Audiological assessment and otoacoustic emissions in patients with head and neck cancer

Fukazawa, Pâmela; Santos, Sarah da Silva; Fontanelli, Raquel Caroline Ferreira Lopes; Gil, Daniela

doi:10.1590/1982-0216/20202248719

ABSTRACT

Purpose:

to describe the audiological and otoacoustic emission findings in patients who had head and neck cancer and compare them with individuals without the disease.

Methods:

a comparative, cross-sectional, observational study encompassing two groups: Study: individuals with a history of head and neck cancer, submitted to chemotherapy and/or radiotherapy; Control: individuals without the disease. The sample comprised 23 individuals in each group, matched for age and gender. Procedures in which the groups were compared: meatoscopy; pure-tone threshold and high-frequency audiometry; speech audiometry; transient-evoked otoacoustic emissions. Statistical tests: Pearson’s chi-square; Fisher’s exact; two-proportion Z-test; Wilcoxon; Mann-Whitney; Student’s t-test.

Results:

the comparison between the groups revealed statistically significant differences at the 3, 6, 8, 10, and 12.5 kHz frequencies in the pure-tone threshold audiometry, with better pure-tone auditory thresholds in the control group. No significant differences were observed between the groups in the otoacoustic emissions regarding the general response and frequency band.

Conclusion:

individuals with a history of head and neck cancer had higher pure-tone auditory thresholds than their controls, especially at the higher frequencies. This evidences the deleterious effect of ototoxicity on the peripheral auditory system of adults. The otoacoustic emissions were similar in the two groups.

Keywords:
Hearing; Head and Neck Neoplasias; Chemotherapy; Radiotherapy; Auditory Tests

RESUMO

Objetivo:

descrever os achados audiológicos e das emissões otoacústicas em pacientes com câncer de cabeça e pescoço e compará-los com indivíduos sem a doença.

Métodos:

estudo observacional transversal comparativo realizado em dois grupos: Estudo: indivíduos com histórico de câncer de cabeça e pescoço submetidos à quimioterapia e/ou radioterapia; Controle: indivíduos sem a doença. A amostra foi composta por 23 indivíduos em cada grupo, pareados considerando idade e gênero. Procedimentos: meatoscopia; audiometria tonal liminar e de altas frequências; logoaudiometria e emissões otoacústicas evocadas transientes, comparados entre os grupos. Testes estatísticos: Qui-quadrado de Pearson; exato de Fisher; igualdade de duas proporções; Wilcoxon; Mann-Whitney e t de Student.

Resultados:

a comparação entre os grupos revelou diferença estatisticamente significante nas frequências de 3, 6, 8, 10 e 12,5kHz na audiometria tonal liminar, com melhores limiares auditivos tonais no grupo controle. Não foram observadas diferenças significantes entre os grupos nas emissões otoacústicas, quanto a resposta geral e banda de frequência.

Conclusão:

indivíduos com histórico de câncer de cabeça e pescoço apresentam limiares auditivos tonais mais elevados do que seus controles, sobretudo nas frequências altas, evidenciando o efeito deletério da ototoxicidade no sistema auditivo periférico de adultos. As emissões otoacústicas mostraram-se semelhantes nos dois grupos.

Descritores:
Audição; Neoplasias de Cabeça e Pescoço; Quimioterapia; Radioterapia; Testes Auditivos

Introduction

Cancer is a disease that results from a variety of chemical, physical, and viral factors, in most of the cases causing permanent and irreversible alterations in a certain proportion of the cells in the organism¹1. Lydiatt WM, Patel SG, O'Sullivan B, Brandwein MS, Ridge JA, Migliacci JC et al. Head and neck cancers - major changes in the American Joint Committee on Cancer Eighth Edition Cancer Staging Manual. CA Cancer J Clin. 2017;67(2):122-37.. According to the National Cancer Institute (Instituto Nacional do Câncer - INCA), of the Brazilian Ministry of Health, head and neck cancer ranks fifth among the most frequent neoplasias, with a worldwide incidence estimated at 780,000 new cases per year²2. Instituto Nacional de Câncer José Alencar Gomes da Silva, Copyright (c) 1996 - 2016 INCA - Ministério da Saúde. [cited 2019 Jul18] Available from: http://www2.inca.gov.br/wps/wcm/connect/tiposdecancer/site/home/laringe
http://www2.inca.gov.br/wps/wcm/connect/... .

Laryngeal cancer, one of the most common of those affecting the head and neck region, occurs predominantly in men³3. Licitra L, Bernier J, Grandi C, Locati L, Merlano M, Gatta G, Lefebvre JL. Cancer of the larynx. Critical Reviews in Oncology/hematology. 2003;47(1):65-80.. It represents approximately 25% of the malignant tumors affecting this region and 2% of all malignant diseases. The number of new cases is estimated at 7,350 - 6,360 in men and 990 in women - and the death toll is 4,141 - 3,635 men and 506 women²2. Instituto Nacional de Câncer José Alencar Gomes da Silva, Copyright (c) 1996 - 2016 INCA - Ministério da Saúde. [cited 2019 Jul18] Available from: http://www2.inca.gov.br/wps/wcm/connect/tiposdecancer/site/home/laringe
http://www2.inca.gov.br/wps/wcm/connect/... .

Regarding etiology, smoking stands out as the main risk factor; when it is combined with alcoholism, the risk is potentialized. There are other aggravating factors, such as family history, bad eating habits, unfavorable socioeconomic conditions, chronic inflammation of the larynx caused by gastroesophageal reflux, human papillomavirus (HPV), exposure to chemical products and pollution⁴4. Wünsch V. The epidemiology of laryngeal cancer in Brazil. Sao Paulo Med. J. 2004;122(5):188-94..

Traditionally, cases of laryngeal cancer are treated through surgery, radiotherapy, and chemotherapy, either alone or in combination⁵5. Vilar CMC, Martins IM. Câncer de cabeça e pescoço. In: Vieira SC, Lustosa AML, Barbosa CNB, Teixeira JMRT, Brito LXE, Soares LFM et al. (eds). Oncologia básica. 1. ed. Teresina, PI: Fundação Quixote, 2012. p.9-22.. The surgical treatment involves the total or partial resection of the larynx, depending on how severely the lesion has affected the organ. The partial resection surgery is called partial laryngectomy⁶6. Vilar CMC, Martins IM. Princípios de cirurgia oncológica. In: Vieira SC, Lustosa AML, Barbosa CNB, Teixeira JMRT, Brito LXE, Soares LFM et al. (eds). Oncologia básica. 1. ed. Teresina, PI: Fundação Quixote, 2012. p.221-36.. Its purpose is to maintain the integrity of the laryngeal functions, such as ventilation, protection of the upper respiratory tract, sphincteric functions, and phonation; the greatest deficit is in swallowing. The total resection surgery, named total laryngectomy⁶6. Vilar CMC, Martins IM. Princípios de cirurgia oncológica. In: Vieira SC, Lustosa AML, Barbosa CNB, Teixeira JMRT, Brito LXE, Soares LFM et al. (eds). Oncologia básica. 1. ed. Teresina, PI: Fundação Quixote, 2012. p.221-36., consists of removing the laryngeal structures, with great damage especially to phonation, due to the loss of the laryngeal voice.

