Introduction
Students studying audiological testing enter the clinic with varying degrees of competency regarding the interpretation of acoustic reflex threshold (ART) test results. If a student clinician becomes lost in the maze of right and left, ipsilateral and contralateral "boxes" - often associated with the fairly common, but rather ghastly, 2x2 ART table, then clinical speed may be compromised as a student tries to recall the connection between pathology location and memorized tables. This tutorial reviews the basics of ART pattern interpretation with a clear, simple model for use as a teaching/learning tool for supervisors and students. This model is also shown as it relates to the traditional 2x2 table for cross reference. Students should be aware that the actual anatomical structures and "real life" clinical interpretations are more complex than those shown with this simple model, but this tutorial is intended as an approachable introduction. What follows are six introductory pieces of information and then a step-by-step illustrated guide to simple ART interpretation.
Six Introductory Pieces of Information
First, students must study the anatomy and physiology associated with the ART including the outer, middle, and inner ear structures, the vestibulocochlear nerve (VIII cranial nerve), and structures in the central auditory nervous system (CANS); specifically, auditory structures located at the level of the lower brainstem including the cochlear nuclei, superior olivary complex and facial nerve (VII nerve) nuclei. For this tutorial, students must be aware that the facial nerve innervates the stapedius muscle and that the stapedius muscle contraction is responsible for the acoustic reflex threshold in humans.
Second, the nature of a reflex must be understood. A reflex occurs when a signal is transmitted along a sensory neuron to an interneuron to a motor neuron causing a contraction of the muscle tissue innervated by the motor neuron. This is below the level of cognitive control; in other words, patients do not have to think about it. This is why one pulls a hand quickly away from a hot pot without thinking first, "Wow, my hand is burning" (that comes later) and this is why the stapedius muscle contracts in response to a loud sound, even though the patient does not consciously control the action. When a loud sound enters a normal ear, the stapedius muscle will contract on both sides regardless of which ear is stimulated. Therefore, the ART is a bilateral ("two side") reflex.
Third, the word ipsilateral (ipsi) means "same side" and contralateral (contra) means "opposite side". These terms refer to where the ART is measured relative to where the loud sound is presented. If the ART is measured on the same side in which a loud sound is presented, then it is an ipsilateral ART. If the signal is measured on the opposite side to that in which the loud sound is presented, then it is a contralateral ART. One additional way to remember this is: if the tone is presented on the probe side, then it is an ipsilateral ART. If the tone is presented on the earphone side, it is a contralateral ART.
Forth, "right" and "left" in ART testing refer to the ear that is stimulated by the loud sound. If the signal goes into the right ear and the ART is measured in the right ear, it is called a right ipsilateral ART. If the signal goes into the right ear and ART is measured in the left ear, it is called the right contralateral ART. Note that some audiologists reverse this and use a non-standardized method, which can be confusing (see Emanuel (2004) for more details).
Fifth, the response pattern can suggest a site of lesion, but other tests are necessary for confirmation. One can suspect, but cannot diagnose, site of lesion based solely on the results of ART testing.
Sixth, commercially available diagnostic bridges for testing ARTs are capable of producing high intensity stimuli (e.g., 120 dB HL and higher) and there is documentation in the literature that ART testing can cause permanent hearing loss and tinnitus (e.g. Hunter, Ries, Schlauch, Levine, & Ward, 2000). Although some authors have recommended a maximum presentation level of 110 dB SPL (Wilson & Margolis, 1999), there are no standards for safe presentation levels for pure tone stimuli. OSHA (1983) recommends a limit of 115 dBA for brief duration noise, but a pure tone results in a greater amount of energy concentrated over a smaller area of the basilar membrane compared with noise. In addition, some individuals are uniquely sensitive to the effects of loud sound. Therefore, clinicians should exercise caution in the presentation of loud sounds as well as be familiar with the literature in this regard.
With these six pieces of information in mind, students are ready to proceed to this ART model.
