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Article

Wideband Tympanometry and Pressurized Otoacoustic Emissions in Children with Surgical Excision of Palatine and/or Pharyngeal Tonsils

by
Aline Buratti Sanches
1,
Milaine Dominici Sanfins
2,3,*,
Piotr Henryk Skarzynski
3,4,5,
Magdalena Beata Skarżyńska
4,5,6,7,
Henrique Costa Penatti
8,
Caroline Donadon
1,
Ingrid Pereira de Souza
1,
Ingridy Vitoria da Silva
1 and
Maria Francisca Colella-Santos
1
1
Faculty of Medical Sciences, State University of Campinas, Campinas 13083-887, São Paulo, Brazil
2
Speech-Hearing-Language Department, Audiology Discipline, Universidade Federal de São Paulo, São Paulo 04023-062, São Paulo, Brazil
3
Department of Teleaudiology and Screening, Institute of Physiology and Pathology of Hearing, 05-830 Kajetany/Warsaw, Poland
4
Department of Otorhinolaryngology Hearing, Center of Hearing and Speech Medincus, 05-830 Kajetany, Poland
5
Department of Clinical Trials, Institute of Sensory Organs, 05-830 Kajetany, Poland
6
Department of Hearing, World Hearing Center, Institute of Physiology and Pathology of Hearing, 05-830 Kajetany, Poland
7
Department of Pharmacotherapy and Pharmaceutical Care, Faculty of Pharmacy, Medical University of Warsaw, 02-097 Warsaw, Poland
8
Department of Otolaryngology, Ambulatory of Medical Specialties, Santa Bárbara D’Oeste 13450-000, São Paulo, Brazil
*
Author to whom correspondence should be addressed.
Brain Sci. 2024, 14(6), 598; https://doi.org/10.3390/brainsci14060598
Submission received: 6 May 2024 / Revised: 3 June 2024 / Accepted: 4 June 2024 / Published: 14 June 2024
(This article belongs to the Special Issue Recent Advances in Hearing Impairment)
Versions Notes

Abstract

:
Palatine and pharyngeal tonsil hypertrophy may lead to dysfunction of the auditory tube due to a propensity for infection, potentially giving rise to otitis media. This is a quantitative and longitudinal study, developed from 2019 to 2021, at the State University of Campinas (UNICAMP). The studied sample comprised 15 participants aged 5 to 12 years (mean 7.9 years), 12 male and 3 female, arranged into two groups: children diagnosed with pharyngeal and/or palatine tonsil hypertrophy who were candidates for surgery (G1), and children who were later evaluated after surgery (G2). As part of the test, an otoscopy and measurements of logoaudiometry, pure-tone threshold audiometry, wideband tympanometry (ambient and peak pressure), and otoacoustic emissions (TEOAEs and DPOAEs, both at ambient and peak pressure) were all performed. There were statistically significant differences between phases in pure-tone audiometry, in terms of 226 Hz tympanometry, wideband tympanometry in peak pressure conditions, in the amplitude measurement TEOAEs in both pressure conditions, in DPOAEs in ambient pressure conditions, and in the signal/noise measurement in both pressures in DPOAEs. Overall, it was found that hearing tests were different for subjects with palatine and pharyngeal tonsil hypertrophy compared to the post-surgical group.

1. Introduction

The auditory system is made up of sensory structures and central connections, consisting of a peripheral and central portion. The peripheral system comprises the structures of the external ear, middle ear, inner ear, and vestibulocochlear nerve, located in the temporal region of the skull. These structures are responsible for the reception, detection, conduction, and transduction of acoustic signals into neuroelectric impulses. The central auditory system comprises the auditory pathways, brain stem, and cortical areas, which are responsible for analyzing and interpreting sound stimuli and the functions of central auditory processing [1].
Changes in the peripheral auditory system can occur due to several factors. One of them is hypertrophy of the pharyngeal and palatine tonsils, which can obstruct the upper airways, causing oral breathing and poor Eustachian tube function [2]. The immunological function of the pharyngeal and palatine tonsils leads to their rapid growth during the first years of life, reaching their maximum size at age 6 for the pharyngeal tonsils and puberty for the palatine tonsils. After this period, involution normally occurs through increased production of fibrous tissue and atrophy of fatty tissue, which generally occurs around 8 to 10 years of age and during adulthood, respectively [3]. However, hypertrophic adenoids and tonsils do not atrophy normally [4].
As they represent the body’s first contact with microorganisms and substances, the tonsils are commonly the site of a range of pathological processes, mainly fighting off infection, and this occurs mostly between the ages of 2 and 5 years [5]. In cases where there is chronic inflammation of these structures, surgical removal is recommended. Worldwide, adenotonsillectomy is one of the most commonly performed surgical procedures and the most common form of otorhinolaryngological surgery, especially in children [6].
Because tonsil hypertrophy is so common in children and can have serious effects, it is very important to perform objective hearing tests on this population. This is because the condition may be linked to otitis media, hearing loss, and central auditory processing disorders, all of which can hurt the development of children.
To detect changes in hearing, audiological assessments are required. One procedure is acoustic immittance measurement, which can evaluate the function and integrity of the middle ear. Tympanometry is a dynamic way to measure acoustic immittance that checks how mobile the tympanic-ossicular chain system is when air pressure changes in the external acoustic cavity (EAC) [7,8,9]. Conventionally, tympanometry is performed using a single frequency, commonly 226 Hz. More recently, wideband tympanometry (WBT) has been used, as it measures the efficiency of the middle ear in transmitting sound at frequencies from 226 to 8000 Hz. WBT allows pressurized and non-pressurized measurements to be performed, allowing evaluation in patients with a ventilation tube or perforated tympanic membrane [10]. WBT can also find out the values of reflectance and absorbance, which change depending on the health of the tympanic-ossicular chain. This gives us more details about the health of the middle ear [11].
Otoacoustic emissions (OAE), whether transient (TEOAE) or distortion product (DPOAE), are electroacoustic tests that evaluate cochlear function. The outer hair cells are connected to the normal functioning of the cochlear amplifier, and OAEs are by-products of those mechanisms. They can change depending on the type of stimulus and the sex of the person [12]. Abnormal OAEs can be a sign of hearing loss due to damaged structures in the inner ear or various pathologies of the middle ear, such as perforation of the eardrum, otitis media, and the presence of impacted cerumen [13].
It is also worth highlighting that the conductive structures, including the pinna, the external auditory canal, the tympanic membrane, and the middle ear, are essentially well developed at birth [14]. Initially, the neonate ear canal is relatively flaccid and prolapsed, but it begins ossifying prenatally and continues throughout the first years of life, while the cochlea is mature and adult from birth [15]. In this way, the life stages of children and adolescents do not have an impact on the responses of WBT and OAE.
Hearing assessments using complementary methods can help diagnose problems and establish remedial actions. They are also useful to monitor subjects after they have undergone surgical procedures. The present study focused on children before and after surgery for removal of pharyngeal and/or palatine tonsils. We evaluated the peripheral auditory system of these children through broadband tympanometry, TEOAEs, and DPOAEs under pressurized and non-pressurized conditions.
This study had the main objective of analyzing the peripheral auditory system of children with surgical indications for removal of the pharyngeal and/or palatine tonsils before and after surgery. The second goal was to look at the results of tests that measured tympanometry across a wide frequency range and the transient and distortion product of otoacoustic emissions, taking into account the moments before and after the tests.