In chemotherapeutic treatment, drugs such as aminoglycosides, carboplatin, vincristine, cisplatin, and others can be used⁷7. Crisanto MLLP. Princípios de Quimioterapia. In: Vieira SC, Lustosa AML, Barbosa CNB, Teixeira JMRT, Brito LXE, Soares LFM, Ferreira MAT et al. (eds). Oncologia básica. 1. ed. Teresina, PI: Fundação Quixote, 2012. p.237-52.. These drugs are considered highly toxic to the auditory system⁸8. Oliveira PF, Oliveira CS, Andrade JS, Santos TFC, Oliveira-Barreto AC. Tratamento oncológico na determinação das alterações auditivas. Braz. j. otorhinolaryngol. 2016;82(1):65-9.. The cisplatin, discovered by Rosenberg et al.⁹9. Rosenberg B, Van Camp L, Krigas T. Inhibition of cell division in escherichia coli by electrolysis products from a platinum electrode. Nature. 1965;205(4972):698-9., is currently used with great effectiveness in the treatment of head and neck tumors. One of its side effects, though, is the degeneration of the hair cells in the basal region of the cochlea¹⁰10. Abdollahi H, Mostafaei S, Cheraghi S, Shiri I, Mahdavi SR, Kazemnejad A. Cochlea CT radiomics predicts chemoradiotherapy induced sensorineural hearing loss in head and neck cancer patients: A machine learning and multi-variable modeling study. Phys Med. 2018;45:192-7., with the potential to impair the whole cochlea.

The hearing losses caused by ototoxic antineoplastic drugs are definitive and irreversible¹¹11. Hyppolito MA, Oliveira JAA. Ototoxicidade, otoproteção e autodefesa das células ciliadas da cóclea. Medicina. 2005;38(3/4):279-89.. First, it affects the base of the cochlea, resulting primarily in a loss at high frequencies; therefore, the audiological assessment must include high frequencies¹²12. Garcia AP, Iório MCM, Petrilli AS. Monitoramento da audição de pacientes expostos à cisplatina. Rev. Bras. Otorrinolaringol. 2003;69(2):215-21..

The radiotherapeutic treatment¹³13. Ng SP, Pollard C, Berends J, Ayoub Z, Kamal M, Garden AS et al. Usefulness of surveillance imaging in patients with head and neck cancer who are treated with definitive radiotherapy. Cancer. 2019;125(11):1823-9. - which uses an ionizing radiation beam - aims to remove all tumorous cells with the least possible damage to the surrounding normal cells⁵5. Vilar CMC, Martins IM. Câncer de cabeça e pescoço. In: Vieira SC, Lustosa AML, Barbosa CNB, Teixeira JMRT, Brito LXE, Soares LFM et al. (eds). Oncologia básica. 1. ed. Teresina, PI: Fundação Quixote, 2012. p.9-22.. However, due to the high anatomical complexity of the head and neck region, it is difficult to exclude certain structures in the area being treated²2. Instituto Nacional de Câncer José Alencar Gomes da Silva, Copyright (c) 1996 - 2016 INCA - Ministério da Saúde. [cited 2019 Jul18] Available from: http://www2.inca.gov.br/wps/wcm/connect/tiposdecancer/site/home/laringe
http://www2.inca.gov.br/wps/wcm/connect/... . Since the components of the auditory system are located nearby the regions affected by head and neck cancers, they can receive radiation even though they are not the target organ - which can lead to hearing loss²2. Instituto Nacional de Câncer José Alencar Gomes da Silva, Copyright (c) 1996 - 2016 INCA - Ministério da Saúde. [cited 2019 Jul18] Available from: http://www2.inca.gov.br/wps/wcm/connect/tiposdecancer/site/home/laringe
http://www2.inca.gov.br/wps/wcm/connect/... ^,⁷7. Crisanto MLLP. Princípios de Quimioterapia. In: Vieira SC, Lustosa AML, Barbosa CNB, Teixeira JMRT, Brito LXE, Soares LFM, Ferreira MAT et al. (eds). Oncologia básica. 1. ed. Teresina, PI: Fundação Quixote, 2012. p.237-52.^,⁸8. Oliveira PF, Oliveira CS, Andrade JS, Santos TFC, Oliveira-Barreto AC. Tratamento oncológico na determinação das alterações auditivas. Braz. j. otorhinolaryngol. 2016;82(1):65-9..

The oncological patients present greatly varying hearing loss results, ranging from 29% to 61% - some individuals with hearing loss are even classified as normal hearing in some of the post-oncological treatment assessment criteria¹⁴14. Schultz C, Goffi-Gomez MV, Liberman PH, Carvalho AL. Report on hearing loss in oncology. Braz. j. otorhinolaryngol. 2009;75(5):634-41.. Hence, it is important to detect hearing loss early through audiological assessment procedures with high sensitivity to identify medication-induced auditory alterations¹⁵15. Jacob LCB, Aguiar FP, Tomiasi AA, Tschoeke SN, Bitencourt RF. Monitoramento auditivo na ototoxidade. Rev. Bras. Otorrinolaringol. 2006;72(6):836-44..

Hearing loss is more likely to occur when the patient is submitted to a treatment combining radiotherapy and chemotherapy⁸8. Oliveira PF, Oliveira CS, Andrade JS, Santos TFC, Oliveira-Barreto AC. Tratamento oncológico na determinação das alterações auditivas. Braz. j. otorhinolaryngol. 2016;82(1):65-9.. The ototoxicity of the medications together with the radiation may cause irreversible hearing loss, either early or late, thus impairing the patient’s quality of life¹¹11. Hyppolito MA, Oliveira JAA. Ototoxicidade, otoproteção e autodefesa das células ciliadas da cóclea. Medicina. 2005;38(3/4):279-89.^,¹²12. Garcia AP, Iório MCM, Petrilli AS. Monitoramento da audição de pacientes expostos à cisplatina. Rev. Bras. Otorrinolaringol. 2003;69(2):215-21..

The patients submitted to partial laryngectomy have their glottis’ histological architecture changed, causing a deficiency in glottal coaptation, which leads to vocal disorders. The main functional impacts caused by partial laryngectomy are breathy voice, low intensity, phonation difficulty, and decreased maximum phonation time. Because of these impacts, a speech-language-hearing therapist - whose role is to help the patient produce their best voice - is made necessary. Speech-language-hearing rehabilitation is based on adapting the functions to the anatomo-functional limits imposed by the treatment a patient was submitted to, aiming to achieve their best possible adaptation for an improved quality of life. Having their hearing preserved is a greatly important factor for such an adaptation to be successful, since it would allow the patient a better sound perception for self-monitoring, reflecting positively on the therapeutic process.

In the case of patients with head and neck cancer, oral cavity cancer, and/or who have been partially laryngectomized, submitted to chemotherapeutic and/or radiotherapeutic treatment¹⁵15. Jacob LCB, Aguiar FP, Tomiasi AA, Tschoeke SN, Bitencourt RF. Monitoramento auditivo na ototoxidade. Rev. Bras. Otorrinolaringol. 2006;72(6):836-44.

