype may help to get even better insights in this matter.