Bone conduction auditory brainstem response
Encyclopedia
Bone-conduction auditory brainstem response or BCABR is a type of auditory evoked response that records neural response from EEG
with stimulus transmitted through bone conduction
.
and middle ears to stimulate the cochlea
. Von Bekesy is credited with the discovery that at the level of the cochlea
, phase shifted bone-conduction signals cancel out air conduction signals. Bone-conduction works because all of the bones of the skull are connected, including the temporal bone
, which in turn stimulates the cochlea. Barany (1938) and Herzog & Krainz (1926) were some of the first researchers to examine the different components of bone-conduction hearing. Tonndorf (1968) found that there are three different forces that contribute to the forces needed to stimulate the cochlea: Distortional, Inertial (Ossicular), and External canal (Osseotympanic)
. This then compresses the scala vestibule into the basilar membrane
in the direction toward the scala tympani
. A traveling wave is created similar to that created by air conduction signals.
are suspended in the head and loosely coupled to the skull. When the head moves, the ossicles move out of phase with the head, but still follow the same cyclic motion. This causes the stapes to move in and out of the oval window. When vibrations come from the mastoid, inertial bone-conduction is greatest below 800 Hz.
Putting the bone vibrator on the forehead instead of the mastoid does not significantly create this affect.
).
Artesia
, microtia
, otitis media
and other outer/middle ear abnormalities will require the use of bone-conduction ABR testing. Infants who have a considerable about of amniotic fluid
in their middle ear space may need to be tested with BCABR. This fluid usually disappears by 48 hours after birth.
and that the inverting electrode is placed on the earlobe, mastoid, or nape of the neck. Using an alternating phase stimuli can also help to reduce artifact, however this will lead to a decrease in frequency selectivity by broadening the ABR response. Since the output of most bone oscillators is around 45 to 55 dB nHL, it becomes difficult to distinguish between sensorineural or mixed hearing losses when the losses by bone exceed this number. The output limitation of the bone oscillator is a major drawback.
Mauldin & Jerger (1979) found that for adults, the Wave V latencies derived from bone-conduction ABR are about approximately 0.5 ms longer than the same intensity level of air conduction. For infants, Wave V latencies for bone-conduction clicks are shorter than the air conduction clicks. These differences can be attributed to changes to the skull due to aging.
An ideal tone burst has energy at a pure-tone frequency (eg. 2000 Hz) regardless of the intensity. This tone burst would stimulate the corresponding area on the basilar membrane. However, if a tone burst is too short in duration, it could cause spectral splatter and lose its frequency selectivity. At high intensity levels, spectral splatter may result in excitement of unwanted areas on the basilar membrane.
EEG
EEG commonly refers to electroencephalography, a measurement of the electrical activity of the brain.EEG may also refer to:* Emperor Entertainment Group, a Hong Kong-based entertainment company...
with stimulus transmitted through bone conduction
Bone conduction
Bone conduction is the conduction of sound to the inner ear through the bones of the skull.Bone conduction is the reason why a person's voice sounds different to him/her when it is recorded and played back. Because the skull conducts lower frequencies better than air, people perceive their own...
.
Types of bone conduction
Vibration of the skull results in auditory sensation. This is a way to somewhat bypass the outerOuter ear
The outer ear is the external portion of the ear, which consists of the pinna, concha, and external auditory meatus. It gathers sound energy and focuses it on the eardrum . One consequence of the configuration of the external ear is to selectively boost the sound pressure 30- to 100-fold for...
and middle ears to stimulate the cochlea
Cochlea
The cochlea is the auditory portion of the inner ear. It is a spiral-shaped cavity in the bony labyrinth, making 2.5 turns around its axis, the modiolus....
. Von Bekesy is credited with the discovery that at the level of the cochlea
Cochlea
The cochlea is the auditory portion of the inner ear. It is a spiral-shaped cavity in the bony labyrinth, making 2.5 turns around its axis, the modiolus....
, phase shifted bone-conduction signals cancel out air conduction signals. Bone-conduction works because all of the bones of the skull are connected, including the temporal bone
Temporal bone
The temporal bones are situated at the sides and base of the skull, and lateral to the temporal lobes of the cerebrum.The temporal bone supports that part of the face known as the temple.-Parts:The temporal bone consists of four parts:* Squama temporalis...