16. Fausti SA, Frey RH, Henry JA, Olson J, Schaffer HI. High-frequency testing techniques and instrumentation for early detection of ototoxicity. Journal Rehabilitation Res Development. 1993;30(3):333-41.^-¹⁷17. Damian PI, Valverde TA, Guimarães DP, Gil D. Auditory monitoring in adults undergoing chemotherapy with carboplatin. Distúrb Comun. 2017;29(3):438-47., the audiological assessment and otoacoustic emissions is greatly relevant, as they identify lesions in the outer hair cells¹⁸18. Dunckley KT, Dreisbach LE. Gender effects on high-frequency distortion product otoacoustic emissions in humans. Ear Hear. 2004;25(6):554-64.

19. Littman TA, Magruder A, Strother DR. Monitoring and predicting ototoxic damage using distortion-product otoacoustic emissions: pediatric case study. J Am Acad Audiol. 1998;9(4):257-62.

20. Yardley MP, Davies CM, Stevens JC. Use of transient evoked otoacoustic emissions to detect and monitor cochlear damage caused by platinum-containing drugs. Br J Audiol. 1998;32(5):305-16.^-²¹21. Almeida EOC, Costa CB, Oliveira SRT, Umeoka MTH. Audiometria tonal e emissões otoacústicas - produtos de distorção em pacientes tratados com cisplatina. Arq. Int. Otorrinolaringol. 2006;10(3):203-8.. Authors point out that no statistically significant values were found for the amplitude of the otoacoustic emissions in adults submitted to carboplatin chemotherapy. Nonetheless, the audibility thresholds worsened, especially in the high frequencies¹⁷17. Damian PI, Valverde TA, Guimarães DP, Gil D. Auditory monitoring in adults undergoing chemotherapy with carboplatin. Distúrb Comun. 2017;29(3):438-47..

The audiological assessment data enables alterations to be identified, to which hearing aids can be indicated. This minimizes the impact hearing loss has on the person’s quality of life, as hearing is essential to communication and so to social interaction adjustment.

Despite the growing number of people submitted to these types of surgeries and/or radiotherapy and chemotherapy every year, there is a shortage of studies in the literature regarding the auditory consequences of radiotherapy, either alone or in combination with chemotherapy.

This study aimed to compare the results of the pure-tone audiometry, high-frequency audiometry, speech audiometry, and transient-evoked otoacoustic emissions in adults with and without a history of head and neck cancer.

Methods

This research was presented, analyzed, and approved by the Research Ethics Committee of UNIFESP (Universidade Federal de São Paulo) in its first versions under the numbers 1214/2015 and 1215/2015. It was a prospective study, conducted at the Speech-Language-Hearing Department of the Universidade Federal de São Paulo, São Paulo, Brazil, in the Hearing Disorders and Human Communication Disorders courses.

This comparative, cross-sectional, observational study involved two groups - SG (study group) and CG (control group) - matched for gender and age. Initially, the protocols of the patients with head and neck cancer receiving care at the institution of origin were analyzed to comprise the SG.

The inclusion criteria for this group were patients aged between 30 and 80 years, both male and female, with type A tympanometry curve, no history of alteration in the middle ear, and a positive history of primary head and neck cancer, submitted to chemotherapy and/or radiotherapy.

The inclusion criteria for the control group were the type A tympanometry curve, no history of alteration in the middle ear, no history of cancer, and no use of ototoxic medications and/or drugs.

The exclusion criteria for both groups were evident or diagnosed cognitive and/or psychiatric alterations, a positive otologic history, and the use of hearing aid.

The convenience sample comprised 46 individuals - 23 with a history of cancer, submitted to chemotherapy and/or radiotherapy; and 23 without a positive history of cancer - aged between 30 and 80 years. The control group was matched for gender and age.

The patients who met the inclusion criteria were contacted and signed the Informed Consent Form.

First, the audiological anamnesis was conducted to collect personal aspects of each patient, such as identification, previous history, and possible auditory complaints.

The following procedures were conducted: meatoscopy, pure-tone audiometry (250 to 8000 Hz), high-frequency audiometry (10,000, 12,000, 14,000 Hz), speech audiometry, acoustic immittance, and transient-evoked otoacoustic emissions (TEOAE).

The external acoustic meatus (EAM) was visually inspected with an otoscope to verify whether there was any outer ear obstruction.

The pure-tone threshold audiometry was conducted in a sound booth with supra-aural earphones²²22. American Speech-Language-Hearing Association. (1988). Determining threshold level for speech [Guidelines]. [cited 2019 Nov29] Available from: http://www.asha.org/policy.
http://www.asha.org/policy... . The audiometric examination was made with an Itera II audiometer, beginning at the 1000 Hz frequency, followed by 2000, 3000, 4000, 6000, 8000, 500, and 250 Hz frequencies, in this order, with supra-aural earphones (TDAH-39). The auditory thresholds for the 10,000, 12,000, and 14,000 Hz frequencies were obtained using the same procedure of the pure-tone audiometry, with circumaural earphones (HDA-200).

The hearing was considered within normality standards when the mean of the 500, 1000, and 2000 Hz frequencies was better than or equal to 25 dB. In the case of hearing loss, its degree was classified according to the method by Lloyd and Kaplan²³23. Lloyd L, Kaplan H. Audiometric interpretation: a manual of basic audiometry. Press, 1978..

The speech audiometry procedures - encompassing the Speech Reception Threshold (SRT) and Word Recognition Score (WRS) - were conducted via live voice while the patient was in the sound booth. In the WRSI, the patient was instructed to repeat monosyllable words presented at the constant level of 40 dB above the mean of the pure-tone thresholds at 500, 1000, and 2000 Hz. Repeating correctly the 25 monosyllable words was worth 100%; for each mistake made by the patient, 4% was subtracted from that total. Individuals without oral communication were instructed to point to images - bread, hand, foot, honey, salt, flower, sea, soccer goal, shovel, and tea - as required by the assessor. The total of the 20 images was worth 100%; for each mistake made by the patient, 5% was subtracted from that total. The equipment used was the Itera II audiometer.

The TEOAE was picked up by a probe with a microphone placed in the external acoustic meatus, sealed with a latex tip. It was conducted in a sound booth through an Ilo92 device. The evoking stimulus was kept between 75 and 85 dB peSPL. The frequency bands surveyed were 1000, 2000, 3000, and 4000 Hz. The criteria employed to consider the presence of response in the transient-evoked otoacoustic emissions test were those of Finitzo²⁴24. Finitzo T, Albright K, Oneal J. The newborn with hearing loss: detection in the nursery. Pediatrics. 1998;102(6):1452-60.: response amplitude (signal-to-noise ratio) equal to or above 3 dB SPL, at the frequency bands of 1000, 2000, 3000, and 4000 Hz; general reproducibility equal to or above 50%; probe stability equal to or above 70%; A and B wave overlap by visual inspection.