Acoustic Reflex Threshold (ART) Model
Figure 1 provides a model of the acoustic reflex pathway. It bears just about no resemblance to the actual anatomical structures which are extremely small, three dimensional and much more complex in terms of the nerve projections. However, this figure illustrates the main ART pathways and most of the key structures.
Figure 1. A simple model of the acoustic reflex pathway. The acronyms are as follows: ME = middle ear, IE = inner ear, VIII = vestibulocochlear nerve, CN = cochlear nucleus, SOC = superior olivary complex, VII = facial nerve. Note: (1) two of the structures in the pons (SOC and VII nucleus) are shown together for simplicity. They are actually separate structures. (2) A branch of the facial nerve ends at the stapedius muscle and the stapes is shown as a stirrup-shaped stick figure. (3) Some nerve projections are omitted for simplicity.
Imagine first a normal right ear and trace the pathway of a loud signal. The signal enters the right ear, travels through the outer, middle (ME) and inner ear (IE), along the VIII nerve, to the brainstem. When the signal reaches the brainstem, the signal arrives first at the cochlear nucleus (CN). From here, the signal travels to both right and left superior olivary complexes and both right and left facial nerve (VII) nuclei. The signal is sent from both facial nerve nuclei to both facial (VII) nerves, which results in a contraction of both stapedius muscles. Thus, both stapes bones are pulled outward and downward, in a direction away from the inner ear. This action makes it harder for energy to travel through the middle ear (increase in impedance/decrease in admittance). The lowest intensity level at which this contraction is measurable is the ART.
The Four Reflex Categories
Highlighted in red (right ear) and blue (left ear) in the following four diagrams are the pathways taken by the signal for right ipsilateral (Figure 2), right contralateral (Figure 3), left ipsilateral (Figure 4) and left contralateral (Figure 5) pathways.
Figure 2. Right ipsilateral pathway.
Figure 3. Right contralateral pathway.
Figure 4. Left ipsilateral pathway.
Figure 5. Left contralateral pathway.
The information from this ART model can be translated into the traditional 2 x 2 ART table (Table 1) for ease of comparison with other textbooks. A normal ear should yield present ARTs from 500 to 2000 Hz at normal levels. This is shown with Normal or N, Present (or P), or Within Normal Limits (WNL) in all of the boxes in the table. The exact notation will depend on the clinical site. For the remainder rest of this tutorial, Normal (N) will be used. Normative values can be found in a number of sources (e.g., Gelfand, Schwander, & Silman, 1990; Silman & Gelfand, 1981; various audiology textbooks) and will not be discussed here. With the normal model and 2x2 table in mind, next examine what happens to the ART pattern for various auditory pathologies.
Table 1. Bilateral normal ART results.
Cochlear Pathology
Imagine first a right cochlear pathology. The signal will affect the ART once the damage to the cochlea has reached a certain degree. For a cochlear hearing loss with air conduction thresholds below about 50 dB HL, the ART should resemble a normal ear. As the hearing threshold increases, the chances of an elevated or absent reflex increase.
Notice in Figure 6 that a right cochlear pathology is highlighted. Any pathway that crosses the damaged area will be affected by the cochlear pathology. So the ART will be absent or elevated whenever the signal is presented to the right ear, regardless of where it is measured. A signal entering the normal left ear will be unaffected, so ARTs will be present for stimuli to the left ear. Thus a pattern of elevated/absent responses on the right side (both ipsilateral and contralateral) and present/normal responses on the left side (both ipsilateral and contralateral) would be the pattern associated with a cochlear pathology on the right side. Table 2 shows this finding in a standard ART table.
Figure 6. Cochlear pathology, right ear. Note that right ipsilateral and right contralateral ARTs are elevated/absent and left ipsilateral and left contralateral ARTs are present.
Table 2. Cochlear pathology, right ear. Whenever a tone enters the left ear, the ART is present/normal. Whenever a tone enters the right ear, the ART is elevated or absent. Note that the abnormal responses are located in the same row (both right ear).
