MADE-UP AUDIOLOGY MIDTERM QUESTIONS

Conductive hearing loss primarily affects the outer or middle ear, while sensorineural hearing loss affects the inner ear or the neural pathways connecting the inner ear to the brain.

A comprehensive audiological assessment typically includes a case history, pure-tone audiometry, speech audiometry, immittance testing (including tympanometry), otoacoustic emissions (OAEs), and possibly other specialized tests depending on the patient's needs.

Tympanometry is used to evaluate the function of the middle ear, including the mobility of the tympanic membrane and the middle ear pressure.

Otoacoustic emissions (OAEs) are sounds generated by the cochlea in response to a sound stimulus. They are commonly used as a screening tool to assess the function of the inner ear and the outer hair cells.

Pure-tone audiometry measures a person's hearing thresholds using pure tones of various frequencies, while speech audiometry assesses a person's ability to understand and repeat speech stimuli.

Air conduction testing involves the use of headphones to deliver sounds to the outer, middle, and inner ear, while bone conduction testing utilizes a bone oscillator placed on the skull to directly stimulate the cochlea.

The vestibular system, located within the inner ear, plays a crucial role in maintaining balance, spatial orientation, and the sense of motion.

Sensorineural hearing loss can have various causes, including exposure to loud noise, aging (presbycusis), genetic factors, certain medications, diseases or infections, and trauma to the head or ear.

In conductive hearing loss, bone conduction testing can still be effective as the bone oscillator bypasses the outer and middle ear and directly stimulates the cochlea. However, sensorineural hearing loss primarily affects the inner ear, so bone conduction testing is often utilized to assess the integrity of the inner ear function.

Mixed hearing loss refers to a combination of conductive and sensorineural components, meaning there is both a problem in the outer or middle ear and in the inner ear or auditory nerve pathways.

Central hearing loss refers to a hearing loss that occurs due to damage or dysfunction in the central auditory pathways, including the auditory nerve and the areas of the brain responsible for processing sound.

The purpose of obtaining a case history in audiological assessments is to gather information about the patient's medical history, hearing-related concerns, symptoms, exposure to noise or ototoxic medications, and any other relevant factors that may impact their auditory function.

The components of pure-tone audiometry include air conduction testing, where the patient listens to pure tones at various frequencies and responds when they hear the sound, and bone conduction testing, where a bone oscillator is used to bypass the outer and middle ear and stimulate the cochlea directly.

The purpose of speech audiometry is to assess the patient's ability to understand and discriminate speech. It involves tasks such as speech recognition threshold (SRT) testing, where the patient identifies and repeats words at a comfortable listening level, and word recognition testing, where the patient identifies and repeats words presented at suprathreshold levels.

mmittance testing involves measures such as tympanometry and acoustic reflex testing. Tympanometry assesses the mobility of the eardrum and middle ear function, while acoustic reflex testing measures the reflexive contraction of the middle ear muscles in response to loud sounds.

Otoacoustic emissions (OAEs) are sounds generated by the cochlea in response to a sound stimulus. They are used to assess the function of the outer hair cells in the inner ear. Auditory brainstem response (ABR) testing measures the electrical activity of the auditory nerve and brainstem in response to sound stimuli, providing information about the integrity of the auditory pathway.

During otoacoustic emissions (OAEs) testing, a small probe is placed in the ear canal, and sounds are presented. The probe microphone picks up the otoacoustic emissions generated by the cochlea in response to the sounds. The emissions are then analyzed to assess the function of the outer hair cells.

The purpose of acoustic reflex testing is to evaluate the integrity of the middle ear and the reflexive contraction of the middle ear muscles. It involves presenting a loud sound to one ear and measuring the acoustic reflex response in the form of a muscle contraction in both ears.

Masked thresholds are used in audiological testing when there is a significant difference in hearing sensitivity between the two ears. Masking involves presenting a noise stimulus to the non-test ear to prevent it from influencing the results obtained from the test ear.

An audiogram is a graph that represents a person's hearing thresholds at different frequencies. It typically displays frequency (in Hertz) on the horizontal axis and intensity (in decibels) on the vertical axis.

Air conduction thresholds are represented by the symbol "O" (circle) on the audiogram, while bone conduction thresholds are represented by the symbol "X" (cross) or "<" (left arrow) on the audiogram.

Some limitations of pure-tone audiometry include its inability to assess complex auditory processes, such as speech discrimination abilities and auditory processing disorders. It also relies on the patient's active participation and subjective responses, which may be influenced by factors such as attention, motivation, and language or cognitive abilities.

The speech recognition threshold (SRT) is the lowest level of speech intensity at which an individual can recognize or identify speech material correctly 50% of the time. It represents the threshold of audibility for speech.

The SRT is measured during speech audiometry by presenting a series of spondee words, which are two-syllable words with equal emphasis on both syllables. The intensity level of the speech material is varied until the individual correctly identifies or repeats the words at least 50% of the time.

The purpose of word recognition testing is to assess an individual's ability to understand and discriminate single-syllable words. It provides information about their ability to recognize and comprehend speech in more challenging listening conditions.

Word recognition testing is performed by presenting a list of single-syllable words at a comfortable listening level. The individual is asked to repeat or identify the words they hear. The percentage of correctly recognized words is calculated as the word recognition score (WRS).

The SRT represents the threshold of audibility for speech, indicating the intensity level at which speech becomes audible to the individual. The word recognition score (WRS) represents the individual's ability to understand and discriminate speech at a comfortable listening level.

The results of speech audiometry are typically reported or represented as percentages. The SRT and word recognition score (WRS) are reported as percentages, indicating the individual's performance relative to the average or expected performance for their age and hearing abilities.

The different types of tympanograms are Type A, Type B, Type C, and Type As. Type A tympanogram indicates normal middle ear function, Type B tympanogram indicates a middle ear problem such as fluid or blockage, Type C tympanogram indicates negative pressure in the middle ear, and Type As tympanogram indicates reduced compliance of the tympanic membrane.

Some common clinical applications of immittance testing include diagnosing middle ear disorders such as otitis media, assessing eustachian tube function, identifying the presence of fluid in the middle ear, and monitoring changes in middle ear function over time.

Some limitations or considerations when interpreting immittance testing results include the need for cooperation and understanding from the patient, the potential impact of factors like earwax or ear canal abnormalities on test results, and the need for correlation with other audiological tests for a comprehensive assessment of hearing function.

The two main types of OAEs are transient-evoked OAEs (TEOAEs) and distortion-product OAEs (DPOAEs).

TEOAEs are evoked by a brief click or tone burst stimulus, and the resulting OAEs are analyzed to assess the cochlear function across a wide range of frequencies. DPOAEs are evoked by two simultaneous tones, and the resulting OAEs are analyzed to assess the frequency-specific cochlear function.