2. Materials and Methods

2.1. Ethics

This is a quantitative, comparative, and descriptive study that used a cross-sectional and longitudinal approach. The project was approved by the Research Ethics Committee of the State University of Campinas under opinion 3,753,188. Data were collected between the years 2019 and 2021. The subjects were invited to voluntarily participate in the research and were accompanied by a guardian. A free and informed consent form was signed by the guardian, and an assent form by the minor.

2.2. Participants

The initial proposal was for 59 individuals in the pre-operative group to undergo re-evaluation after the surgical procedure; however, due to the pandemic, a large number of patients did not agree to return for the re-evaluation process. However, it should also be noted that isolation due to COVID had positive impacts on cases of tonsil hypertrophy. A study carried out on children who were awaiting adenotonsillectomy surgery identified that there was an improvement in symptoms during quarantine, demonstrating that confinement can have a positive impact on specific diseases derived from early socialization, in a way that causes changes in medical and surgical therapeutic indications [16]. Another study suggested that the prevalence of OME has returned to pre-lockdown levels, and that interrupting day care center attendance for a two-month period could be effective in resolving most cases of chronic OME [17].
The study sample consisted of 15 children between 5 and 12 years old (mean 7.9 years), comprising 12 males and 3 females. Considering the phases in which they were evaluated, they were grouped into two groups: G1, the pre-operative study group comprising children whose otorhinolaryngologists said they needed surgery to remove their palatine and/or pharyngeal tonsils, and G2, the post-operative study group comprising children from G1 who were re-evaluated after the surgery.
The children who made up G1 came from an otorhinolaryngology outpatient clinic, where the researcher attended medical appointments and invited children to participate in this study.
G2 was made up of the subjects from G1 who had undergone surgery to remove their tonsils.
The data were obtained between the end of 2019 and the end of 2021, a period in which we went through the pandemic, and both research and outpatient activities were suspended for a year.

2.3. Inclusion Criteria

The individuals who qualified for G1 had to have undergone an otorhinolaryngological examination, have a surgical indication for palatine and/or pharyngeal tonsil hypertrophy, and be free of any complaints, neurological changes, or cognitive deficits (as reported by the parent and supported by medical records). For G2, the criteria were: having been evaluated preoperatively; and having undergone surgery to remove the pharyngeal and/or palatine tonsils in the previous 3 to 6 months. All children presented results within normal limits for speech audiometry.

2.4. Exclusion Criteria

The exclusion criteria for the present study were as follows: children aged younger than 5 years or older than 12 years; lack of authorization from the person responsible for the child; and children with tympanic membrane perforation, cholesteatoma, tympanosclerosis, aural atresia, craniofacial anomalies, cleft palate, genetic syndromes, neurological changes, or cognitive deficits.

2.5. Procedures

An otorhinolaryngological exam, a meatoscopy, speech audiometry, pure-tone audiometry, broadband tympanometry at ambient pressure (AP) and peak pressure (PP), an investigation of acoustic reflexes, and tests of transient otoacoustic emissions (TEOAEs) and distortion product otoacoustic emissions (DPOAEs) at ambient pressure (AP) and peak pressure (PP) were all performed on the participants.
The otorhinolaryngological evaluations were carried out at the Ambulatory of Medical Specialties of Santa Bárbara D’Oeste, and the audiological evaluations were carried out at the Audiology Laboratories of the Department of Human Development and Rehabilitation/Faculty of Medical Sciences of the State University of Campinas.
Hearing assessments were carried out with the necessary equipment in the institution’s audiology laboratories and were performed in a single day.

