The Ear – Anatomy, Blood and Nerve Supply, Function

Structure of The Ear

The ear is organized into three different anatomical structures: the outer, middle, and inner ear. The outer ear consists of the pinna, external auditory canal, and tympanic membrane and is responsible for the transmission of sound waves from the external environment.[rx] The middle ear is an air-filled space that contains the three ossicles (malleus, incus, and stapes), which are bones responsible for transmitting vibrations from the tympanic membrane to the inner ear. Vibrations are transmitted from the malleus through the incus to the stapes, which is in contact with the cochlear oval window. The inner ear is located within the bony labyrinth of the temporal bone and contains the cochlea, semicircular canals, utricle, and saccule. These organs make up the membranous labyrinth that is within the bony labyrinth, separated only by perilymph. The membranous labyrinth contains a fluid known as endolymph, which plays a vital role in the excitation of hair cells responsible for sound and vestibular transmission.

The cochlea is a spiral-shaped fluid-filled organ located within the cochlear duct of the inner ear. The cochlea contains three distinct anatomic compartments: the scala vestibule, scala media (also referred to as the cochlear duct), and scala tympani. The scala vestibuli and scala tympani both contain perilymph and surround the scala media, which contains endolymph. The endolymph within the scala media originates from cerebrospinal fluid (CSF) and is secreted by the stria vascularis, which is a network of capillaries located in the spiral ligament. The perilymph in the scala vestibuli originates from blood plasma, whereas the perilymph in the scala tympani comes from CSF. Endolymph and perilymph vary significantly in their concentration of ions, which is essential to the overall function of the cochlea. Endolymph is rich in potassium and low in sodium and calcium, whereas perilymph is rich in sodium and low in potassium and calcium. This difference in concentration allows for a positive endocochlear potential. The difference in concentration of potassium ions among the three fluid compartments within the cochlea enables proper transduction of current along with the hair cells.

Hearing

Vibration from the stapes gets transmitted through the oval window, which is an opening into the inner ear through which the middle and inner ear communicate. Vibrations across the oval window initiate a perilymph wave that propagates along the scala vestibule, with high frequency sounds dissipating earlier at the base of the cochlea and low-frequency sounds dissipating later towards the apex of the cochlea. The perilymphatic wave terminates at the round window, another point at which the middle ear communicates with the inner ear. In contrast to the oval window, the round window does not articulate with the stapes. Rather, the round window membrane is located inferomedial to the oval window and functions to counteract the fluid shift created in the cochlea. The presence of the round window allows for fluid to move more freely through the cochlea, thereby improving sound transmission.

As vibration transmits across the oval window, perilymph gets pushed towards the cochlear apex, which causes the scala media to become compressed. Within the scala media, there is a tectorial membrane that sits atop the organ of Corti. The compression of the scala media causes the tectorial membrane to change the position of cells within the organ of Corti.

The organ of Corti is located within the scala media and is responsible for converting mechanical forces into electrical impulses. It contains 15000 inner and outer hair cells that are arranged tonotopically throughout the cochlea to help distinguish between sounds of varying frequencies. The hair cells have projections known as stereocilia and kinocilia that are in contact with the tectorial membrane. Vibrations transmitted to the tectorial membrane cause displacement of stereocilia, leading to the displacement of the adjacent kinocilia. Movement of the kinocilia triggers depolarization of the hair cell, leading to an influx of calcium and the release of specific neurotransmitters that act at the cochlear ganglion. This activity produces an action potential that is propagated along the cochlear nerve and along auditory pathways, where it eventually reaches the cochlear nuclei located in the brainstem.[rx]

Balance

The inner ear also contains the vestibular organs that are responsible for balance and position. The vestibular organs include the semicircular canals, utricle, and saccule. To understand the anatomy of the vestibular organs, it is helpful to separate the vestibular organs based on their specific functions. The semicircular canals, including their ampullas, are responsible for angular acceleration (rotational movement of the head), whereas the utricle and saccule are involved in linear acceleration.[rx]