Vestibulocochlear nerve pathology
A vestibulocochlear (VIII) nerve pathology (Figure 7, Table 3) would result in the same pattern as a cochlear pathology; however it is much more likely that ARTs will be absent or unusually elevated compared with a cochlear pathology. Elevated/absent ARTs which do not agree with the hearing loss (again, consult normative values) are a cause for suspicion of retrocochlear pathology. Keep in mind the ART should be tested in combination with a battery approach for differential diagnosis as it is not a perfect test. For example, in an analysis of published studies, Turner, Shepard, and Frazer (1984) found 73% sensitivity and 90% specificity for prediction of acoustic neuroma (more correctly called a vestibular schwannoma) using the ART, so there is plenty of room for error in this test.
Figure 7. Vestibulocochlear nerve pathology, right side. Note that right ipsilateral and right contralateral ARTs are absent/elevated and left ipsilateral and left contralateral ARTs are present/normal.
Table 3. VIII nerve pathology, right ear. Whenever a tone enters the left ear, the ART is normal. Whenever a tone enters the right ear, the ART is elevated/absent. The ART pattern is identical to the cochlear pattern but the response is more likely to be absent in a vestibulocochlear nerve pathology or unusually elevated compared with normative values for cochlear hearing loss.
Facial Nerve Pathology
Facial nerve pathology causes a distinct ART pattern; specifically, ARTs are missing whenever ART is
measuredon the affected side (Figure 8, Table 4). This same pattern can also be seen if there is a problem with innervation of the stapedius muscle, dysfunction of the stapedius muscle, or disconnect between the stapedius muscle and the stapes. Often, facial nerve pathology is associated with other signs of facial nerve involvement, including a facial droop or history of VII nerve palsy (e.g., Bell's palsy).
Figure 8. Facial nerve pathology, right side. Note that anything that is measured on the right side will be affected. This includes right ipsilateral and left contra.\
Table 4. Facial nerve pathology, right side. Whenever an ART is measured in the right ear (right ipsilateral and left contralateral) it is absent. Note the absent responses are in opposite corners of the box.
Middle Ear Pathology
Middle ear pathology will affect the signal "coming and going." In more useful terms, the middle ear pathology can decrease the intensity of the signal going into the ear and it can interfere with the ability to measure the ART. Figure 9 illustrates the location of the pathology and Tables 5 and 6 illustrate two examples of possible ART patterns for middle ear pathology. Table 5 shows a milder condition causing ARTs to be elevated and Table 6 shows a more severe condition, such as that seen in chronic otitis media, in which the entire middle ear cavity is filled with fluid. Middle ear pathologies may also cause bizarre ART responses such as an ART recording that deflects in a direction that is opposite of normal, which may be seen in stiffening pathologies such as otosclerosis, or a pulsing on the ART, which may be a result of a mass growing through the inferior wall of the tympanum (middle ear cavity). This paper will not cover these more advanced ART findings.
Figure 9. Middle ear pathology, right side. Note that anything that goes through the right ear or is measured in the right ear can be affected, depending on the severity of the pathology.
Table 5. Mild middle ear pathology, right ear. ART may be affected for signals traveling through the right ear (right ipsilateral, right contralateral) or signals measured in the right ear (right ipsilateral, left contralateral).
Table 6. Severe middle ear pathology, right ear. ART will be absent for signals traveling through the right ear and signals measured in the right ear. Left ipsilateral would be unaffected.
Intra-Axial Brainstem Pathology
This is the point when basic ART pattern interpretation is less straightforward. "Textbook" intra-axial brainstem pathology (Figure 10) causes missing contralateral reflexes and present ipsilateral reflexes (Table 7), but, as the saying goes, very few patients read the textbooks before coming into the clinic. This same pattern of missing contralateral reflexes can also be observed if you test ARTs using supra-aural earphone cushions for patients with bilateral collapsing ear canals; thus, be wary of this pattern in patients with unusually small or narrow, slit-shaped ear canals.