2.5.1. Otorhinolaryngological Evaluation

The same otorhinolaryngologist performed all of the otorhinolaryngological evaluations, which included an otoscopy, rhinoscopy, and otoscopy physical examination after reviewing the patient’s clinical history. When enlargement of the tonsils was observed on physical examination, a classification of 1 to 4 was given according to the degree of hypertrophy and obstruction of the oropharynx (following the classification of Brodsky [18]). The degrees of turbinate hypertrophy were also observed, as were any craniofacial characteristics, such as adenoid facies or maxillary atresia. For the diagnosis of pharyngeal tonsil hypertrophy, flexible nasofibroscopy or cavum radiography were performed as necessary. For surgical indications, the following criteria were used: loud and persistent snoring, observed apnea, dysphagia due to tonsillar hypertrophy, oral breathing that does not get better with medical treatment, or recurrent tonsillitis or rhinosinusitis (according to the Paradise criteria [19]).

2.5.2. Otoscopy

All children underwent a meatoscopy to check for any impediments to carrying out audiological assessments. Only patients who had no changes in their otoscopy during their initial visit with an otorhinolaryngologist were eligible to participate in the studies. If there was any change, the patient was excluded from the study.

2.5.3. Pure-Tone Audiometry

A soundproof booth (Redusom) using an audiometer (model AC40, manufacturer Interacoustics, Middelfart, Denmark) and supra-aural headphones (model TDH 49, manufacturer Interacoustics, Middelfart, Denmark) was used to test frequencies from 250 to 8000 Hz with pure tones to find the hearing threshold. The normality criteria adopted were those of Northern and Downs: hearing thresholds ≤ 15 dBHL when the frequencies 500, 1000, and 2000 Hz were averaged [20].

2.5.4. Logoaudiometry

Logoaudiometry consisted of a speech recognition threshold (SRT) and a speech recognition percentage index (SRPI), both carried out in a soundproof booth and with the same equipment as used in tonal audiometry. The SRF sought to confirm the tonal thresholds obtained in audiometry by obtaining the minimum level of intensity at which the subject could correctly repeat 50% of the words presented. The SRPI was a measure of speech intelligibility at an intensity of 40 dB, as determined by correct answers to a list of monosyllables. Values of 88% to 100% on SRPI were adopted as a normality criterion [21].

2.5.5. Wideband Tympanometry (Ambient and Peak Pressure)

In order to test for conditions of the middle ear, broadband tympanometry was performed with Interacoustics Titan equipment, connected via a USB cable to a portable computer, probe, and earpiece. With the probe inserted into the EAC, a click stimulus was presented at 96 dB SPL and a pressure that swept from +200 to −300 daPa depending on the performance condition. The microphone in the probe picked up the stimulus that came back from the tympanic membrane. The software then calculated the acoustic absorbance by looking at the relationship between the stimulus and the acoustic absorbance. This created a three-dimensional graph with frequency (226–8000 Hz), pressure, and acoustic absorbance as its axes.
There were 107 separate frequencies on the absorbance curve, spanning from 226 to 8000 Hz. For this study, 17 frequencies were chosen at random, based on results from other research [22,23,24,25]. These frequencies were 226, 257, 324, 408, 500, 630, 794, 1000, 1260, 1587, 2000, 2520, 3175, 4000, 5040, 6350, and 8000 Hz. In each ear, two scans were performed: one at ambient pressure (AP, 0 daPa) and the other at peak pressure (PP). A measurement was taken at peak pressure (the point where the two-dimensional broadband tympanometry graph [23] showed the highest specific absorbance for each subject). According to the equipment’s shadow curve of normality, the acoustic absorbance curve was either classified as normal or altered.
The mobility of the tympanic-ossicular chain system was examined by measuring the tympanometric curve at a frequency of 226 Hz while air pressure was changed in the EAC. The reference values used were the peak compliance at atmospheric pressure (0 daPa) for an equivalent volume of 0.3 to 1.3 mL. The acoustic reflex was tested ipsilaterally and contralaterally at frequencies of 500, 1000, 2000, 3000, and 4000 Hz. A reflex at 70 to 100 dB above the threshold for pure tone from 500 to 4000 Hz was expected [7].

2.5.6. TEOAEs and DPOAEs (Ambient and Peak Pressure)

TEOAEs and DPOAEs were performed to record the activity of outer hair cells. The equipment used to capture emissions was the same equipment as used in wideband tympanometry. Emissions were obtained at peak pressure (pressurized) and ambient pressure (non-pressurized) conditions.
TEOAEs were registered in response to 300 stimuli at 83 dBpeSPL over the frequency range of 1000 to 5000 Hz. To show that TEOAEs were present, a signal-to-noise ratio of at least 6 dBSPL was used for four frequency bands in a row, with an overall reproducibility of at least 90% and probe stability of at least 90%. We recorded DPOAEs in the DP-gram mode while two stimuli, f1 and f2, were shown at the same time. The ratio of f2 to f1 was 1.22, and the dBSPL levels were 65/55 over the frequency range of 500 to 10,000 Hz. The criterion used to indicate the occurrence of DPOAEs was a signal/noise ratio ≥ 6 dB and an amplitude above −10 dB SPL [26,27].

