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Section 8.1.8: Hearing & Balance

Wendell Nakamura

(NeuroscienceNews, 2024)
LEARNING OBJECTIVES:
  1. Differentiate the four primary types of hearing loss.
  2. Identify the body structures related to the auditory system and describe their functions.
  3. Discuss how dysfunctions of these structures may contribute to the different kinds of hearing loss.
  4. Explain the role of occupational therapy in treating people with hearing loss.
  5. Differentiate two of the most common vestibular disorders.
  6. Identify the body structures related to the vestibular system and describe their functions.
  7. Discuss how dysfunction of these structures may contribute to vestibular disorders.
  8. Explain the role of occupational therapy in treating people with vestibular disturbances.

Deafness, Hearing Loss, & the Auditory System

Hearing loss is a widely common condition that affects people of all ages, from neonates to the elderly (Anastasiadou & Khalili, 2023) and is often overlooked as a part of overall health and well-being (Hearing Loss Association of America [HLAA], n.d.). Hearing loss can affect one or both ears and is categorized by the HLAA (n.d.) into four different levels: mild, moderate, severe, and profound. Deaf people mostly have profound hearing loss, implying very little to no hearing (World Health Organization [WHO], 2024).

While it is commonly understood that hearing loss significantly impacts communication, it is also widely noted that hearing loss is significantly associated with increased risk of falls (HLAA, n.d.; Lin & Ferrucci, 2012), lower educational attainment, lower rates of employment, cognitive decline, and emotional effects leading to diminished social interactions (Chang et al., 2021; Haile et al., 2021; WHO, 2024).


Epidemiology of Hearing Loss

The National Institute on Deafness and Other Communication Disorders (NIDCD; 2024) estimates that approximately 37.5 million Americans over the age of 18 years (15%) report some trouble with hearing and that about 1.9 million children in the U.S. (3%) are born with some detectable hearing loss. While most neonatal hearing loss is genetic, most school-aged children and adolescents have hearing loss that is acquired (Anastasiadou & Khalili, 2023). Acquired hearing loss is closely associated with aging, exposure to noise, and comorbidities such as hypertension, high blood glucose, and smoking history (Anastasiadou & Khalili, 2023). Age is the strongest predictor of hearing loss among adults and the greatest amount of hearing loss occurs with the 60-69 age group (NIDCD, 2024).


Global Burden of Disease of Hearing Loss

During the 1999-2000 school year, the Center for Disease Control and Prevention (CDC; 2025) estimated that the cost of providing special education services to children who were hard of hearing or deaf totaled approximately $11,000 per child ($652 million total). The total lifetime educational cost of hearing loss is estimated to be approximately $115,000 per child (CDC, 2025). The total lifetime cost for all individuals in the U.S. with hearing impairment in 2000 is estimated to be $2.1 billion, 6% of which were attributed to direct medical costs (doctor visits, prescription medications, and hospital stays), 30% were attributed to direct non-medical costs (home modifications and special education services), and 63% were attributed to indirect costs (lost wages) (CDC, 2025).


Health Disparities of Hearing Loss

Adults who have been identified as having hearing loss are more likely to smoke tobacco products, consume more alcohol, engage in more sedentary behaviors, and sleep six hours or less, compared to hearing individuals (Schoeborn & Heyman, 2008). Additionally, Schuh & Bush (2020) noted that people who are members of the deaf community have significantly poorer situations in the social determinants of health. These include healthcare access and quality, education access and quality, social and community context, economic stability, and safe neighborhoods and access to community resources (Schuh & Bush, 2020).

In a 2000-2015 review of the literature on access to healthcare services, Kuenburg et al. (2015) noted that people who were deaf or had hearing impairments experienced significant barriers to accessing services compared to hearing individuals. In particular, they experienced fear, mistrust, and frustration due to challenges in communication with their providers. Furthermore, the authors suggest that members of the deaf community present with lower health literacy, even if the individual is highly educated. This may be due to lifelong challenges with accessing health information that is presented to the public in ways that are difficult for members of the deaf community to receive. There is a paucity of qualified sign language interpreters for the deaf community, especially those who understand medical terminology.