The following statistical tests were used for the comparison between the groups: Pearson’s chi-square, two-proportion Z-test, Wilcoxon signed-rank test, Mann-Whitney test, and the parametric Student’s t-test. The significance level adopted was p < 0.05 (5%). The confidence intervals developed throughout the paper were considered with 95% of statistical reliability.

Results

A total of 46 individuals participated in this study - 23 with a history of head and neck cancer submitted to chemotherapy and/or radiotherapy, and 23 without a positive history of cancer, matched for age (Student’s t-test, p > 0.999). Their age ranged from 32 to 80 years; the mean age was 59 years; median, 58 years; standard deviation, 12.89 years; the youngest age was 32, and the oldest, 80 years; the confidence interval was 53.73 - 64.88 years.

As for the frequency distribution regarding gender and type of treatment in the groups studied, it was observed that males were predominant in the study group, as well as chemotherapy and combined treatment with radiotherapy and chemotherapy, in equal proportion. The SG and CG were matched for age and gender (Table 1).

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Table 1:
Characterization of the Study Group regarding gender and type of treatment

There was no statistical significance in either of the variables - i.e., the sample proved to be homogeneous for both variables. Hence, the sample comprised predominantly male adults, whose most frequent treatments were both chemotherapy and combined radiotherapy and chemotherapy. The time of treatment ranged from 6 to 36 sessions.

The comparison between the study and control groups concerning pure-tone thresholds, using Student’s t-test, is shown in Table 2.

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Table 2:
Comparison between the Study Group and Control Group regarding the pure-tone auditory thresholds, in dB HL, obtained in the pure-tone threshold audiometry

The observation revealed statistically significant differences between the groups at the 3000, 6000, 8000, 10,000, and 12,500 Hz frequencies in the pure-tone threshold audiometry. The comparison of the 46 ears in the SG and the 46 ears in the CG in relation to the pure-tone auditory thresholds obtained in the pure-tone threshold audiometry is presented in Figure 1.

Figure 1:
Comparison of the means and standard deviations of the pure-tone auditory thresholds, in dB HL, obtained in the pure-tone threshold audiometry between the Study Group and Control Group

No statistically significant differences were observed between the groups for the percentage of correct answers in the WRS with monosyllable words (p = 0.508), using the Student’s t-test and Mann-Whitney U-test to compare the groups. The SG presented a performance of 90.13% on average, with a standard deviation of 13.59%; the CG’s performance was 91.83%, with a standard deviation of 12.39%. The median was 96% for both groups.

In the sequence, the comparative table between SG and CG in the transient-evoked otoacoustic emissions, using Student’s t-test, is presented (Table 3).

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Table 3:
Descriptive comparison measures between Study Group and Control Group regarding response amplitude based on the signal-to-noise ratio in the research of transient-evoked otoacoustic emissions

No statistically significant differences were observed between the groups for any of the parameters assessed in the TEOAE research. Thus, in this study’s sample, both the SG and CG had a similar performance in the TEOAE research.

Discussion

In this study, 23 patients with a positive history of head and neck cancer submitted to chemotherapy and/or radiotherapy were assessed. Also, a control group was formed with 23 individuals matched for gender and age.

The age range encompassed in the study went from 32 to 80 years, with a mean age of 59 years - i.e., an adult population. The sample had a predominance of males, as there were 9 women (39.1%) and 14 men (60.9%) (Table 1). The characteristics of the sample were compared with the data in the literature, and an agreement was observed regarding age and gender for head and neck cancer. According to data from the American Cancer Society²⁵25. American Cancer Society. Clinical Oncology. Atlanta: ACS; 2001., this type of neoplasia affects predominantly the age group above 50 years, in a proportion of four men to one woman.

The predominant treatments in the sample were the combined radiotherapy and chemotherapy (34.8%), and chemotherapy alone (34.8%), whereas there were 30.4% of radiotherapy alone (Table 1). According to the literature, the ideal treatment must be defined by consensus between the head and neck surgeon, the oncologist, and the radiotherapist. They must determine the best therapeutic option according to the type, place, and severity of the tumor, and avoid unnecessary procedures²2. Instituto Nacional de Câncer José Alencar Gomes da Silva, Copyright (c) 1996 - 2016 INCA - Ministério da Saúde. [cited 2019 Jul18] Available from: http://www2.inca.gov.br/wps/wcm/connect/tiposdecancer/site/home/laringe
http://www2.inca.gov.br/wps/wcm/connect/... .

Moreover, Menezes²⁶26. Menezes M. Efeitos da radioterapia sobre a audição em pacientes portadores de tumores de cabeça e pescoço [monografia]. Recife (PE): CEFAC; 1999. observed that when the patient is submitted to the combined treatment (i.e., chemotherapy and radiotherapy), the chances of alteration in the audiometric threshold is potentialized, as opposed to what happens when either treatment is used alone. In this research, regarding the descriptive comparison measures of pure-tone auditory thresholds between the study and control groups, quantitatively, statistically significant values were observed at the 3000, 6000, 8000, 10,000, and 12,500 Hz frequencies, with worse thresholds in the study group (Table 2).

Qualitatively, the auditory thresholds of the individuals in the study group were compared to those of the control group, and an increase was observed in most of the high frequencies. Such results are similar to the data from Fausti et al.¹⁶16. Fausti SA, Frey RH, Henry JA, Olson J, Schaffer HI. High-frequency testing techniques and instrumentation for early detection of ototoxicity. Journal Rehabilitation Res Development. 1993;30(3):333-41., Littman et al.¹⁹19. Littman TA, Magruder A, Strother DR. Monitoring and predicting ototoxic damage using distortion-product otoacoustic emissions: pediatric case study. J Am Acad Audiol. 1998;9(4):257-62., Yardley et al.²⁰20. Yardley MP, Davies CM, Stevens JC. Use of transient evoked otoacoustic emissions to detect and monitor cochlear damage caused by platinum-containing drugs. Br J Audiol. 1998;32(5):305-16., Jacob et al.¹⁵15. Jacob LCB, Aguiar FP, Tomiasi AA, Tschoeke SN, Bitencourt RF. Monitoramento auditivo na ototoxidade. Rev. Bras. Otorrinolaringol. 2006;72(6):836-44., and Schultz et al.¹⁴14. Schultz C, Goffi-Gomez MV, Liberman PH, Carvalho AL. Report on hearing loss in oncology. Braz. j. otorhinolaryngol. 2009;75(5):634-41., who reported the auditory alteration caused by ototoxic medications that impaired the high frequencies on the base of the cochlea, with possible evolution to the apex, posteriorly impairing the medium and low frequencies. Such findings reinforce that medication ototoxicity in combination with radiation can lead to irreversible hearing loss, either early or late, after the treatment has finished.

Furthermore, Almeida et al.²¹21. Almeida EOC, Costa CB, Oliveira SRT, Umeoka MTH. Audiometria tonal e emissões otoacústicas - produtos de distorção em pacientes tratados com cisplatina. Arq. Int. Otorrinolaringol. 2006;10(3):203-8. observed that the patients who were submitted to cisplatin chemotherapy in combination with other chemotherapeutic drugs had auditory alterations even at 1000 Hz, and more significant impairment beginning at 6000 Hz. Likewise, in this study significantly worse auditory alterations were observed in the comparison with the control group beginning at 6000 Hz (Table 2).

