Aminoglycoside-induced ototoxicity

In 1995, the WHO stated that aminoglycoside ototoxicity was a ‘major concern’, and highlighted the lack of epidemiological data on ototoxicity and hearing impairment in both developed and developing countries.Reference Saunders, Greinwald, Vaz and Guo⁸ Compared to developed countries, where there has been a dramatic reduction in the use of aminoglycosides, these drugs are still widely used in developing countries due to their low cost and broad antimicrobial spectrum.Reference Saunders, Greinwald, Vaz and Guo⁸ The reported prevalence of aminoglycoside ototoxicity among deaf individuals in developing countries ranges from 3 to 30 per cent.Reference Saunders, Greinwald, Vaz and Guo⁸

Multidrug-resistant TB, defined as resistance to both isoniazid and rifampicin, requires prolonged treatment for up to 18–24 months with injectable aminoglycosides such as kanamycin and amikacin.⁹ Due to the global upsurge of multidrug-resistant TB, aminoglycoside use is on the increase, placing many people at risk of ototoxicity.⁹ In sub-Saharan Africa, where HIV contributes to the burden of TB, the prevalence of multidrug-resistant TB is five to six times higher than that in China and India.^{9, 10}

Cisplatin-induced ototoxicity

Cisplatin is an antineoplastic drug often used to treat various tumours, including head and neck, oesophageal, and small and non-small cell lung cancers, as well as Hodgkin's and non-Hodgkin's lymphomas and sarcomas. Ototoxicity is a dose-limiting side-effect of the drug.Reference Rybak and Whitworth¹¹ Bokemeyer et al. showed that patients with sensorineural hearing loss or chronic noise exposure prior to chemotherapy had a threefold risk of ototoxicity.Reference Bokemeyer, Berger, Hartmann, Kollmansberger, Schmoll and Kuczyck¹² Other risk factors for cisplatin-induced ototoxicity include increased dosage, depleted nutritional state (with low serum albumin levels and anaemia) and cranial irradiation.Reference Rybak, Whitworth, Mukherjea and Ramkumar¹³ Patients with nasopharyngeal carcinoma appear to be very susceptible to the interaction of cisplatin and cochlear irradiation.Reference Huang, Teh, Strother, Davis, Chiu and Lu¹⁴

Human immunodeficiency virus treatment and ototoxicity

Patients who are HIV-positive have an increased incidence of hearing loss: 21–49 per cent will develop sensorineural hearing loss, predominantly in the high frequencies.Reference Birchall, Wight, French, Cockbain and Smith^4, Reference Soucek and Michaels^6, Reference Chandrasekhar, Connelly, Brahmbhatt, Shah, Kloser and Baredes¹⁵

Human immunodeficiency virus positive patients are at greater risk of hearing loss, due to otitis media, opportunistic central nervous system infections (e.g. toxoplasmosis, cytomegalovirus, TB and cryptococcosis), malignancies (including Kaposi's sarcoma and lymphoma), HIV-1 infection, ototoxic drug treatment and other causes.Reference Chandrasekhar, Connelly, Brahmbhatt, Shah, Kloser and Baredes^15–Reference Grimaldi, Luzi, Martino, Furlan, Nemni and Antonelli¹⁹ In addition, HIV may directly affect auditory function due to neurotropism of the virus.Reference McArthur²⁰

Long-term antiretroviral therapy also has significant metabolic side effects.Reference Moore, James, Nolan, Upton, McKinnon and Mallal²¹ The metabolic side effects of nucleoside reverse transcriptase inhibitor, a drug used in HIV treatment, may be related to mitochondrial toxicity.Reference Brinkman, Smeitink, Romijn and Reiss^22, Reference Anuurad, Semrad and Berglund²³ Cross-sectional studies have demonstrated an association between this drug and hearing loss.Reference Marra, Wechkin, Longstreth, Rees, Syapin and Gates^24–Reference McNaghten, Wan and Dworkin²⁶ To date, prospective studies have not examined the long-term effects of antiretroviral drugs on the auditory system. However, Khoza-Shangase recently published a study which monitored the auditory status of adults with AIDS and receiving HAART, compared with a control group, over a period of six months. Initially, both groups had normal pure tone audiograms; however, after six months the HAART-treated AIDS patients showed subclinical hearing changes together with clinically significant changes in distortion product otoacoustic emissions.Reference Khoza-Shangase²⁷

More recently, an animal study showed that while antiretroviral drugs may not be directly ototoxic, they may act synergistically when combined with other stressors (e.g. noise) due to effects on outer hair cell mitochondria.Reference Bektas, Martin, Stagner and Lonsbury-Martin²⁸ This may have implications for HIV-positive patients receiving HAART, in terms of noise exposure and noise-induced hearing loss.

In South Africa, as in many sub-Saharan countries, TB treatment is one of the most frequently administered therapies for HIV-AIDS patients. The combined effects of aminoglycosides and HAART on the auditory system have yet to be determined. While there is very limited information on possible HAART ototoxicity, it is clear that HIV-positive individuals are potentially at high risk of ototoxic hearing loss, as they are often prescribed ototoxic medication for the treatment of opportunistic infections (e.g. amphotericin B) or cancer (e.g. cisplatin).Reference Birchall, Wight, French, Cockbain and Smith^4–Reference Soucek and Michaels^6, Reference Little, Gardner, Acker and Land¹⁸

Human immunodeficiency virus positive patients have an increased risk of malignancy.Reference Silverberg, Chao, Leyden, Xu, Horberg and Klein²⁹ Treating cancer in HIV-positive patients is challenging because of drug interactions, compounded side effects, and the potential effects of chemotherapy on HIV-1 viral load. To date, there are no published reports assessing the combined effects of chemotherapy (particularly platin-based chemotherapy) and HAART on the hearing status of HIV-positive patients.