Clinical Presentation of Hearing Loss

Early signs and symptoms of hearing loss may include (Cleveland Clinic, n.d.d; Mayo Clinic, 2023):


While there are many causes of hearing loss, the most common reasons include (Mayo Clinic, 2023):


(Mayo Clinic, n.d.)

There are four primary types of hearing loss (Anastasiadou & Khalili, 2023):

The Auditory System & Neuropathophysiology of Hearing Loss

There are four parts of the auditory system that we’ll explore: the outer ear, the middle ear, the inner ear, and the auditory pathway.

(NIDCD, 2022)
Auditory pathway. (Peelle & Wingfield, 2016)

Medical Management & Alternative Therapies for Hearing Loss

Conductive hearing loss is managed differently, depending on the cause. It may be managed through the removal of a foreign body, removal of cerumen (ear wax) impaction, or the administration of antibiotics and placement of grommets in the middle ear (drainage tubes).

The most common cause of sensorineural hearing loss in older adults is age-related hearing loss {ARHL), also known as presbycusis, when hair cells in the inner ear die, resulting in the loss of detection of high-pitched sounds (NIDCD, 2023). There is emerging research on some pharmacologic agents that target hair cell death (Crowson et al., 2017). Damage to the inner ear structures that result in sensorineural hearing loss is most often managed through assistive devices designed for amplification, such as hearing aids, personal amplification devices (e.g., pocket talkers), or cochlear implants. While hearing aids are the mainstay devices to compensate for hearing impairment, compliance has been low (Chang, 2021), mostly due to cost.


Impact of Hearing Loss on Occupational Performance

About 40% of young adults who were identified with hearing loss during childhood reported experiencing at least one limitation in occupational performance and only about 71% of young adults with hearing loss and who didn’t have other associated conditions (such as cerebral palsy, intellectual disabilities, vision loss, and epileptic disorders) were employed (CDC, 2025). The NICDC (2024) reports that approximately 28% of adults over the age of 52 years with moderate to severe hearing loss experience difficulty with daily activities, compared to 7.3% of comparable adults without hearing loss. The vast majority of older adults have sensorineural hearing loss or mixed type (Blaylock & Bewernitz, 2024).

Some of the more significant age-related changes in hearing include pitch discrimination, auditory reaction time, and speech perception (Blaylock & Bewernitz, 2024). Untreated hearing loss may result in increased risk of falls, depression, dementia, hospitalization, social isolation, paranoia, and reduced quality of life (Blaylock & Bewernitz, 2024; Chang, 2021). Hearing loss is also associated with decreased ADL and IADL performance in the elderly (Chang, 2021). Occupational therapists can help clients with hearing loss discover ways to improve independence with ADL and IADL through the use of assistive technologies. For example, devices that provide haptic feedback (such as vibration) or visual feedback (such as lights blinking or screen displays) may alert clients with hearing loss (Chang, 2021). Other environmental modifications such as dampening background noise in living spaces through the use of sound absorbing material, may improve sound quality for people with hearing loss (Chang, 2021).




Vestibular Disorders & the Vestibular System

Vestibular disorders encompass a wide range of health conditions that affect an individual’s balance. They can be broadly classified into two categories.


Epidemiology of Vestibular Disorders

Agrawal et al. (2013) estimated that 35% of adults in the U.S. over the age of 40 years experienced balance disorders and the prevalence increased with age; 85% of individuals over the age of 80 years experienced balance disorders. Moreover, the authors found that the prevalence of balance disorders among adults with diabetes mellitus increased by 70% and more if they also had complications of diabetes, such as peripheral neuropathy or diabetic retinopathy.