The authors¹⁵15. Jacob LCB, Aguiar FP, Tomiasi AA, Tschoeke SN, Bitencourt RF. Monitoramento auditivo na ototoxidade. Rev. Bras. Otorrinolaringol. 2006;72(6):836-44.^,²¹21. Almeida EOC, Costa CB, Oliveira SRT, Umeoka MTH. Audiometria tonal e emissões otoacústicas - produtos de distorção em pacientes tratados com cisplatina. Arq. Int. Otorrinolaringol. 2006;10(3):203-8. also reported that in the comparison of results between conventional pure-tone audiometry and high-frequency audiometry, this last one was more sensitive to early detect auditory alterations. Nevertheless, this study revealed (Table 2) that the conventional audiometry had been sensitive to early detect auditory alterations, which was observed with the diagnosis of hearing loss beginning at the 3000 Hz frequency.

Regarding the speech recognition percentage index, neither group presented quantitative alteration, corroborating the findings of the pure-tone threshold audiometry. No statistically significant differences were observed between the groups for the percentage of right answers in the WRS with monosyllable words. These results are compatible with pure-tone threshold alterations in both groups. Authors¹⁷17. Damian PI, Valverde TA, Guimarães DP, Gil D. Auditory monitoring in adults undergoing chemotherapy with carboplatin. Distúrb Comun. 2017;29(3):438-47. pointed out that the impairment caused by chemotherapy occurs predominantly at the high frequencies - which, with the intensity used to apply the test (40 dB SL above the three-frequency mean), does not significantly impair speech.

Almeida et al.²¹21. Almeida EOC, Costa CB, Oliveira SRT, Umeoka MTH. Audiometria tonal e emissões otoacústicas - produtos de distorção em pacientes tratados com cisplatina. Arq. Int. Otorrinolaringol. 2006;10(3):203-8. presented results of the distortion-product otoacoustic emissions research that agreed with the thresholds found in the pure-tone audiometry. As for this study, when the descriptive measures of the transient-evoked otoacoustic emissions were compared between the study and control groups, quantitatively, no statistically significant differences were observed between the groups for any of the parameters assessed by the TEOAE research. Hence, in this study’s sample, both the SG and the CG had similar performance in the TEOAE research (Table 3), revealing responses with lower signal-to-noise ratio at the high frequencies (3000 and 4000 Hz) when compared with the other frequencies. In contrast with the described studies, this one presented pure-tone threshold alteration beginning at 3000 Hz; however, it did not reveal alteration in the assessment of the outer hair cells functioning.

Nonetheless, Garcia et al.¹²12. Garcia AP, Iório MCM, Petrilli AS. Monitoramento da audição de pacientes expostos à cisplatina. Rev. Bras. Otorrinolaringol. 2003;69(2):215-21., who monitored the TEOAE in patients with osteosarcoma treated with cisplatin, found an increase in the high-frequency auditory thresholds and response amplitude in the low-level otoacoustic emissions. Garcia et al.¹²12. Garcia AP, Iório MCM, Petrilli AS. Monitoramento da audição de pacientes expostos à cisplatina. Rev. Bras. Otorrinolaringol. 2003;69(2):215-21.⁾ described an increase in the amplitude of the emissions when compared with the signal-to-noise ratio between the doses of cisplatin, after a small dosage of cisplatin, probably due to the chemical changes (calcium and magnesium metabolism) caused by cisplatin in the hair cells. This leads to an increase in the intracellular level of calcium as a consequence of the absence of its antagonist (the magnesium), increasing the permeability of the cytoplasmatic membrane. This mobility of the hairs in the outer hair cells depends on the intracellular calcium. Hence, it can cause an increase in the otoacoustic emissions - which can be an initial indication of a lesion in (and posterior death of) the cell.

The ototoxicity caused by chemotherapy⁹9. Rosenberg B, Van Camp L, Krigas T. Inhibition of cell division in escherichia coli by electrolysis products from a platinum electrode. Nature. 1965;205(4972):698-9.^,¹¹11. Hyppolito MA, Oliveira JAA. Ototoxicidade, otoproteção e autodefesa das células ciliadas da cóclea. Medicina. 2005;38(3/4):279-89.^,¹²12. Garcia AP, Iório MCM, Petrilli AS. Monitoramento da audição de pacientes expostos à cisplatina. Rev. Bras. Otorrinolaringol. 2003;69(2):215-21.^,¹⁵15. Jacob LCB, Aguiar FP, Tomiasi AA, Tschoeke SN, Bitencourt RF. Monitoramento auditivo na ototoxidade. Rev. Bras. Otorrinolaringol. 2006;72(6):836-44.^,¹⁷17. Damian PI, Valverde TA, Guimarães DP, Gil D. Auditory monitoring in adults undergoing chemotherapy with carboplatin. Distúrb Comun. 2017;29(3):438-47.^,¹⁹19. Littman TA, Magruder A, Strother DR. Monitoring and predicting ototoxic damage using distortion-product otoacoustic emissions: pediatric case study. J Am Acad Audiol. 1998;9(4):257-62.

20. Yardley MP, Davies CM, Stevens JC. Use of transient evoked otoacoustic emissions to detect and monitor cochlear damage caused by platinum-containing drugs. Br J Audiol. 1998;32(5):305-16.^-²¹21. Almeida EOC, Costa CB, Oliveira SRT, Umeoka MTH. Audiometria tonal e emissões otoacústicas - produtos de distorção em pacientes tratados com cisplatina. Arq. Int. Otorrinolaringol. 2006;10(3):203-8.^,²⁷27. Yasui N, Adachi N, Kato M, Koh K, Asanuma S, Sakata H et al. Cisplatin-induced Hearing Loss. J Pediatr Hematol Oncol. 2014;36(4):e241-5. and radiotherapy⁸8. Oliveira PF, Oliveira CS, Andrade JS, Santos TFC, Oliveira-Barreto AC. Tratamento oncológico na determinação das alterações auditivas. Braz. j. otorhinolaryngol. 2016;82(1):65-9.^,¹⁰10. Abdollahi H, Mostafaei S, Cheraghi S, Shiri I, Mahdavi SR, Kazemnejad A. Cochlea CT radiomics predicts chemoradiotherapy induced sensorineural hearing loss in head and neck cancer patients: A machine learning and multi-variable modeling study. Phys Med. 2018;45:192-7.^,¹⁴14. Schultz C, Goffi-Gomez MV, Liberman PH, Carvalho AL. Report on hearing loss in oncology. Braz. j. otorhinolaryngol. 2009;75(5):634-41.^,²⁶26. Menezes M. Efeitos da radioterapia sobre a audição em pacientes portadores de tumores de cabeça e pescoço [monografia]. Recife (PE): CEFAC; 1999.^,²⁸28. Driessen CML, Leijendeckers J, Snik A, Graaf WTA, Boer JP, Gelderblom H et al. Ototoxicity in locally advanced head and neck cancer patients treated with induction chemotherapy followed by intermediate or high-dose cisplatin-based chemoradiotherapy. Head & Neck. 2019;41(2):488-94. is a serious issue, which could set a limit to the dosage¹²12. Garcia AP, Iório MCM, Petrilli AS. Monitoramento da audição de pacientes expostos à cisplatina. Rev. Bras. Otorrinolaringol. 2003;69(2):215-21.^,²⁷27. Yasui N, Adachi N, Kato M, Koh K, Asanuma S, Sakata H et al. Cisplatin-induced Hearing Loss. J Pediatr Hematol Oncol. 2014;36(4):e241-5.^,²⁸28. Driessen CML, Leijendeckers J, Snik A, Graaf WTA, Boer JP, Gelderblom H et al. Ototoxicity in locally advanced head and neck cancer patients treated with induction chemotherapy followed by intermediate or high-dose cisplatin-based chemoradiotherapy. Head & Neck. 2019;41(2):488-94.. Although influenced by such factors as the age and initial hearing conditions (before making use of the medications), there is also an influence from the genes related to processing the medications. Hence, the pharmacogenetics can have an impact on each patient’s toxicity²⁸28. Driessen CML, Leijendeckers J, Snik A, Graaf WTA, Boer JP, Gelderblom H et al. Ototoxicity in locally advanced head and neck cancer patients treated with induction chemotherapy followed by intermediate or high-dose cisplatin-based chemoradiotherapy. Head & Neck. 2019;41(2):488-94..