Semicircular canals

There are three semicircular canals; anterior, posterior, and lateral. Each semicircular canal is located in a different plane (x,y, and z) and connects to the utricle via an ampulla, which is a widening of the canal. Within the ampulla, there are sensory epithelia known as cristae that contain projections of hair cells. Above the hair cells and cristae, there is a gelatinous cupula. As the head rotates in various directions, endolymph flowing through the semicircular canals displaces the gelatinous cupula that rests above the cristae leading to excitation of the hair cells embedded within the cristae. The hair cells become depolarized or hyperpolarized depending on the direction in which endolymph flows.[rx]

Utricle and Saccule

The utricle and saccule each contain a macula, which is the fundamental end-organ (the equivalent of the crista within the ampulla described in the previous section) involved in detecting linear acceleration. The utricle is involved in longitudinal acceleration, whereas the saccule is involved in acceleration along the vertical axis. Each macule contains hair cells and supporting cells that are surrounded by a gelatinous layer, which is covered by an otolithic membrane. Resting atop the otolithic membrane are otoconia, which are heavy calcium carbonate crystals. Linear acceleration of the head causes a shear force between the otolithic membrane and macula, causing displacement of the hair bundles. Similar to the hair bundles within the ampulla of the semicircular canals, displacement of the hair cells in the macula leads to the generation of a potential depending on the direction of movement. The movement towards the kinocilium causes the opening of channels and a subsequent depolarization of the cell. The movement away from the kinocilium causes the closure of channels leading to hyperpolarization of nerve fibers.

Blood Supply of The Ear

The blood supply to the inner ear is via the labyrinthine artery (LA), also known as the internal auditory artery.[rx] The LA usually arises from the anterior inferior cerebellar artery (83.6%), but can also arise from the basilar artery (12.3%).[rx] It enters the internal acoustic meatus alongside the vestibulocochlear nerve and supplies both the facial and the vestibulocochlear nerves.[rx] The LA then divides into three arteries while coursing through the internal acoustic canal:

• (1) anterior vestibular artery (AVA),
• (2) vestibulocochlear artery (VCA), and
• (3) cochlear artery (CA).[rx]

The VCA separates into the cochlear and vestibular branches. The cochlear branch eventually forms an anastomosis with the CA, which makes up the main vascular supply to the cochlea. The vestibular branch and the AVA are responsible for vascular supply to the vestibular system.

Vestibular and cochlear aqueducts are responsible for venous drainage of the inner ear. The anterior and posterior spiral modiolar veins drain blood from the cochlea. The anterior and posterior vestibular veins drain blood from the vestibule, connects with the vein of the round window (RW), and eventually empties into the inferior cochlear vein (ICV). The ICV then drains into the inferior petrosal sinus.

Lymphatic fluid in the inner ear plays a critical role, circulating inside the cells and transferring metabolites from the CSF.[rx] The membranous labyrinth is filled with and surrounded by lymphatic fluid. Perilymph, also derived from the lymphatic system, is present between the membranous and bony labyrinth. Lymphatic fluid drains through lymphatic chains from the middle ear to the cervical lymph nodes. Studies in guinea pigs showed that the inner ear drains to the parotid nodes and the superficial ventral cervical lymph nodes.[rx]

Nerves

The vestibulocochlear nerve transmits an electrochemical signal from the cochlea, semicircular canals, and vestibule through the internal acoustic meatus and into the posterior cranial fossa.[rx]

Cochlear nerve

Impulses begin in the hair cells located within the spiral ganglion of the cochlea. Depolarization of hair cells propagates to the cochlear nerve.

