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Yes, the basilar membrane in the cochlea is responsible for detecting different frequencies of sound.

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The structure within the cochlea containing hair cells that vibrate at different natural frequencies is the?

The structure within the cochlea containing hair cells that vibrate at different natural frequencies is the basilar membrane. This structure is vital for detecting different pitches of sound as vibrations of different frequencies cause specific hair cells to be stimulated, sending signals to the brain for processing.


Does In your inner ear different parts of the basilar membrane vibrate at different natural frequencies?

Yes. It is correct. In your ear different parts of the basilar membrane vibrate at different natural frequencies. You have stapes bone attached to oval window. When it vibrates, the vibrations are transmitted to round window. This transmission goes through scala vestibuli and comes back through scala tympani. This can happen because there is communication between to channels at the tip. When this fluid vibrates, the vibrations are taken up by different part of basilar membrane. For this you have to have the basilar membrane anatomically tapered. The longer part vibrates with low frequency sound and tapering part vibrates with sounds of higher frequencies successively. So the 'resultant' frequency is taken up by part of the basilar membrane. The signal is transmitted by hair cells to brain. With successive 'resultant' signals brain can analyse the hundreds of different sounds. Two ears together give stereoscopic effect to the sound.


What structure vibrates with the frequency of the received sound?

air around youair in your earseardrum membranethe 3 bones in the earcochlear membraneliquid in the cochleahair cells lining the cochlea


Gel-like membrane overlying the hair cells of the organ of Corti?

The gel-like membrane overlying the hair cells of the organ of Corti is called the tectorial membrane. It plays a crucial role in the transmission of sound waves and vibration to the hair cells, which are the sensory receptors responsible for detecting sound. The movement of the hair cells against the tectorial membrane initiates the generation of electrical signals that eventually get sent to the brain for sound processing.


Where are receptors located?

in the cell membrane depends on the receptor. A lot are in the cell membrane but some may be cytoplasmic or even nuclear depending on the solubility of the ligand and how it enters the cell.

Related Questions

The structure within the cochlea containing hair cells that vibrate at different natural frequencies is the?

The structure within the cochlea containing hair cells that vibrate at different natural frequencies is the basilar membrane. This structure is vital for detecting different pitches of sound as vibrations of different frequencies cause specific hair cells to be stimulated, sending signals to the brain for processing.


Explain how cochlea allow us to hear both low frequency and high frequency sound?

The basilar membrane within the cochlea is responsible for detecting different frequencies of sound. High frequency sounds cause vibrations near the base of the spiral-shaped cochlea, while low frequency sounds cause vibrations near the apex. This allows the brain to interpret different frequencies based on where the vibrations occur along the basilar membrane.


Does In your inner ear different parts of the basilar membrane vibrate at different natural frequencies?

Yes. It is correct. In your ear different parts of the basilar membrane vibrate at different natural frequencies. You have stapes bone attached to oval window. When it vibrates, the vibrations are transmitted to round window. This transmission goes through scala vestibuli and comes back through scala tympani. This can happen because there is communication between to channels at the tip. When this fluid vibrates, the vibrations are taken up by different part of basilar membrane. For this you have to have the basilar membrane anatomically tapered. The longer part vibrates with low frequency sound and tapering part vibrates with sounds of higher frequencies successively. So the 'resultant' frequency is taken up by part of the basilar membrane. The signal is transmitted by hair cells to brain. With successive 'resultant' signals brain can analyse the hundreds of different sounds. Two ears together give stereoscopic effect to the sound.


How does the cochlea detect different sound frequencies?

The cochlea detects different sound frequencies through the activation of hair cells sensitive to specific frequencies along its spiral structure. As sound waves travel through the cochlea, they cause different regions of the basilar membrane to vibrate depending on the frequency. This vibration is then translated into neural signals that the brain interprets as different pitches or frequencies.


What Forms the floor of the cochlea?

The floor of the cochlea is formed by the basilar membrane, which is a thin, flexible structure that supports the hair cells responsible for detecting sound vibrations. The basilar membrane plays a crucial role in converting sound waves into neural signals that can be interpreted by the brain.


What structure vibrates with the frequency of the received sound?

air around youair in your earseardrum membranethe 3 bones in the earcochlear membraneliquid in the cochleahair cells lining the cochlea


What is the length of the basilar membrane?

The basilar membrane in the human cochlea is around 35-38 mm long. This membrane plays a crucial role in auditory processing by vibrating in response to sound waves, which helps in the process of hearing. The membrane varies in width along its length, with different regions vibrating in response to different frequencies of sound.


Gel-like membrane overlying the hair cells of the organ of Corti?

The gel-like membrane overlying the hair cells of the organ of Corti is called the tectorial membrane. It plays a crucial role in the transmission of sound waves and vibration to the hair cells, which are the sensory receptors responsible for detecting sound. The movement of the hair cells against the tectorial membrane initiates the generation of electrical signals that eventually get sent to the brain for sound processing.


How is pitch translated in your ear?

In your inner ear, different parts of the basilar membrane vibrate at different natural frequencies, and hair cells near those parts send nerve impulses to your brain where they are interpreted as different pitches.


Where are receptors located?

in the cell membrane depends on the receptor. A lot are in the cell membrane but some may be cytoplasmic or even nuclear depending on the solubility of the ligand and how it enters the cell.


What is sensorys receptor for smell?

The sensory receptor for smell is called the olfactory receptor. These receptors are located in the olfactory epithelium in the upper part of the nasal cavity and are responsible for detecting and transmitting odors to the brain for interpretation.


How are peripheral and integral proteins different in terms of their functions within the cell membrane?

Peripheral proteins are loosely attached to the cell membrane and are involved in cell signaling and communication. Integral proteins are embedded within the membrane and are responsible for transporting molecules across the membrane and maintaining its structure.