, which in turn stimulates the cochlea. Barany (1938) and Herzog & Krainz (1926) were some of the first researchers to examine the different components of bone-conduction hearing. Tonndorf (1968) found that there are three different forces that contribute to the forces needed to stimulate the cochlea: Distortional, Inertial (Ossicular), and External canal (Osseotympanic)
Distortional bone-conduction
As vibrations compress the bones of the skull, pressure is put on the otic capsule and the membranous labyrinthMembranous labyrinth
The receptors for the senses of equilibrium and hearing are housed within a collection of fluid filled tubes and chambers known as the membranous labyrinth...
. This then compresses the scala vestibule into the basilar membrane
Basilar membrane
The basilar membrane within the cochlea of the inner ear is a stiff structural element that separates two liquid-filled tubes that run along the coil of the cochlea, the scala media and the scala tympani .-Function:...
in the direction toward the scala tympani
Scala tympani
Scala tympani is one of the perilymph-filled cavities in the cochlear labyrinth of the human ear. It is separated from the scala media by the basilar membrane, and it extends from the round window to the helicotrema, where it continues as scala vestibuli....
. A traveling wave is created similar to that created by air conduction signals.
Inertial bone-conduction
The ossiclesOssicles
The ossicles are the three smallest bones in the human body. They are contained within the middle ear space and serve to transmit sounds from the air to the fluid-filled labyrinth . The absence of the auditory ossicles would constitute a moderate-to-severe hearing loss...
are suspended in the head and loosely coupled to the skull. When the head moves, the ossicles move out of phase with the head, but still follow the same cyclic motion. This causes the stapes to move in and out of the oval window. When vibrations come from the mastoid, inertial bone-conduction is greatest below 800 Hz.
Putting the bone vibrator on the forehead instead of the mastoid does not significantly create this affect.
Osseotympanic bone-conduction
This type of bone-conduction also involves low frequencies. As a bone vibrator vibrates the skull, the bone and cartilage of the external ear receives energy, most of which escapes the unoccluded ear. Some of this energy hits the tympanic membrane and combines with inertial bone-conduction, stimulating the inner ear. An example of this occurs when you close your ears and speak- your voice appears to be much lower in frequency.Bone-conduction ABR
Bone-conduction auditory brainstem responses (BCABR) are similar to air conduction auditory brainstem responses, with the main difference being that the signal is transmitted via bone-conduction instead of air. The goal of bone ABR is to estimate cochlear function and to help identify the type of hearing loss present. Responses to air and bone-conduction ABRs are compared (for the same intensity and stimuliStimulus (physiology)
In physiology, a stimulus is a detectable change in the internal or external environment. The ability of an organism or organ to respond to external stimuli is called sensitivity....
).
When is BCABR needed?
Mauldin & Jerger (1979) stated that when an infant is found to have delayed latencies to an air conduction ABR, a bone-conduction ABR should be conducted as long as the facility has the appropriate equipment and normative data.Artesia
Artesia
Artesia may refer to:Places* Artesia, California* Artesia, Colorado * Artesia, Mississippi* Artesia, New Mexico* Artesia Wells, Texas* Mosomane, Botswana, also known as ArtesiaCompanies...
, microtia
Microtia
Microtia, also called microtia-anotia, is a congenital deformity where the pinna is very small and underdeveloped or absent . It can be unilateral or bilateral . It occurs in 1 out of about 8,000–10,000 births. In unilateral microtia, the right ear is most commonly affected...
, otitis media
Otitis media
Otitis media is inflammation of the middle ear, or a middle ear infection.It occurs in the area between the tympanic membrane and the inner ear, including a duct known as the eustachian tube. It is one of the two categories of ear inflammation that can underlie what is commonly called an earache,...
and other outer/middle ear abnormalities will require the use of bone-conduction ABR testing. Infants who have a considerable about of amniotic fluid
Amniotic fluid
Amniotic fluid or liquor amnii is the nourishing and protecting liquid contained by the amniotic sac of a pregnant woman.- Development of amniotic fluid :...
in their middle ear space may need to be tested with BCABR. This fluid usually disappears by 48 hours after birth.