In this study, the cumulative dosage of head and neck cancer chemotherapy of the adults was not controlled. Nevertheless, the TEOAE response was observed, which can mean that an alteration in calcium and magnesium metabolism may be taking place - made evident by the presence of responses in the emission assessment even with the audiological impairment observed in the pure-tone audiometry.

In conclusion, it is verified that the pure-tone audiometry is the most sensitive test in terms of audiological assessment to identify chemotherapy-induced hearing impairment due to head and neck cancer in adults, especially at the 3000, 6000, 8000, 10,000, and 12,500 Hz frequencies. However, there were responses in the electroacoustic assessment, indicating that chemotherapy alters the calcium and magnesium metabolism, which in turn leads to an increase in the responses in the transient-evoked otoacoustic emissions. Thereby, it is not possible to identify audiological alterations assessing the functioning of the outer hair cells.

This study’s limitation was the control of the medication used for the different types of intervention in head and neck cancer treatment. Nonetheless, considering the findings in the research, it is relevant to have periodical audiological follow-ups of the patients submitted to chemotherapy and/or radiotherapy - especially those who did not present pretreatment auditory alterations, or who reported auditory complaints during the treatment.

Conclusion

Given the above, it is concluded that individuals with a history of head and neck cancer have higher pure-tone auditory thresholds than their controls, particularly at high frequencies beginning at 3000 Hz. Hence, bilateral sensorineural hearing loss is characterized, with a down-slope configuration. This evidences the deleterious effect of ototoxicity on the peripheral auditory system of adults, especially in its base, observed with a greater impairment in the high-frequency audiometry. The speech recognition is compatible with the alterations in these individuals; the otoacoustic emissions assessment, with the technique used in this study, did not demonstrate statistically significant differences in patients with a history of head and neck cancer submitted to chemotherapy and/or radiotherapy.

REFERENCES

¹
Lydiatt WM, Patel SG, O'Sullivan B, Brandwein MS, Ridge JA, Migliacci JC et al. Head and neck cancers - major changes in the American Joint Committee on Cancer Eighth Edition Cancer Staging Manual. CA Cancer J Clin. 2017;67(2):122-37.
²
Instituto Nacional de Câncer José Alencar Gomes da Silva, Copyright (c) 1996 - 2016 INCA - Ministério da Saúde. [cited 2019 Jul18] Available from: http://www2.inca.gov.br/wps/wcm/connect/tiposdecancer/site/home/laringe
» http://www2.inca.gov.br/wps/wcm/connect/tiposdecancer/site/home/laringe
³
Licitra L, Bernier J, Grandi C, Locati L, Merlano M, Gatta G, Lefebvre JL. Cancer of the larynx. Critical Reviews in Oncology/hematology. 2003;47(1):65-80.
⁴
Wünsch V. The epidemiology of laryngeal cancer in Brazil. Sao Paulo Med. J. 2004;122(5):188-94.
⁵
Vilar CMC, Martins IM. Câncer de cabeça e pescoço. In: Vieira SC, Lustosa AML, Barbosa CNB, Teixeira JMRT, Brito LXE, Soares LFM et al. (eds). Oncologia básica. 1. ed. Teresina, PI: Fundação Quixote, 2012. p.9-22.
⁶
Vilar CMC, Martins IM. Princípios de cirurgia oncológica. In: Vieira SC, Lustosa AML, Barbosa CNB, Teixeira JMRT, Brito LXE, Soares LFM et al. (eds). Oncologia básica. 1. ed. Teresina, PI: Fundação Quixote, 2012. p.221-36.
⁷
Crisanto MLLP. Princípios de Quimioterapia. In: Vieira SC, Lustosa AML, Barbosa CNB, Teixeira JMRT, Brito LXE, Soares LFM, Ferreira MAT et al. (eds). Oncologia básica. 1. ed. Teresina, PI: Fundação Quixote, 2012. p.237-52.
⁸
Oliveira PF, Oliveira CS, Andrade JS, Santos TFC, Oliveira-Barreto AC. Tratamento oncológico na determinação das alterações auditivas. Braz. j. otorhinolaryngol. 2016;82(1):65-9.
⁹
Rosenberg B, Van Camp L, Krigas T. Inhibition of cell division in escherichia coli by electrolysis products from a platinum electrode. Nature. 1965;205(4972):698-9.
¹⁰
Abdollahi H, Mostafaei S, Cheraghi S, Shiri I, Mahdavi SR, Kazemnejad A. Cochlea CT radiomics predicts chemoradiotherapy induced sensorineural hearing loss in head and neck cancer patients: A machine learning and multi-variable modeling study. Phys Med. 2018;45:192-7.
¹¹
Hyppolito MA, Oliveira JAA. Ototoxicidade, otoproteção e autodefesa das células ciliadas da cóclea. Medicina. 2005;38(3/4):279-89.
¹²
Garcia AP, Iório MCM, Petrilli AS. Monitoramento da audição de pacientes expostos à cisplatina. Rev. Bras. Otorrinolaringol. 2003;69(2):215-21.
¹³
Ng SP, Pollard C, Berends J, Ayoub Z, Kamal M, Garden AS et al. Usefulness of surveillance imaging in patients with head and neck cancer who are treated with definitive radiotherapy. Cancer. 2019;125(11):1823-9.
¹⁴
Schultz C, Goffi-Gomez MV, Liberman PH, Carvalho AL. Report on hearing loss in oncology. Braz. j. otorhinolaryngol. 2009;75(5):634-41.
¹⁵
Jacob LCB, Aguiar FP, Tomiasi AA, Tschoeke SN, Bitencourt RF. Monitoramento auditivo na ototoxidade. Rev. Bras. Otorrinolaringol. 2006;72(6):836-44.
¹⁶
Fausti SA, Frey RH, Henry JA, Olson J, Schaffer HI. High-frequency testing techniques and instrumentation for early detection of ototoxicity. Journal Rehabilitation Res Development. 1993;30(3):333-41.
¹⁷
Damian PI, Valverde TA, Guimarães DP, Gil D. Auditory monitoring in adults undergoing chemotherapy with carboplatin. Distúrb Comun. 2017;29(3):438-47.
¹⁸
Dunckley KT, Dreisbach LE. Gender effects on high-frequency distortion product otoacoustic emissions in humans. Ear Hear. 2004;25(6):554-64.
¹⁹
Littman TA, Magruder A, Strother DR. Monitoring and predicting ototoxic damage using distortion-product otoacoustic emissions: pediatric case study. J Am Acad Audiol. 1998;9(4):257-62.
²⁰
Yardley MP, Davies CM, Stevens JC. Use of transient evoked otoacoustic emissions to detect and monitor cochlear damage caused by platinum-containing drugs. Br J Audiol. 1998;32(5):305-16.
²¹
Almeida EOC, Costa CB, Oliveira SRT, Umeoka MTH. Audiometria tonal e emissões otoacústicas - produtos de distorção em pacientes tratados com cisplatina. Arq. Int. Otorrinolaringol. 2006;10(3):203-8.
²²
American Speech-Language-Hearing Association. (1988). Determining threshold level for speech [Guidelines]. [cited 2019 Nov29] Available from: http://www.asha.org/policy
» http://www.asha.org/policy
²³
Lloyd L, Kaplan H. Audiometric interpretation: a manual of basic audiometry. Press, 1978.
²⁴
Finitzo T, Albright K, Oneal J. The newborn with hearing loss: detection in the nursery. Pediatrics. 1998;102(6):1452-60.
²⁵
American Cancer Society. Clinical Oncology. Atlanta: ACS; 2001.
²⁶
Menezes M. Efeitos da radioterapia sobre a audição em pacientes portadores de tumores de cabeça e pescoço [monografia]. Recife (PE): CEFAC; 1999.
²⁷
Yasui N, Adachi N, Kato M, Koh K, Asanuma S, Sakata H et al. Cisplatin-induced Hearing Loss. J Pediatr Hematol Oncol. 2014;36(4):e241-5.
²⁸
Driessen CML, Leijendeckers J, Snik A, Graaf WTA, Boer JP, Gelderblom H et al. Ototoxicity in locally advanced head and neck cancer patients treated with induction chemotherapy followed by intermediate or high-dose cisplatin-based chemoradiotherapy. Head & Neck. 2019;41(2):488-94.