Audiological monitoring for ototoxicity

Early identification of ototoxic hearing loss due to cisplatin therapy provides physicians with an opportunity to adjust the drug therapy in order to minimise or prevent hearing loss.Reference Fausti, Helt, Gordon, Reavis, Phillips, Konrad-Martin and Campbell³⁰ However, multidrug-resistant TB is a more immediately life-threatening disease, both to the patient and their community, and aminoglycosides often have to be continued despite ototoxic hearing loss. Even so, screening and monitoring for ototoxic hearing loss is still important for patients with multidrug-resistant TB, as this enables audiologists to counsel patients and their families regarding ototoxicity-induced hearing loss, tinnitus, communication strategies, and the synergistic effects of noise and ototoxic damage. It also identifies patients who may benefit from appropriate rehabilitation after completion of treatment.

There are no universally accepted protocols for monitoring ototoxicity. In the UK, there is wide variation in screening practices for ototoxicity related to multidrug-resistant TB.Reference Sturdy, Goodman, José, Loyse, O'Donoghue and Kon³¹ The guidelines of the American Speech-Language-Hearing Association for audiological management of individuals treated with ototoxic drugs are based on large clinical studies, and recommend that patients should undergo a baseline evaluation before treatment is initiated. The frequency of monitoring depends on the particular drug regimen. For patients undergoing cisplatin chemotherapy, monitoring is usually performed prior to each dose; for those receiving ototoxic antibiotics such as aminoglycosides, it is done once or twice a week. Because ototoxic hearing loss can occur up to six months following drug exposure, post-treatment evaluation is required to confirm that hearing has stabilised.Reference Fausti, Helt, Gordon, Reavis, Phillips, Konrad-Martin and Campbell³⁰

Initially, ototoxic drug exposure typically affects the basal end of the cochlea and the vascular striae and causes hearing loss in the high frequencies; however, continued exposure affects progressively lower frequencies which are important for understanding speech.Reference Rybak and Whitworth^11, Reference Fausti, Helt, Gordon, Reavis, Phillips, Konrad-Martin and Campbell³⁰ Therefore, detecting changes in pure tone thresholds using serial ultra-high frequency audiometry (up to 18 kHz) is an effective indicator of ototoxic hearing loss. High frequency audiometry and distortion product otoacoustic emission testing have been shown to be the most reliable means of detecting early cochlear outer hair cell damage. However, abnormal middle-ear function and baseline hearing loss of greater than 40 dB HL may preclude effective monitoring using otoacoustic emissions. Auditory brainstem evoked response testing may be more appropriate in such cases.Reference Fausti, Helt, Gordon, Reavis, Phillips, Konrad-Martin and Campbell³⁰

Obstacles to audiological monitoring in the developing world

Developing countries have financial pressures on their health systems and competing budgetary demands from life-threatening and/or communicable diseases. In addition to these general constraints, the provision of audiology services in developing world countries is subject to additional challenges, exemplified in the Western Cape region of South Africa.Reference Swart³² These challenges include: a heavy concentration of services at central hospitals, with few or no services available in smaller facilities; a need to decentralise audiological screening to peripheral hospitals where community-based multidrug-resistant TB treatment is commenced;^{2, 33} a shortage of staff and skills at regional hospitals, as well as at specialised TB hospitals (where multidrug-resistant TB patients should be screened and monitored for ototoxicity);Reference Swart³² and inadequate facilities and equipment for delivery of audiology services.Reference Swart³²

Fagan and Jacobs conducted a survey of ENT services in sub-Saharan Africa and found an alarming paucity of audiology services, with several countries having no audiology services at all.Reference Fagan and Jacobs⁷ In most of the countries surveyed, the majority of people depended on state services. In countries where ENT services were available, they were restricted to major cities.

Therefore, at this stage it is unrealistic to implement in developed countries the international audiological monitoring protocols that are considered to represent an acceptable standard of care as regards ototoxicity screening and monitoring.

Cost-effective, affordable monitoring of ototoxicity

We need to develop and validate ototoxicity screening and monitoring tools which are commensurate with the financial, infrastructural and audiology service constraints of developing world countries.

Telephonic and telemedicine audiology tools are already being used. More than 50 per cent of the world's mobile phones are in the developing world. This presents an opportunity to develop applications for mobile devices – tools of media and communication which are easy to use and readily available despite educational and socio-economic barriers.

The Apple computer company, together with Oticon, a hearing aid company, have devised uHear, a software program freely available for downloading onto Apple iPhone devices. uHear is a self-testing application that performs pure tone audiometric assessments. Its accuracy has not yet been validated in published studies.

However, in 2011 a pilot study assessing iPhone uHear as a screening tool for detecting hearing loss was conducted at Groote Schuur Hospital in Cape Town (S Peer, unpublished data). Twenty-five patients were tested using uHear, in three different settings: a waiting room, a quiet room and a soundproof room. The results were compared to a formal audiogram. There was good accuracy for high frequencies in a quiet setting and a soundproof room, and fair-to-moderate correlation for low frequencies.

Although this study was only a pilot study, its results suggest that audiology applications for mobile devices hold promise as cheap, mobile screening and monitoring tools for ototoxicity in developing world settings.