Problems with BCABR
It is very common for there to be a large amount of artifact while using bone-conduction ABR. This is especially true at high intensities (~50 dB nHL) and at earlier waves (i.e. Wave I). To avoid stimulus artifact, it is recommended that the bone oscillator be placed high on the temporal boneTemporal bone
The temporal bones are situated at the sides and base of the skull, and lateral to the temporal lobes of the cerebrum.The temporal bone supports that part of the face known as the temple.-Parts:The temporal bone consists of four parts:* Squama temporalis...
and that the inverting electrode is placed on the earlobe, mastoid, or nape of the neck. Using an alternating phase stimuli can also help to reduce artifact, however this will lead to a decrease in frequency selectivity by broadening the ABR response. Since the output of most bone oscillators is around 45 to 55 dB nHL, it becomes difficult to distinguish between sensorineural or mixed hearing losses when the losses by bone exceed this number. The output limitation of the bone oscillator is a major drawback.
BCABR responses
With Bone ABR, the waves are typically more rounded that with traditional auditory brainstem responses. The maximum output for bone is around 50 dB nHL and should look similar to the 50 dB HL response of air conduction for people with normal hearing or with a mild SNHL. With conductive hearing losses, the latencies for air are shifted when compared to the latencies of bone-conduction.Mauldin & Jerger (1979) found that for adults, the Wave V latencies derived from bone-conduction ABR are about approximately 0.5 ms longer than the same intensity level of air conduction. For infants, Wave V latencies for bone-conduction clicks are shorter than the air conduction clicks. These differences can be attributed to changes to the skull due to aging.
BCABR with tone bursts
Tone burst stimuli can be used during bone ABR can be used to estimate frequency specific thresholds. Stapells is one researcher who reported on the accuracy of using tone bursts with BC ABR to estimate cochlear hearing sensitivity. Hofmann and Flach in 1981 demonstrated the ability to differentiate between the types of hearing loss by comparing air and bone ABRs evoked with tone burst stimuli.Physiology
Wegel and Lane found that low-frequencies masked high-frequencies better than the highs mask the lows. This is explained by von Bekesy's findings that the cochlea has an asymmetrical filter function effect. This asymmetry and higher travelling wave velocity at the base explains why the ABR is biased towards the high frequencies. For a low-frequency tone burst, the travelling wave velocity is greatest at the base than at the apex. For low frequency tone bursts, the displacement is largest in the apex. The neural response is synchronous only over a short distance of the apex. The response is broader due to lack of neural synchrony. High intensity tone bursts stimulate more of the basal areas. Tone burst masking techniques have been developed to overcome this upward spread of masking.An ideal tone burst has energy at a pure-tone frequency (eg. 2000 Hz) regardless of the intensity. This tone burst would stimulate the corresponding area on the basilar membrane. However, if a tone burst is too short in duration, it could cause spectral splatter and lose its frequency selectivity. At high intensity levels, spectral splatter may result in excitement of unwanted areas on the basilar membrane.
Polarity
Rarefaction polarity is recommended for clicks, but there is no agreement on the recommended polarity for tone burst stimuli. For some high intensity tone bursts, especially 500 Hz, rarefaction polarity results in very large amplitudes, making it difficult to distinguish waves from artifact. Using an alternating polarity helps to revert the ABR back to typical looking waveforms.Effectiveness
- Tone burst stimuli are clinically possible and straightforward to conduct.
- There is wide support that shows that low to moderate intensity levels do produce frequency-specific responses.
- Research has shown that although tone bursts with linear onset and offset characteristics may produce spectral splatter, this can be reduced with the use of non-linear stimulus shaping envelopes.
See also
- auditory brainstem responseAuditory Brainstem ResponseThe auditory brainstem response is an auditory evoked potential extracted from ongoing electrical activity in the brain and recorded via electrodes placed on the scalp. The resulting recording is a series of vertex positive waves of which I through V are evaluated...
- bone-conduction
- cochleaCochleaThe cochlea is the auditory portion of the inner ear. It is a spiral-shaped cavity in the bony labyrinth, making 2.5 turns around its axis, the modiolus....
- middle earMiddle earThe middle ear is the portion of the ear internal to the eardrum, and external to the oval window of the cochlea. The mammalian middle ear contains three ossicles, which couple vibration of the eardrum into waves in the fluid and membranes of the inner ear. The hollow space of the middle ear has...
- tone-burst