2.6. Statistical Analyses

A statistician examined the results. SPSS V20, Minitab 16, and Excel Office 2010 were used for statistical analysis.
The significance level adopted was 5% (p < 0.05). Parametric statistical tests were used.
To compare the two groups in the distribution of qualitative variables, a chi-square test was used.
To compare the qualitative factors of G1 and G2, a chi-square test was used, and for the quantitative factors, a paired Student’s t-test was used.
To compare the results between the groups in different pressure situations (peak pressure vs. ambient pressure), a paired Student’s t-test was used.
The results are shown in the accompanying tables. In the tables, statistically significant p-values are shown with an asterisk symbol (*). The symbol ‘x’ indicates that it was not possible to use the statistics in the data set.

3. Results

3.1. Sample Characterization

The sample consisted of 15 children, divided into two groups: (i) a study group pre-surgery (G1) and (ii) a study group post-surgery (G2). From the otorhinolaryngological exam, a surgical indication was found for all of the subjects.
There were 12 children who had both their pharyngeal and palatine tonsils removed at the same time, and 3 children who only had their pharyngeal tonsils removed (adenoid).
Table 1 shows the subjects distributed by age, sex, and structures removed in surgery.
Statistical analysis was performed examining the results considering the ear, and there was no significant difference; thus, the researchers chose to group the ears, so n represented 30 ears in the following tests.

3.2. Pure-Tone Audiometry

Table 2 shows the comparison between groups of auditory thresholds from pure-tone audiometry at frequencies from 250 to 8000 Hz, in the pre- and post-surgical phases. There was a statistically significant difference between phases at frequencies of 1000 Hz, 2000 Hz, and 3000 Hz, with better auditory thresholds in the G2 (post-surgery phase).

3.3. Tympanometry (226 Hz and Wideband)

Table 3 shows a comparison of the phases in relation to the classification (normal or altered) of results, following the criteria of each test, pure tone audiometry, tympanometry, and research on ipsi and contralateral acoustic reflexes. There was a statistically significant difference between the groups in terms of 226 Hz tympanometry, with G2 exhibiting better results.
In the AP condition, there was no significant difference between groups, while in the PP condition (Table 4), there was a significant difference between the groups at frequencies from 500 to 749 Hz.
There was no significant difference between the phases in the classification (normal or altered) of the absorbance curve, both for the peak pressure and ambient pressure conditions.

3.4. TEOAEs and DPOAEs

Table 5 shows the amplitude measurement of transient evoked otoacoustic emissions (TEOAEs) between frequencies from 1000 Hz to 5000 Hz in the peak pressure and ambient pressure conditions in both groups. The results indicate that there was a significant difference between the groups in the amplitude measurement, only for the frequency of 1000 Hz in PP and AP.
There was no significant difference between groups for the signal/noise ratio measurement in both pressure conditions in TEOAEs.
Table 6 shows a comparison between groups in terms of amplitude of otoacoustic emissions by distortion product in peak pressure and ambient pressure conditions in both groups (paired Student’s t-test).
This table shows the amplitude measurement of otoacoustic emissions by distortion product (DPOAEs) between frequencies from 1000 Hz to 5000 Hz in peak pressure and ambient pressure conditions in both groups. The results indicate that there was a significant difference between the groups in the amplitude measurement, only for the frequency of 8000 Hz in AP.
Table 7 shows a comparison between groups in terms of signal/noise of otoacoustic emissions by distortion product in peak pressure and ambient pressure conditions in both groups (paired Student’s t-test).
This table shows the signal/noise measurement of otoacoustic emissions by distortion product (DPOAEs) between frequencies from 1000 Hz to 5000 Hz in peak pressure and ambient pressure conditions in both groups. The results indicate that there was a significant difference between the groups in the signal/noise measurement for frequencies from 1000 Hz to 3000 Hz in PP, and for frequencies from 1000 Hz to 4000 Hz in AP.

4. Discussion

The present study aimed to understand the differences in how the peripheral auditory system functions in children with hypertrophy of the pharyngeal and/or palatine tonsils. We tested these children both before and after the removal of these structures using 226 Hz and wideband tympanometry, pure-tone audiometry, and otoacoustic emissions. To date, few studies have been carried out on this population using different assessment methods.

4.1. Pure-Tone Audiometry

The main objective of audiological assessment is to determine the integrity of the auditory system as well as identify the type, degree, and configuration of hearing loss in each ear. Tonal threshold audiometry is fundamental to audiological diagnosis and is the gold standard test for evaluating hearing [28].
Comparisons between G1 and G2 showed that G1 had higher (or poorer) tonal thresholds for frequencies from 1000 to 3000 Hz. The improvement in pure-tone audiometry for G2 was probably due to the surgical procedure, corroborating previous studies that studied hearing loss in patients following otorhinolaryngological treatment, including cases of adenotonsillar hypertrophy [29,30]. However, both groups presented mean and median hearing thresholds within normal limits at all frequencies. It should be noted that good hearing sensitivity at medium and high frequencies is important for understanding and acquiring speech, and sensory deprivation can harm child development.

