The ear converts sound waves in the air into electrical impulses, which can be interpreted by the brain. As sound enters the ear, it passes through the external auditory canal, where it meets the tympanic membrane. The tympanic membrane then vibrates in response to the sound. Sounds of a lower pitch, or frequency, produce a slower rate of vibration. And sounds of lower volume, or amplitude, produce a less dramatic vibration.
Higher frequency sounds produce faster vibrations. The tympanic membrane is cone-shaped and articulates with a chain of three bones, called the auditory ossicles. They consist of the malleus, the incus, and the stapes. The movements of the tympanic membrane vibrate the ossicles, passing on the information of frequency and amplitude. The three bones pivot together on an axis shown here in red.
The pivotal axis is due to a series of ligaments which hold the bones in place within the middle ear cavity. The anterior malleoligament and the posterior incudoligament are of particular importance for the pivotal axis. Two structures which normally obscure this view of the middle ear have been removed.
They are the chordae tympani nerve and the tendon of the tensor tympani muscle. Through the ossicles, the vibrations of the tympanic membrane are transferred to the footplate of the stapes. The stapes moves with a piston-like action, which sends vibrations into a structure called the bony labyrinth. The labyrinth is filled with a fluid called paralymph. If it were a completely closed and inflexible system, the movement of the stapes would be unable to displace the paralymph and therefore unable to send vibrations into the bony structure.
Due to the flexibility of a membrane called the round window, the stapes movement can displace the paralymph, allowing vibrations to enter the labyrinth. The corridor leading to the round window is found within the spiral portion of the bony labyrinth known as the cochlea. Vibrations produced by the stapes are drawn into the spiral system and return to meet the round window. The portion of the spiral passage in which vibrations ascend to the apex of the cochlea is called the scala vestibuli. The descending portion of the passage is called the scala tympani.
A third structure called the cochlear duct is situated between the scala vestibuli and the scala tympani. The cochlear duct is filled with a fluid called endolymph and when viewed in cross-section the membranes separating the two fluid-filled systems are visible. They are Reissner's membrane and the basilar membrane. The membranes are flexible and move in response to the vibrations traveling up the scala vestibuli. The movements of the membranes then send vibrations back down to the scala tympani.
A specialized structure called the organ of Corti is situated on the basilar membrane. As the basilar membrane vibrates, the organ of Corti is stimulated, which sends nerve impulses to the brain via the cochlear nerve. The actual nerve impulses are generated by specialized cells within the organ of Corti called hair cells.
The hair cells are closely covered by a structure called the tectorial membrane. As the basilar membrane vibrates, the tiny clusters of hairs are bent against the tectorial membrane, triggering the hair cells to fire. The entire basilar membrane does not vibrate simultaneously.
Instead, specific areas along the basilar membrane move variably in response to different frequencies of sound. Lower frequencies vibrate the basilar membrane closer to the apex of the cochlea, whereas higher frequencies produce vibrations closer to the base. This arrangement is known as tonotopic organization. Together, this sequence of events is responsible for our acoustic perception of the world around us.