Global Burden of Disease of Vestibular Disorders

It is estimated that for individuals in the U.S, who are over the age of 60 years, the total economic burden for vestibular dysfunction is approximately &227 billion for direct medical costs (Agrawal et al., 2017). In a systematic review of 16 articles on the economic burden of vestibular dysfunction, Kowacs et al. (2019) noted a significant reduction of workplace productivity and absenteeism among individuals with vestibular dysfunction who continued to work, although overall rates of work-related costs were not provided.


Health Disparities of Vestibular Disorders

In a survey of 33,047 individuals in the U.S. who were enrolled in the National Health Interview Survey (NHIS) in 2016, Youn et al. (2023) found that there were statistically significant differences between people with and without vestibular disorders, in regards to age group, sex, educational attainment, race, income level, and insurance coverage. People who were over 60 years of age, female, had lower educational attainment, white, lower income, or on public medical insurance or were uninsured had higher rates of vestibular dysfunction. Moreover, the authors found that of people with vestibular dysfunction, African Americans, people of lower income brackets, or people who were uninsured were more likely to delay access to treatment services due to lack of transportation.


Clinical Presentation of Vestibular Disorders

Commonly experienced symptoms of vestibular disorder include vertigo (a sense of spinning), accompanied by blurred vision, disorientation, nausea, vomiting, and increased heart rate (Cleveland Clinic, n.d.b). While vestibular disorders may occur at any age, they are most common in older adults and may be due to cell death, tumors, exposure to environmental toxins, inflammation secondary to viral or bacterial infections, or acquired neurological conditions such as head injury or stroke (Cleveland Clinic, n.d.b; Kashouty, n.d.). Two of the most common vestibular disorders on which we will focus include benign paroxysmal positional vertigo (BPPV) and Ménière’s Disease.


The Vestibular System & Neuropathophysiology of Vestibular Disorders

The vestibular system is a complex set of sensory structures and neural pathways that functions to coordinate eye movements and maintain head position, spatial orientation, equilibrium, balance, and posture (Casale et al., 2023; Yoo & Mihaila, 2022).

(Kashouty, n.d.)
(Betts et al., 2022, Fig. 14.11)

The Role of Vision in Maintaining Balance

As previously mentioned, the vestibular tract has projections to the oculomotor nuclei (CN-III, CN-IV, and CN-VI) and the vestibulo-spinal tract to coordinate eye movement and postural corrections. There are two quick-acting reflexes that make this possible: the vestibulo-ocular reflex and the vestibulo-spinal reflex (Pritt, n.d.).


Medical Management & Alternative Therapies for Vestibular Disorders

Depending on the underlying cause of vestibular disorder, a number of treatment options are available.


Impact of Vestibular Disorders on Occupational Performance

Vestibular dysfunction can cause diminished balance, unsteady vision, and an increased risk of falls. As such, vestibular dysfunction report challenges with ADL and IADL performance, especially in areas of functional and household mobility (including ascending and descending stairs) and driving (Agrawal et al., 2017). To avoid provoking symptoms, people with vestibular dysfunction may avoid leaving the house and restrict their activities, such as shopping, working, socializing, and attending worship (AOTA, 2017).

In addition to providing vestibular rehab services to remediate the effects of vestibular dysfunction, occupational therapists may modify or adapt the environment in which an activity is performed or adapting how the occupation is performed (AOTA, 2017). Entry-level practitioners have the qualifications and skills to evaluate and analyze vestibular functioning and how it impacts occupational performance (AOTA, 2017).




Summary

The auditory and vestibular systems play an integral part of everyday activities. It allows us to engage in all kinds of movement patterns, interact with the environment around us, and participate in favored occupations. When parts of the auditory or vestibular systems are damaged, occupational performance may be significantly impaired. To limited extent, occupational therapists may remediate the performance skills of people with auditory or vestibular system deficits. By far, however, occupational therapists are well-equipped to provide clients with education and training in modifying the environment or the method in which an occupation is performed, or in the selection and use of adaptive equipment.







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