4.2. Tympanometry (226 Hz and Wideband)

Tympanometry is an objective and rapid test that investigates the integrity of the tympanic-ossicular system and helps identify middle ear changes. These occur mainly in schoolchildren, such as the children in the present study [7,31].
Tympanometry using a 226 Hz probe showed no statistically significant difference between the groups. These data diverge from the literature, where it is reported that changes in the adenoid and/or palatine tonsils tend to produce negative middle ear pressures, with values ranging from −100 to −400 daPa. This shift in the tympanometric curve is probably related to mechanical obstruction of the auditory tube [32,33]. Abdel and Tabook reported a highly significant relationship between adenoid hypertrophy and the presence of a type B tympanogram; they also reported a high correlation between adenoid size and the incidence of otitis media with effusion [34].
When comparing subjects in the pre- and post-surgical phases, there was a statistical difference in tympanometry, in which the normality index rose from 86.7% in the pre-surgical phase to 100% in the post-surgical phase. The altered tympanometric curves obtained in the pre-surgical phase were classified as two type B curves and two type C curves. There was no significant difference between the phases for compliance and pressure. However, when observing the descriptive pressure values, we identified that in the comparison between the groups, the subjects in pre-surgical phase showed a wide variation in negative pressure, which recovered in the post-surgical phase. Bluestone et al. indicated that enlarged adenoids can lead to mechanical obstruction of the auditory tube, leading to air absorption and negative intratympanic pressure [32].
Thus, our study demonstrates that children with adetonsillar hypertrophy presented tympanometric changes, indicative of otitis media and tubal dysfunction. This result is in agreement with the study by Bianchini et al., which concluded that patients with hypertrophy are more susceptible to tympanometric changes [29]. According to Salvinelli et al., surgery for chronic nasal obstruction significantly improves tubal function and middle ear ventilation at least one month after the surgical procedure [35]. Therefore, our result is in line with an improvement in tympanometric findings after a period of 3–6 months following the surgical procedure.
When comparing acoustic reflexes in the pre- and post-phases (Table 3), we found no statistical difference, but it was possible to observe an improvement in responses post-operatively. The absence of the acoustic reflex is an indication of changes in the middle ear; however, due to the high complexity of the neural mechanism involved, the presence of increased threshold values and/or the absence of the acoustic reflex in individuals with tonal auditory thresholds within the standard normality may be associated with the presence of changes in language and auditory processing [36].
When analyzing the measurement of acoustic absorbance in the pre- and post-surgery phases, the results indicated a significant difference for the frequencies of 500, 630, and 749 Hz, in which the average post-surgery absorbance was increased; that is, the subjects showed greater absorbance after surgery for all frequencies. It was observed that there was no significant difference between the phases in the classification of the absorbance curve in both the peak pressure and ambient pressure conditions.
Our findings are in line with a literature review performed by Hunter and colleagues that confirmed that WBT has the potential to be a better diagnostic tool than traditional tympanometry because it can precisely measure how the middle ear receives, absorbs, and sends sound energy at different frequencies [37].
There are no previous studies of WBT in children with hypertrophy, and so the present work adds important information in this area. It is also worth noting that WBT can be useful in monitoring different stages of treatment, particularly before and after a surgical procedure, providing a marker of conditions and improvements in the middle ear.

4.3. TEOAEs and DPOAEs

OAEs aim to evaluate the functioning of the cochlea via measurements of outer hair cell responses, and can be used to help diagnose central auditory impairment. The most clinically useful otoacoustic emissions are transient stimulus otoacoustic emissions (TEOAEs) and distortion product otoacoustic emissions (DPOAEs) [38].
Combining OAE testing with tympanometry is appropriate for identifying middle ear changes [39]. The presence of middle ear abnormalities, such as in cases of otosclerosis and otitis media, affects OAE amplitudes, as the integrity of the middle ear and tympanic membrane are crucial for detecting outer hair cell responses.
Studies have shown that ambient pressure measurements may have sufficient accuracy for use in some hearing screening applications, but the pressurized condition provides additional information that may be useful for diagnostic applications [40].

4.4. Limitations and Future Research

Early hearing screening of children can help avoid possible adverse impacts on their global development. It is therefore suggested that studies in the area be continued, and that a hearing assessment protocol for all children who present clinical signs of tonsil hypertrophy be implemented.
The present study was carried out during the SARS-COVID-19 pandemic. Collections were initially suspended and then gradually resumed after making services more flexible and with the authorization of the institution. Unfortunately, even after introducing more flexible testing, many parents and guardians chose not to continue with the research, resulting in a reduced number of cases for follow-up.
Therefore, we are continuing our work, aiming to deepen our knowledge of the effect of hypertrophy of the pharyngeal and/or palatine tonsils on auditory function.

5. Conclusions

This study used an updated comprehensive middle ear evaluation methodology that included wideband tympanometry, which allowed for a thorough assessment of middle ear status. Using a variety of peripheral auditory assessments, we demonstrated that children with pharyngeal and/or palatine tonsil hypertrophy had improved auditory responses after surgery. Our findings support the implementation of wideband tympanometry as a standard in pediatric audiology.

Author Contributions

Conceptualization: A.B.S. and M.F.C.-S.; methodology: A.B.S. and M.F.C.-S.; formal analysis: A.B.S., M.F.C.-S. and M.D.S.; investigation: A.B.S., H.C.P., C.D., I.P.d.S. and I.V.d.S.; resources: M.F.C.-S.; data curation: A.B.S.; writing, original draft preparation: A.B.S., M.F.C.-S. and M.D.S.; writing, review and editing: A.B.S., M.D.S., P.H.S., M.B.S. and M.F.C.-S.; visualization: A.B.S., M.D.S. and M.F.C.-S.; supervision: M.F.C.-S.; project administration: A.B.S.; funding acquisition: M.D.S. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

This study was conducted according to the guidelines of the Declaration of Helsinki and approved by the Research Ethics Committee of the State University of Campinas under opinion 3,753,188, approved on 9 December 2019.