Figure 10. Small intra-axial brainstem pathology. A classical finding is missing contralateral responses, but this can also be seen with bilateral collapsing ear canals. One or both ipsilateral responses may also be missing, depending on the exact location.
Table 7. Small intra-axial brainstem pathology (small). All contralateral ARTs are absent. All ipsilateral ARTs are present. This is a "textbook" pattern which will actually vary depending on the exact location and the structures that are compressed.
In actual practice, ARTs associated with intra-axial brainstem pathology will vary tremendously depending on exactly where the pathology is located and how large it is. As brainstem structures are very small, a small intra-axial pathology can cause pressure on a number of structures, causing ARTs to be affected on both sides. Figure 11 and Table 8 illustrate the ART results for a larger intra-axial pathology.
Figure 11. Larger intra-axial brainstem pathology. Depending on the location, size, and the extent to which surrounding structures are compressed, some or all of the responses will be absent. Due to the large number of nuclei located in the pons, other non-auditory neurological symptoms are also expected.
Table 8. Large intra-axial brainstem pathology. All ARTs are absent, but this is the least of this persons worries. Significant non-auditory neural symptoms are anticipated.
Extra-Axial Brainstem Pathology
Extra-axial brainstem pathology can result in a variety of ART patterns depending on the size and location of the lesion. The lesion may mimic a vestibulocochlear (VIII nerve) pathology or it could mimic an intra-axial pathology, or it could mimic facial nerve pathology or it may have a bizarre pattern depending on size and location. Note in Figure 12, that the ART pathway will depend on the location.
Figure 12. Extra-axial brainstem pathology may result in a myriad of ART patterns, depending on the size and location.
Problem Solving with ART Patterns
The following method can be used to teach ART interpretation to student clinicians. To determine the damaged pathway, have the student start with the ART model (Figure 1) and sketch in the pathways for ARTs that are normal. After obtaining an individual patient's ARTs, the pathology should be localized to the area that is not highlighted.
For example, examine the ART findings from Table 9a and 9b (note that you'll need to synthesize the results from the three frequencies, as in 9a, into one overall summary, as in 9b). Ask the student to determine where the pathology is located. Rather than recall memorized tables, have the student trace the pathway using the model in order to understand the pathways.
Table 9. (a) Example ART results for 500 - 2000 Hz and (b) Summary table.
Figure 13. Example pathway traced on ART model. Note that any time the signal enters the left ear, the reflex is present and any time the signal enters the right ear, the signal is absent.
Point out to the student that as per Figure 13 the ARTs are missing whenever the signal goes into the right ear but present whenever the signal goes into the left ear. This is regardless of where the signal is measured. Therefore, ARTs indicate a problem along the right pathway somewhere. Further examination is required to determine the exact location along the right pathway. Ask the student to determine if the ART levels are consistent with cochlear or retrocochlear pathology based on published normative data. Point out that as clinicians, we need to combine findings from the entire audiological test battery to make appropriate recommendations for further testing, medical referrals, amplification, and so forth. Always keep in mind when both teaching ARTs and conducting ART testing, that ARTs are not meant to be used alone, but as part of a battery of tests to help in the evaluation process.
References
Emanuel, D.C. (2004, September/October). Probe ear or stimulus ear? How audiologists report contralateral acoustic reflex thresholds. Audiology Today, 36.
Gelfand, S. A., Schwander, T., & Silman, S. (1990). Acoustic Reflex Thresholds in Normal and Cochlear-Impaired Ears: Effects of no-response rates on 90th percentiles in a large sample. Journal of Speech and Hearing Disorders, 55, 198-205.
Hunter, L. L., Ries, D. T., Schlauch, R. S., Levine, S. C., & Ward, W. D. (1999). Safety and clinical performance of acoustic reflex tests. Ear & Hearing, 20, 506-514.