Publication Dates

Publication in this collection
17 July 2020
Date of issue
2020

History

Received
23 July 2019
Accepted
08 June 2020

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ¹
Lydiatt WM, Patel SG, O'Sullivan B, Brandwein MS, Ridge JA, Migliacci JC et al. Head and neck cancers - major changes in the American Joint Committee on Cancer Eighth Edition Cancer Staging Manual. CA Cancer J Clin. 2017;67(2):122-37.

[2] ²
Instituto Nacional de Câncer José Alencar Gomes da Silva, Copyright (c) 1996 - 2016 INCA - Ministério da Saúde. [cited 2019 Jul18] Available from: http://www2.inca.gov.br/wps/wcm/connect/tiposdecancer/site/home/laringe
» http://www2.inca.gov.br/wps/wcm/connect/tiposdecancer/site/home/laringe

[3] ³
Licitra L, Bernier J, Grandi C, Locati L, Merlano M, Gatta G, Lefebvre JL. Cancer of the larynx. Critical Reviews in Oncology/hematology. 2003;47(1):65-80.

[4] ⁴
Wünsch V. The epidemiology of laryngeal cancer in Brazil. Sao Paulo Med. J. 2004;122(5):188-94.

[5] ⁵
Vilar CMC, Martins IM. Câncer de cabeça e pescoço. In: Vieira SC, Lustosa AML, Barbosa CNB, Teixeira JMRT, Brito LXE, Soares LFM et al. (eds). Oncologia básica. 1. ed. Teresina, PI: Fundação Quixote, 2012. p.9-22.

[6] ⁶
Vilar CMC, Martins IM. Princípios de cirurgia oncológica. In: Vieira SC, Lustosa AML, Barbosa CNB, Teixeira JMRT, Brito LXE, Soares LFM et al. (eds). Oncologia básica. 1. ed. Teresina, PI: Fundação Quixote, 2012. p.221-36.

[7] ⁷
Crisanto MLLP. Princípios de Quimioterapia. In: Vieira SC, Lustosa AML, Barbosa CNB, Teixeira JMRT, Brito LXE, Soares LFM, Ferreira MAT et al. (eds). Oncologia básica. 1. ed. Teresina, PI: Fundação Quixote, 2012. p.237-52.

[8] ⁸
Oliveira PF, Oliveira CS, Andrade JS, Santos TFC, Oliveira-Barreto AC. Tratamento oncológico na determinação das alterações auditivas. Braz. j. otorhinolaryngol. 2016;82(1):65-9.

[9] ⁹
Rosenberg B, Van Camp L, Krigas T. Inhibition of cell division in escherichia coli by electrolysis products from a platinum electrode. Nature. 1965;205(4972):698-9.

[10] ¹⁰
Abdollahi H, Mostafaei S, Cheraghi S, Shiri I, Mahdavi SR, Kazemnejad A. Cochlea CT radiomics predicts chemoradiotherapy induced sensorineural hearing loss in head and neck cancer patients: A machine learning and multi-variable modeling study. Phys Med. 2018;45:192-7.

[11] ¹¹
Hyppolito MA, Oliveira JAA. Ototoxicidade, otoproteção e autodefesa das células ciliadas da cóclea. Medicina. 2005;38(3/4):279-89.

[12] ¹²
Garcia AP, Iório MCM, Petrilli AS. Monitoramento da audição de pacientes expostos à cisplatina. Rev. Bras. Otorrinolaringol. 2003;69(2):215-21.

[13] ¹³
Ng SP, Pollard C, Berends J, Ayoub Z, Kamal M, Garden AS et al. Usefulness of surveillance imaging in patients with head and neck cancer who are treated with definitive radiotherapy. Cancer. 2019;125(11):1823-9.

[14] ¹⁴
Schultz C, Goffi-Gomez MV, Liberman PH, Carvalho AL. Report on hearing loss in oncology. Braz. j. otorhinolaryngol. 2009;75(5):634-41.

[15] ¹⁵
Jacob LCB, Aguiar FP, Tomiasi AA, Tschoeke SN, Bitencourt RF. Monitoramento auditivo na ototoxidade. Rev. Bras. Otorrinolaringol. 2006;72(6):836-44.

[16] ¹⁶
Fausti SA, Frey RH, Henry JA, Olson J, Schaffer HI. High-frequency testing techniques and instrumentation for early detection of ototoxicity. Journal Rehabilitation Res Development. 1993;30(3):333-41.