Informed Consent Statement

Informed consent was obtained from all subjects involved in this study.

Data Availability Statement

The raw data supporting the conclusions of this article will be made available by the authors on request due to privacy concerns. The data in tables are deposited in the UNICAMP research data repository (REDU) and can be accessed via the link: https://doi.org/10.25824/redu/VYLYMD, accessed on 29 May 2024.

Acknowledgments

The authors acknowledge the contributions of patients, employees at CEPRE and AME, and statistical and translation staff.

Conflicts of Interest

The authors declare no conflicts of interest.

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Table 1. Characterization of 15 subjects before surgery by age, sex, and structures removed in surgery.
Table 1. Characterization of 15 subjects before surgery by age, sex, and structures removed in surgery.
Age (Years)56789101112
SexFMFMFMFMFMFMFMFM
Structures removed in surgeryPharyngeal and palatine tonsils0201011302011000
Pharyngeal tonsils0000011000010000
Legend: F, female; M, male.
Table 2. Comparison between groups in terms of pure-tone thresholds (paired Student’s t-test).
Table 2. Comparison between groups in terms of pure-tone thresholds (paired Student’s t-test).
Frequency (Hz)GroupnMean (dB HL)MedianSDMinMaxp-Value
250G1308.17105.94−5200.889
G2308.00104.66020
500G1306.6755.14−5150.086
G2305.0054.35−515
1000G1304.3354.50−515* 0.014
G2301.8303.07−510
2000G1304.8354.45−515* 0.037
G2302.8353.39−510
3000G1305.1753.82010* <0.001
G2301.8303.59−510
4000G1303.1754.64−5150.119
G2301.6705.14−515
6000G1305.6756.12−10150.202
G2307.3356.12020
8000G1304.6755.71−5200.778
G2305.0056.57−1015
Legend: G1, group pre-surgery; G2, group post-surgery; n, number of subjects; SD, standard deviation; Min, minimum; Max, maximum; p-value, * p ≤ 0.05.
Table 3. Comparison of subjects in relation classifications (normal or altered) of the results of pure-tone audiometry, and acoustic reflex research, in the pre- and post-surgical phases (chi-square test).
Table 3. Comparison of subjects in relation classifications (normal or altered) of the results of pure-tone audiometry, and acoustic reflex research, in the pre- and post-surgical phases (chi-square test).
TestClassificationG1G2Totalp-Value
n%n%n%
Pure tone audiometryAltered00%00%00%-x-
Normal30100%30100%60100%
TympanometryAltered413.3%00%46.7%* 0.038
Normal2686.7%30100%5693.3%
Reflex IPSI 500Absent723.3%516.7%1220.0%0.519
Present2376.7%2583.3%4880.0%
Reflex IPSI 1000Absent516.7%310.0%813.3%0.448
Present2583.3%2790.0%5286.7%
Reflex IPSI 2000Absent620.0%310.0%915.0%0.278
Present2480.0%2790.0%5185.0%
Reflex IPSI 4000Absent1136.7%826.7%1931.7%0.405
Present1963.3%2273.3%4168.3%
Reflex CONTRA 500Absent2170.0%1963.3%4066.7%0.584
Present930.0%1136.7%2033.3%
Reflex CONTRA 1000Absent2066.7%2066.7%4066.7%1.000
Present1033.3%1033.3%2033.3%
Reflex CONTRA 2000Absent1033.3%1240.0%2236.7%0.592
Present2066.7%1860.0%3863.3%
Reflex CONTRA 3000Absent1451.9%1348.1%2750.0%0.785
Present1348.1%1451.9%2750.0%
Reflex CONTRA 4000Absent1343.3%1446.7%2745.0%0.795
Present1756.7%1653.3%3355.0%
Legend: G1, group pre-surgery; G2, group post-surgery; n, number of ears; %, percentage; p-value, * p ≤ 0.05; -x-, was not possible to use the statistics in the data set.
Table 4. Comparison between groups in terms of absorbance at peak pressure from wideband tympanometry (paired Student’s t-test).
Table 4. Comparison between groups in terms of absorbance at peak pressure from wideband tympanometry (paired Student’s t-test).
Frequency (Hz)GroupnMean (dB HL)MedianSDMinMaxp-Value
226 PPG1300.1010.0940.0500.0010.2120.057
G2300.1210.1160.0560.0470.259
257 PPG1300.1070.0990.0520.0030.2220.060
G2300.1280.1230.0590.0500.273
324 PPG1300.1360.1190.0620.0290.2880.055
G2300.1620.1520.0750.0550.345
408 PPG1300.1870.1550.0780.0880.3750.055
G2300.2210.2090.1010.0690.434
500 PPG1300.2400.2030.0970.1030.451* 0.031
G2300.2840.2640.1250.0930.512
630 PPG1300.3380.3070.1310.1350.670* 0.047
G2300.3900.3820.1550.1340.670
749 PPG1300.4400.4200.1550.1860.714* 0.046
G2300.4980.4860.1760.1960.766
1000 PPG1300.5980.6030.1690.2490.8620.159
G2300.6390.6370.1530.3890.933
1260 PPG1300.6530.6840.1310.2600.8400.644
G2300.6670.6830.1280.4440.978
1587 PPG1300.6670.6970.1270.3510.8460.729
G2300.6760.7330.1490.3520.909
2000 PPG1300.6520.6540.1680.3310.9320.973
G2300.6530.7260.2210.0850.947
2520 PPG1300.7290.7330.2040.3240.9920.590
G2300.7520.7900.1960.3430.989
3175 PPG1300.7670.7980.1760.3480.9890.629
G2300.7440.7840.2030.3030.990
4000 PPG1300.7280.7630.1740.2910.9490.302
G2300.6770.7250.1660.2500.968
5040 PPG1300.5610.5510.1770.2720.9470.754
G2300.5450.5550.1860.1990.880
6350 PPG1300.3110.2830.1160.1610.5450.869
G2300.3050.2840.1460.1040.670
8000 PPG1300.2300.1870.1320.0660.5840.450
G2300.2580.2070.1570.0540.589
Legend: G1, group pre-surgery; G2, group post-surgery; PP, peak pressure; n, number of ears; SD, standard deviation; Min, minimum; Max, maximum; p-value, * p ≤ 0.05.
Table 5. Comparison between groups in terms of amplitude of transient evoked otoacoustic emissions in peak pressure and ambient pressure conditions in both groups (paired Student’s t-test).
Table 5. Comparison between groups in terms of amplitude of transient evoked otoacoustic emissions in peak pressure and ambient pressure conditions in both groups (paired Student’s t-test).
Frequency (Hz)
Condition		GroupnMeanMedianSDMinMaxp-Value
Amplitude (dBSPL)
1000 PP		G12914.2913.95.354.629.8* 0.015
G22912.1111.86.39−1.330.5
2000
PP		G12912.8113.23.75018.10.074