OSHA (1983). OSHA Instruction CPL 2-2.35, Nov. 9, 1983. Guidelines for Noise Enforcement. Occupational Safety and Health Administration, U.S. Department of Labor, Washington, DC.
Silman, S., & Gelfand, S. A. (1981). The relationship between magnitude of hearing loss and acoustic reflex threshold levels. Journal of Speech & Hearing Disorders, 46, 312-316.
Turner, R. G., Shepard, N.T., & Frazer, G. J. (1984). Clinical performance of audiological and related diagnostic tests. Ear & Hearing, 5, 187-194.
Wilson, R. H., & Margolis, R. H. (1999). Acoustic reflex measurements. In Musiek, F.E., & Rintlemann, W.F. (Eds.). Contemporary Perspectives in Hearing Assessment. Boston: Allyn & Bacon, 131-165.
FAQs
What is the threshold for acoustic reflex? ›
An Acoustic Reflex Threshold test lets the audiologist know whether your child's acoustic reflex is working correctly. In mammals, the acoustic reflex is triggered by loud noises. In humans, the range is usually between 65 dB and 95 dB. Muscles in the inner ear contract to help protect the eardrum from damage.
What does it mean to have absent acoustic reflexes? ›Definition. Absence of the acoustic reflex, an involuntary contraction of the stapedius muscle that occurs in response to high-intensity sound stimuli. [ from HPO]
What are the results of acoustic reflex testing? ›Acoustic reflex threshold (ART) helps audiologists test for proper middle ear functioning by testing the ear's natural reflex to lower the volume of very loud sounds. A normal result means your child falls within the usual range. An abnormal ART may show some kind of a neurological disorder or nerve damage.
What are the acoustic reflex thresholds in normal and cochlear impaired ears? ›In subjects with normal hearing sensitivity, the acoustic reflex is typically elicited at a sensation level of between 85 and 100 dB for frequencies below 4000 Hz. In subjects with cochlear hearing loss, reflexes are often evoked at SLs of between 15 and 70 dB.
Why is acoustic reflex testing important? ›Why perform acoustic reflex measurements? Acoustic reflex results make a major contribution to differential diagnosis and should be part of every basic audiological evaluation. They can provide/confirm information about the type (conductive, sensory, neural) and degree of hearing loss.
What is the purpose of acoustic reflex? ›The acoustic reflex mostly protects against low frequency sounds. When triggered by sounds 20 dB above the reflex threshold, the stapedius reflex decreases the intensity of the sound transmitted to the cochlea by around 15 dB. The acoustic reflex is also invoked when a person vocalizes.
Are acoustic reflexes affected by hearing loss? ›Patients with mild to moderate cochlear sensorineural hearing loss have reflexes bilaterally at about the same intensity level as those with normal hearing, but patients with severe or profound hearing loss have absent reflexes when the affected ear is stimulated.
What triggers the acoustic reflex? ›This reflex, sometimes referred to as the acoustic reflex, is a contraction of the stapedial muscle in the middle ear, which is elicited by high-level sounds, especially those of low frequency.
What happens if the acoustic nerve is damaged? ›When the auditory nerve is damaged, the primary symptoms are sensorineural deafness and/or vertigo. The auditory nerve is the 8th cranial nerve. It connects the inner ear to the brain. The auditory nerve divides into two branches: the cochlear nerve and the vestibular nerve.
What do elevated acoustic reflexes mean? ›An elevated or ab- sent acoustic reflex threshold is consistent with a middle ear disorder, hearing loss in the stimulated ear, and/or interruption of neural innervation of the stapedius muscle.
What is normal hearing threshold? ›
Normal hearing range is from 0 dBHL (Decibel Hearing Level), which is the audiometric zero, to 20 dBHL. Any threshold, at any frequency, that is over 20 dBHL is identified as hearing loss. Though a 'normal' audible range for loudness is 0 – 180dB, anything over 85dB is considered damaging for our hearing.