[17] ¹⁷
Damian PI, Valverde TA, Guimarães DP, Gil D. Auditory monitoring in adults undergoing chemotherapy with carboplatin. Distúrb Comun. 2017;29(3):438-47.

[18] ¹⁸
Dunckley KT, Dreisbach LE. Gender effects on high-frequency distortion product otoacoustic emissions in humans. Ear Hear. 2004;25(6):554-64.

[19] ¹⁹
Littman TA, Magruder A, Strother DR. Monitoring and predicting ototoxic damage using distortion-product otoacoustic emissions: pediatric case study. J Am Acad Audiol. 1998;9(4):257-62.

[20] ²⁰
Yardley MP, Davies CM, Stevens JC. Use of transient evoked otoacoustic emissions to detect and monitor cochlear damage caused by platinum-containing drugs. Br J Audiol. 1998;32(5):305-16.

[21] ²¹
Almeida EOC, Costa CB, Oliveira SRT, Umeoka MTH. Audiometria tonal e emissões otoacústicas - produtos de distorção em pacientes tratados com cisplatina. Arq. Int. Otorrinolaringol. 2006;10(3):203-8.

[22] ²²
American Speech-Language-Hearing Association. (1988). Determining threshold level for speech [Guidelines]. [cited 2019 Nov29] Available from: http://www.asha.org/policy
» http://www.asha.org/policy

[23] ²³
Lloyd L, Kaplan H. Audiometric interpretation: a manual of basic audiometry. Press, 1978.

[24] ²⁴
Finitzo T, Albright K, Oneal J. The newborn with hearing loss: detection in the nursery. Pediatrics. 1998;102(6):1452-60.

[25] ²⁵
American Cancer Society. Clinical Oncology. Atlanta: ACS; 2001.

[26] ²⁶
Menezes M. Efeitos da radioterapia sobre a audição em pacientes portadores de tumores de cabeça e pescoço [monografia]. Recife (PE): CEFAC; 1999.

[27] ²⁷
Yasui N, Adachi N, Kato M, Koh K, Asanuma S, Sakata H et al. Cisplatin-induced Hearing Loss. J Pediatr Hematol Oncol. 2014;36(4):e241-5.

[28] ²⁸
Driessen CML, Leijendeckers J, Snik A, Graaf WTA, Boer JP, Gelderblom H et al. Ototoxicity in locally advanced head and neck cancer patients treated with induction chemotherapy followed by intermediate or high-dose cisplatin-based chemoradiotherapy. Head & Neck. 2019;41(2):488-94.

Variable	Groups	Category	N	Frequency (%)	p-value
Gender	Study Group	Males	14	60.9	> 0.999
	Study Group	Females	9	39.1
	Control Group	Males	14	60.9
	Control Group	Females	9	39.1
Type of treatment conducted with the Study Group	Chemotherapy	Males	3	37.5	0.475
	Chemotherapy	Females	5	62.5
	Radiotherapy	Males	5	71.4
	Radiotherapy	Females	2	28.6
	Chemotherapy + Radiotherapy	Males	6	75.0
	Chemotherapy + Radiotherapy	Females	2	25.0

Sound frequencies (kHz)	Group	Mean	SD	Median	Minimum	Maximum	p-value
0.25	SG	16.96	10.30	15.00	0.00	40.00	0.797
0.25	CG	16.41	9.87	15.00	0.00	50.00	0.797
0.5	SG	17.83	8.86	15.00	5.00	40.00	0.180
0.5	CG	15.22	9.66	12.50	0.00	45.00	0.180
1	SG	17.93	10.83	15.00	5.00	45.00	0.255
1	CG	15.33	11.03	15.00	0.00	45.00	0.255
2	SG	20.33	14.73	17.50	0.00	60.00	0.814
2	CG	19.57	16.12	15.00	0.00	60.00	0.814
3	SG	31.09	20.81	27.50	5.00	80.00	0.029*
3	CG	21.85	19.16	15.00	0.00	60.00	0.029*
4	SG	34.24	21.63	25.00	5.00	95.00	0.151
4	CG	27.83	20.89	20.00	0.00	70.00	0.151
6	SG	43.46	22.63	40.00	10.00	95.00	0.006*
6	CG	30.54	21.11	25.00	0.00	80.00	0.006*
8	SG	41.09	24.96	37.50	5.00	100.00	0.034*
8	CG	30.33	23.03	22.50	5.00	85.00	0.034*
10	SG	58.59	27.30	55.00	10.00	95.00	0.020*
10	CG	45.98	23.51	40.00	5.00	95.00	0.020*
12.5	SG	67.93	24.05	80.00	5.00	85.00	0.005*
12.5	CG	53.80	22.81	52.50	0.00	85.00	0.005*
14	SG	56.85	16.65	65.00	0.00	65.00	0.535
14	CG	54.67	16.85	65.00	0.00	65.00	0.535

TEOAE	Group	N	Mean response amplitude of the TEOAE	SD	Median	Maximum	p-value
General response (dB)	SG	36	8.42 (6.88-9.98)	5.42 (4.35-6.24)	8.80 (7.20-10.70)	20.50	0.810
General response (dB)	CG	37	8.15 (6.58-9.74)	5.32 (4.30-6.20)	8.65 (7.60-10.00)	19.60	0.810
Response for the 1 kHz (dB) band	SG	37	9.48 (7.58-11.33)	6.58 (5.32-7.59)	10.50 (7.00-12.50)	24.60	0.575
Response for the 1 kHz (dB) band	CG	38	8.76 (7.12-10.42)	5.74 (4.73-6.57)	8.20 (7.10-9.80)	19.00	0.575
Response for the 2 kHz (dB) band	SG	37	9.07 (7.13-10.97)	6.80 (5.52-7.73)	8.75 (5.70-11.20)	24.60	0.231
Response for the 2 kHz (dB) band	CG	34	7.49 (5.78-9.16)	5.69 (4.64-6.58)	7.50 (6.20-9.20)	20.30	0.231
Response for the 3 kHz (dB) band	SG	28	7.75 (5.58-10.04)	7.76 (6.15-9.14)	8.15 (0.00-11.10)	27.20	0.586
Response for the 3 kHz (dB) band	CG	31	6.97 (5.30-8.69)	5.76 (4.91-6.42)	7.20 (5.40-9.70)	18.50	0.586
Response for the 4 kHz (dB) band	SG	27	4.91 (3.06-6.94)	6.85 (4.05-8.82)	3.35 (0.00-3.95)	27.60	0.966
Response for the 4 kHz (dB) band	CG	31	4.97 (3.73-6.31)	4.48 (3.66-5.14)	4.20 (3.20-6.40)	15.00	0.966

Brasil

Brasil

Audiological assessment and otoacoustic emissions in patients with head and neck cancer

ABSTRACT

Purpose:

Methods:

Results:

Conclusion:

RESUMO

Objetivo:

Métodos:

Resultados:

Conclusão:

Introduction

Methods

Results

Discussion

Conclusion

REFERENCES

Publication Dates

History