Vestibular nerves

Impulses begin in hair cells located within the ampulla of the semicircular canals and the utricle and saccule. There is a vestibular ganglion, known as Scarpa’s ganglion, that exists within the internal acoustic meatus at the junction at which the vestibular and cochlear nerve meet. The bipolar cells that comprise Scarpa’s ganglion have dendritic processes that retrieve electrochemical impulses directly from the hair cells. Specifically, the superior vestibular nerve innervates the utricle and superior and lateral semicircular canals. The inferior vestibular nerve innervates the saccule and inferior/posterior semicircular canal. The bipolar cells then transfer the electrochemical impulse via axonal fibers to the vestibular nerve.[rx]

Vestibulocochlear nerve

The vestibulocochlear nerve refers to the point at which the vestibular and cochlear nerve course together through the internal auditory meatus. After entering the posterior cranial fossa, CN VIII enters the brainstem between the pons and medulla and synapses on nuclei within the pons. The cochlear nerve synapses on the dorsal and ventral cochlear nuclei. The vestibular nerve synapses on the superior, inferior, medial, and lateral vestibular nuclei.[rx]

Muscles of The Ear

Two important muscles within the middle ear are responsible for modulating the auditory signal:

Stapedius muscle

The stapedius muscle is only one millimeter in length, making it the smallest skeletal muscle in the entire body. The stapedius is attached to the stapes and helps modulate the transfer of sound waves from the external environment to the inner ear. In particular, it serves to decrease the vibration of the stapes, thereby dampening the sound energy that reaches the cochlea. The stapedius muscle receives innervation by a branch of the facial nerve (CN VII). Dysfunction of the stapedius muscle can lead to hyperacusis, a disorder characterized by impaired tolerance to certain noises due to an inability to dampen sounds entering the middle ear.[rx]

Tensor tympani

The tensor tympani also plays a role in sound modulation by tensing the tympanic membrane to prevent loud sounds from damaging the inner ear. The tensor tympani originates in the cartilaginous portion of the Eustachian tube that connects the pharynx to the middle ear. The muscle inserts on the medial portion of the malleus. It gets innervated by the mandibular division of the trigeminal nerve (CN V). The tensor tympani is activated during talking, chewing, coughing, and laughing.[rx]

Middle ear myoclonus (MEM), one of many causes of pulsatile tinnitus, is due to dysfunction of either the tensor tympani or stapedius muscle. It is often characterized as a clicking sound with the involvement of the tensor tympani and as a buzzing sound when due to the dysfunctional movement of the stapedius. It has also been described as a tapping, throbbing, fluttering, or whooshing sound. The tinnitus is usually objective and, therefore, can be heard by the examiner. MEM has been treated successfully in the past with surgical removal of the involved tendon. However, there is still some controversy over what the best approach to treatment is, warranting more prospective controlled trials.[rx]

• https://www.ncbi.nlm.nih.gov/books/NBK532978/
• https://www.ncbi.nlm.nih.gov/books/NBK557380/
• https://www.ncbi.nlm.nih.gov/pmc/articles/PMC2561233/
• https://www.ncbi.nlm.nih.gov/books/NBK532311/
• https://www.ncbi.nlm.nih.gov/books/NBK537359/
• https://www.ncbi.nlm.nih.gov/books/NBK531483/
• https://www.ncbi.nlm.nih.gov/books/NBK551658/
• https://www.ncbi.nlm.nih.gov/books/NBK542323/
• https://www.ncbi.nlm.nih.gov/books/NBK538335/
• https://www.ncbi.nlm.nih.gov/books/NBK430809/
• https://www.ncbi.nlm.nih.gov/books/NBK544280/
• https://www.ncbi.nlm.nih.gov/books/NBK540992/
• https://www.ncbi.nlm.nih.gov/books/NBK544288/
• https://www.ncbi.nlm.nih.gov/books/NBK470177/
• https://www.ncbi.nlm.nih.gov/books/NBK526135/
• https://www.ncbi.nlm.nih.gov/books/NBK557713/
• https://www.ncbi.nlm.nih.gov/books/NBK556014/
• https://www.ncbi.nlm.nih.gov/books/NBK470359/
• https://www.ncbi.nlm.nih.gov/books/NBK1434/
• https://www.ncbi.nlm.nih.gov/books/NBK559220/
• https://www.ncbi.nlm.nih.gov/books/NBK227/
• https://www.ncbi.nlm.nih.gov/books/NBK448117/
• https://www.ncbi.nlm.nih.gov/books/NBK459335/
• https://en.wikipedia.org/wiki/Auditory_system