What is the threshold range of normal hearing? ›People with normal hearing can hear sounds between 20 and 20,000 Hz. Decibels measure how loud a sound is. The following list of the average decibel ratings of familiar sounds was put together by the National Institute on Deafness and Other Communication Disorders (NIDCD): Breathing: 10 dB.
How is acoustic trauma diagnosed? ›The health care provider will most often suspect acoustic trauma if hearing loss occurs after noise exposure. A physical exam will determine if the eardrum is damaged. Audiometry may determine how much hearing has been lost.
What are the symptoms of acoustic trauma? ›Hazardous noise causes injury to the hearing mechanisms in the inner ear. The symptoms of acoustic trauma are: HL, tinnitus (ringing in the ear), aural fullness, recruitment (ear pain with loud noise), difficulty localizing sounds, difficulty hearing in a noisy background, and vertigo.
What is a positive reflex test? ›Reflex Tests refer to the additional testing, which occurs when initial test results are positive or outside of normal parameters and indicate that a second related test (second level) is medically appropriate.
What does it mean if you fail the reflex test? ›When reflex responses are absent this could be a clue that the spinal cord, nerve root, peripheral nerve, or muscle has been damaged. When reflex response is abnormal, it may be due to the disruption of the sensory (feeling) or motor (movement) nerves or both.
What are the 3 main components of a hearing test? ›There are three components of hearing screening: 1) otoscopic inspection, 2) pure tones (PTs) or otoacoustic emissions (OAEs) and 3) immittance screening. All children should be screened with all three components.
Which two muscles are involved in the acoustic reflex? ›In some mammals, both the stapedius and tensor tympani muscles contract in response to auditory stimuli. In humans, the stapedius reflex is considered to be the dominant acoustically evoked MEM reflex pathway.
What part of the brain is damaged in hearing loss? ›Finally, hearing loss can occur after direct damage to the parts of the brain that process sound, such as the temporal lobe. This type is known as central hearing loss. It can also develop after damage to hearing pathways that reside in the brain stem.
What causes acoustic nerve damage? ›In most cases of acoustic neuroma, there is no known cause. This faulty gene is also inherited in neurofibromatosis type 2, a rare disorder that usually involves the growth of tumors on the hearing and balance nerves on both sides of your head (bilateral vestibular schwannomas).
What kind of trauma causes hearing loss? ›
Ear injuries and trauma can cause damage to any part of the outer or inner ear. Accidents, loud noises, changes in air pressure, trauma from contact sports and foreign objects in the ear can cause injuries. Ear injuries can lead to dizziness, balance problems, hearing loss or changes in the ear's appearance.
Can acoustic trauma get worse? ›Symptoms include: Partial hearing loss that most often involves repeated long-term exposures to loud or high-pitched sounds. The hearing loss may slowly get worse.
How common is acoustic trauma? ›Of teenagers, 20-50 percent experience exposure to noise levels high enough to cause acute acoustic trauma. Hearing loss due to noise is the second most common sensorineural hearing loss, after age-related hearing loss (presbycusis).
Can acoustic neuroma affect memory? ›The psychiatric signs and symptoms reported in acoustic neuroma patients are usually described as transient, and these include mood changes, agitation, persecutory delusions, hallucinations, and memory loss and confusional episodes.
Is acoustic neuroma considered brain surgery? ›Overview. A suboccipital craniotomy is a surgery performed to remove an acoustic neuroma growing from the nerve responsible for balance and hearing. During surgery, a section of the skull is removed behind the ear to access the tumor and nerves. Acoustic neuromas cause hearing loss, ringing in the ears, and dizziness.
Is acoustic neuroma fatal? ›Untreated acoustic neuroma can be fatal
An acoustic neuroma is usually benign, but it can still be fatal if left untreated. This is because the tumour will keep growing. Once it runs out of space inside the small canal that links the inner ear to the brain, it begins to grow into the skull cavity.