G22911.0811.94.050.717.1
3000
PP		G1297.408.15.03−418.10.233
G2296.617.34.60−3.618
4000
PP		G1291.013.35.07−10.7100.325
G2290.331.85.67−10.89.8
5000
PP		G129−7.53−7.,15.12−201.50.284
G229−8.28−85.52−172.1
1000
AP		G12914.1013.85.602.529.2* 0.002
G22911.7911.66.300.730.5
2000
AP		G12913.2113.43.806.923.10.511
G22917.8912.238.55−0.7217.3
3000
AP		G1297.497.94.99−6.418.20.095
G2296.567.14.73−3.118.9
4000
AP		G1291.102.95.20−1110.30.129
G2290.121.55.93−12.19.6
5000
AP		G129−7.58−75.47−19.420.534
G229−8.01−75.39−171.9
Legend: G1, group pre-surgery; G2, group post-surgery; PP, peak pressure; AP, ambient pressure; n, number of ears; SD, standard deviation; Min, minimum; Max, maximum; p-value, * p ≤ 0.05.
Table 6. Comparison between groups in terms of amplitude of otoacoustic emissions by distortion product, in peak pressure and ambient pressure conditions, in the both groups (Paired student t-test).
Table 6. Comparison between groups in terms of amplitude of otoacoustic emissions by distortion product, in peak pressure and ambient pressure conditions, in the both groups (Paired student t-test).
Frequency (Hz)
Condition		GroupnMeanMedianSDMinMaxp-Value
Amplitude (dBSPL)
500 PP		G1306.557.156.98−5.720.10.168
G2308.708.756.67−4.318.2
1000
PP		G13012.8013.554.724.722.30.557
G23013.1513.84.782.323.5
1500
PP		G13015.0415.45.314.125.20.897
G23015.1116.55.302.924
2000
PP		G13012.4412.454.992.522.30.286
G23013.0813.254.383.820.6
3000
PP		G13010.2410.354.471190.662
G23010.5211.74.242.417.4
4000
PP		G13011.4612.654.701.419.50.613
G23011.0912.455.35019.2
5000
PP		G13010.4411.45.60−4.918.40.210
G2309.0110.056.52−518.5
6000
PP		G1308.088.354.73−1.917.20.137
G2306.097.557.25−9.416.8
7000
PP		G1308.4310.256.21−8.8190.169
G2306.269.88.79−10.516.2
8000
PP		G129−0.59−0.37.93−18.517.10.081
G230−3.600.9511.39−22.712.8
9000
PP		G130−2.76−1.78.47−18.712.40.054
G229−6.64−4.311.37−37.19.4
10,000
PP		G130−3.26−3.49.07−21.919.40.061
G230−6.71−6.158.79−22.38.6
500
AP		G1296.658.26.59−11.618.50.241
G2298.729.97.21−16.117.6
1000
AP		G12911.7412.17.41−6.724.40.160
G22913.6613.95.312.825.1
1500
AP		G12913.9114.77.66−6.826.70.118
G22916.2017.24.855.124.3
2000
AP		G12915.2412.817.64−9.610.90.631
G22913.6713.94.363.821.4
3000
AP		G12910.7310.56.30−2.226.30.227
G22912.2211.55.142.325.6
4000
AP		G12912.3713.35.891.432.90.877
G22912.19136.210.230.2
5000
AP		G12911.9711.96.491.136.60.206
G22910.22106.54−6.421.8
6000
AP		G1299.958.67.380.941.60.818
G22910.879.821.11−13.1113.5
7000
AP		G1299.3510.77.55−8.9290.314
G2297.84129.23−14.920
8000
AP		G1292.163.610.66−16.9419* 0.048
G229−2.222.110.81−25.512.8
9000
AP		G129−1.13−2.210.82−21.237.3* 0.020
G229−5.98−3.410.60−28.29.6
10,000
AP		G129−2.26−2.411.92−29.12.50.077
G229−5.94−3.69.09−22.68
Legend: G1: group pre-surgery; G2: group post- surgery; PP: peak pressure; AP: ambient pressure; n: number of ears; SD: standard deviation; Min: minimum; Max: maximum; p-value: * p ≤ 0.05.
Table 7. Comparison between groups in terms of signal/noise of otoacoustic emissions by distortion product, in peak pressure and ambient pressure conditions, in the both groups (Paired student t-test).
Table 7. Comparison between groups in terms of signal/noise of otoacoustic emissions by distortion product, in peak pressure and ambient pressure conditions, in the both groups (Paired student t-test).
Frequency (Hz)
Condition		GroupnMeanMedianSDMinMaxp-Value
S/R (dB)
500 PP		G1306.337.45.43−8.812.30.262
G2304.495.456.86−9.315
1000
PP		G13016.1114.855.417.527* 0.017
G23019.7918.957.810.334.2
1500
PP		G13023.1422.255.2114.734.3* 0.002
G23026.9027.256.751241
2000
PP		G13023.1122.66.0110.234* <0.001
G23027.2427.25.2816.540.4
3000
PP		G13024.5623.95.0514.435.3* <0.001
G23028.9229.14.4119.436
4000
PP		G13039.873156.8415.8339.10.491
G23032.8533.46.4516.942.3
5000
PP		G12933.7234.47.1814.146.30.291
G23035.4637.756.961945.1
6000
PP		G13033.6833.656.002148.10.523
G23034.7836.78.0418.144.3
7000
PP		G13032.0332.257.3815.947.60.610
G23033.0235.758.7916.742.9
8000
PP		G13024.66238.246.441.90.582
G23023.4324.5512.05−3.242.3
9000
PP		G13023.4023.27.1713.6410.161
G23020.4521.3512.08−7.136.3
10,000
PP		G13018.4117.18.335.944.70.475
G23017.0716.39.200.532.4
500
AP		G1296.458.46.08−16.312.60.358
G2294.985.97.49−16.119.2
1000
AP		G12915.8516.35.62−0.925.9* 0.035
G22919.2020.58.341.935.2
1500
AP		G12922.1223.47.043.433.3* 0.020
G22926.5425.76.9613.437.8
2000
AP		G12922.8723.66.220.932* <0.001
G22928.1928.65.1615.338.8
3000
AP		G12925.2124.35.4916.334.1* <0.001
G22929.0429.64.8717.439.3
4000
AP		G12930.4330.65.5916.839.9* 0.023
G22932.3333.35.8420.941.6
5000
AP		G12935.1035.75.7321.844.90.752
G22935.5836.57.6419.346.3
6000
AP		G12934.7935.25.6525.146.60.869
G22935.0835.77.1918.444.9
7000
AP		G12933.1434.87.3613.646.50.709
G22933.7737.18.8314.344.4
8000
AP		G12926.5027.58.1212.242.10.450
G22924.8027.111.84−3.541.1
9000
AP		G12923.9125.77.689.437.50.221
G22921.3122.811.83−4.936.9
10,000
AP		G12917.5116.210.25−9.343.10.693
G22916.7319.39.950.331.1
Legend: G1: group pre-surgery; G2: group post- surgery; PP: peak pressure; AP: ambient pressure; n: number of ears; SD: standard deviation; Min: minimum; Max: maximum; p-value: * p ≤ 0.05.
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Sanches, A.B.; Sanfins, M.D.; Skarzynski, P.H.; Skarżyńska, M.B.; Penatti, H.C.; Donadon, C.; Souza, I.P.d.; Silva, I.V.d.; Colella-Santos, M.F. Wideband Tympanometry and Pressurized Otoacoustic Emissions in Children with Surgical Excision of Palatine and/or Pharyngeal Tonsils. Brain Sci. 2024, 14, 598. https://doi.org/10.3390/brainsci14060598