The hearing threshold is the sound level below which a person's ear is unable to detect any sound. For adults, 0 dB is the reference level. A threshold shift is an increase in the hearing threshold for a particular sound frequency.
What is the dB of threshold of hearing? ›In the logarithmic scale the range of human ear's audible sounds is from 0 dB SPL (hearing threshold) to 120-140 dB SPL (pain threshold) (see table 1 below).
What is the normal auditory threshold? ›The range for normal hearing is 0 to 15 dB. Although the threshold for classification as hearing impaired has generally been defined as 25 dB, most experts agree that any hearing loss greater than 15 dB in an infant or young child could impede speech perception and language development.
What is threshold limit of hearing? ›Humans have a hearing threshold of around 0 decibels. Above this threshold, sounds with higher sound pressure levels are heard as louder noises. Sounds above 90 dB can lead to chronic hearing damage if people are exposed to them every day or all the time.
Why is the threshold of hearing important? ›
Measurement of the absolute hearing threshold provides some basic information about our auditory system. The tools used to collect such information are called psychophysical methods. Through these, the perception of a physical stimulus (sound) and our psychological response to the sound is measured.
What are hearing thresholds used for? ›In order to determine a person's degree of hearing loss, their hearing thresholds must be determined. Hearing thresholds are defined as the lowest level sound that can be heard 50% of the time. The decibel (or dB) is the unit of intensity used to describe hearing sensitivity.
How do you read hearing test results? ›- Normal hearing: -10 to 20 dB.
- Mild hearing loss: 20 to 40 dB higher than normal.
- Moderate hearing loss: 40 to 70 dB higher than normal.
- Severe hearing loss: 70 to 90 dB higher than normal.
- Profound loss: 90 dB or more.
While hearing loss can range from mild to profound, there are four classifications that all hearing losses fall under. The four types of hearing loss are sensorineural, conductive, mixed (sensorineural and conductive) and auditory neuropathy spectrum disorder (ANSD).
What does 40 percent hearing loss mean? ›25-40 dB. Difficulty hearing and understanding quiet/soft conversations, especially situations with a lot of background noise (restaurants, classrooms, etc.) Moderate Hearing Loss. 40-60 dB. Difficulty understanding speech, higher volume levels are required for hearing TV and radio.
What are the 5 levels of hearing? ›- Stage 1: Mild hearing loss.
- Stage 2: Moderate hearing loss.
- Stage 3: Moderately severe hearing loss.
- Stage 4: Severe hearing loss.
- Stage 5: Profound hearing loss.
- Treating hearing loss.
There is no “pass” or “fail.” This is just an assessment of your hearing. Push the button when you hear a sound, but don't push the button because you think you should be hearing a sound. Remember, it's not a “test,” so there is no reason to cheat! Next up is the word comprehension part of the exam.
What frequencies can you hear by age? ›People of All ages without a hearing impairment should be able to hear the 8000hz. People under 50 should be able to hear the 12,000hz and people under 40, the 15,000hz. Under 30s should hear the 16,000hz, and the 17,000hz is receivable for those under 24.
What percentage of hearing loss is considered a disability? ›Procedure for calculating hearing disability is based on pure tone thresholds as well as speech discrimination score in order to arrive at the percentage of the disability. The minimum degree of disability should be 40% in order to be eligible for any concessions/ benefits.
What level of hearing loss is considered deaf? ›If you are unable to detect sounds quieter than 90dB HL (decibels Hearing Level), it is considered a profound hearing loss for those frequencies. If the average of the frequencies at 500Hz, 1000Hz, and 2000Hz is 90dB or higher, the person is considered deaf.
What is the difference between sounds and noise? ›
Sounds can be used to communicate, warn, navigate and as a form of entertainment. Noise is an unwanted or unpleasant sound. Therefore, all noises are sounds while not all sounds are noises.