AMA Style

Sanches AB, Sanfins MD, Skarzynski PH, Skarżyńska MB, Penatti HC, Donadon C, Souza IPd, Silva IVd, Colella-Santos MF. Wideband Tympanometry and Pressurized Otoacoustic Emissions in Children with Surgical Excision of Palatine and/or Pharyngeal Tonsils. Brain Sciences. 2024; 14(6):598. https://doi.org/10.3390/brainsci14060598

Chicago/Turabian Style

Sanches, Aline Buratti, Milaine Dominici Sanfins, Piotr Henryk Skarzynski, Magdalena Beata Skarżyńska, Henrique Costa Penatti, Caroline Donadon, Ingrid Pereira de Souza, Ingridy Vitoria da Silva, and Maria Francisca Colella-Santos. 2024. "Wideband Tympanometry and Pressurized Otoacoustic Emissions in Children with Surgical Excision of Palatine and/or Pharyngeal Tonsils" Brain Sciences 14, no. 6: 598. https://doi.org/10.3390/brainsci14060598

APA Style

Sanches, A. B., Sanfins, M. D., Skarzynski, P. H., Skarżyńska, M. B., Penatti, H. C., Donadon, C., Souza, I. P. d., Silva, I. V. d., & Colella-Santos, M. F. (2024). Wideband Tympanometry and Pressurized Otoacoustic Emissions in Children with Surgical Excision of Palatine and/or Pharyngeal Tonsils. Brain Sciences, 14(6), 598. https://doi.org/10.3390/brainsci14060598

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