Stapes

Medically Reviewed by Anatomy Team

The stapes is the smallest and lightest bone in the human body, and it is one of the three auditory ossicles located in the middle ear. Shaped like a stirrup, the stapes consists of a head, neck, two limbs (anterior and posterior crura), and a base called the footplate. It plays a crucial role in sound transmission by connecting the middle ear to the inner ear. The stapes is essential for transferring sound vibrations into the cochlea for further processing.

Location

The stapes is located in the middle ear, where it connects to the incus at the incudostapedial joint. Its footplate rests on the oval window, a membrane-covered opening that leads into the fluid-filled cochlea in the inner ear. The stapes is suspended by ligaments within the tympanic cavity.

Structure and Anatomy

The stapes is the smallest bone in the human body and forms the final link in the chain of three ossicles in the middle ear. It has a distinctive stirrup-like shape and several anatomical features that are essential for its role in transmitting sound vibrations from the middle ear to the inner ear.

General Shape and Size

The stapes is approximately 3-4 mm in length and weighs about 2-4 milligrams, making it both the smallest and lightest bone in the human body. Its stirrup shape consists of several key parts that contribute to its ability to efficiently transmit sound vibrations.

Key Anatomical Features

  • Head of the Stapes:
    • The head of the stapes is a rounded structure located at the superior part of the bone.
    • It articulates with the lenticular process of the incus at the incudostapedial joint, a small synovial joint that allows for movement between the two ossicles.
    • The head of the stapes serves as the attachment point for the stapedius muscle, the smallest muscle in the body.
  • Neck of the Stapes:
    • The neck is a slender, constricted region just below the head.
    • The stapedius muscle attaches to the neck, providing a point of leverage for the muscle’s role in regulating sound transmission.
  • Anterior and Posterior Limbs (Crura):
    • The stapes has two thin, curved bony projections called the anterior crus and posterior crus, which extend from the neck of the stapes to the base (footplate).
    • The anterior and posterior crura are slightly different in length and curvature, with the posterior crus typically being longer and more curved than the anterior.
    • These crura create the stirrup-like appearance of the stapes and provide structural support while allowing the base of the stapes to vibrate efficiently.
  • Base (Footplate):
    • The footplate is a flat, oval-shaped structure at the bottom of the stapes. It forms the base of the bone and fits into the oval window, a membrane-covered opening that leads to the fluid-filled cochlea in the inner ear.
    • The footplate is anchored to the edges of the oval window by the annular ligament, which allows it to move in a piston-like fashion in response to sound vibrations, thereby transferring energy to the inner ear fluids.

Articulations

  • Incudostapedial Joint: The stapes articulates with the incus at the incudostapedial joint, a small but flexible synovial joint. This articulation allows the stapes to move in response to vibrations passed from the tympanic membrane through the ossicular chain.
  • Oval Window: The footplate of the stapes fits into the oval window of the cochlea. This location is essential for transmitting sound vibrations from the air-filled middle ear into the fluid-filled inner ear.

Ligamentous Attachments

Annular Ligament:

  • The footplate of the stapes is attached to the oval window by the annular ligament, a ring-like ligament that surrounds the footplate and holds it securely within the oval window while still allowing the necessary movement.
  • The elasticity of the annular ligament is critical for the piston-like movement of the stapes, which allows it to transfer sound energy efficiently to the cochlear fluids.

Muscular Attachments

Stapedius Muscle: The stapedius muscle attaches to the neck of the stapes. This tiny muscle, the smallest in the human body, plays a role in modulating the movement of the stapes by pulling on its neck, although its specific function is beyond the scope of this anatomical description.

Blood Supply

The stapes is supplied by the anterior tympanic artery, a branch of the maxillary artery, which provides blood to the ossicles and surrounding structures.

Nerve Supply

The stapes is innervated by the facial nerve (cranial nerve VII) through a small branch that also supplies the stapedius muscle.

Function

The stapes plays a crucial role in hearing by acting as the final link in the chain of three ossicles that transmit sound vibrations from the tympanic membrane (eardrum) to the inner ear. Its structure and movement allow it to efficiently transfer sound energy while amplifying vibrations for proper auditory processing. Below are the key functions of the stapes.

Transmission of Sound Vibrations

The primary function of the stapes is to transmit sound vibrations from the middle ear to the inner ear.

Mechanism:

  • Sound waves that reach the eardrum cause it to vibrate. These vibrations are passed along the ossicular chain from the malleus to the incus, and finally to the stapes.
  • The head of the stapes moves in response to the vibrations received from the incus via the incudostapedial joint. As the stapes moves, its footplate transmits these vibrations into the oval window, a membrane-covered opening that leads to the fluid-filled cochlea of the inner ear.

Importance:

The stapes serves as the direct link between the air-filled middle ear and the fluid-filled inner ear. Without the efficient movement of the stapes, sound energy would not reach the inner ear, making the process of hearing impossible.

 Amplification of Sound

The stapes plays an essential role in amplifying the sound vibrations it receives from the other ossicles, increasing their intensity as they pass into the inner ear.

Mechanism:

  • The size difference between the tympanic membrane and the footplate of the stapes plays a crucial role in amplification. The tympanic membrane is much larger than the footplate, and as sound vibrations are transmitted through the ossicular chain, they are focused onto the much smaller surface area of the stapes’ footplate.
  • This size difference acts like a mechanical lever, amplifying the force of the sound vibrations as they are transferred into the inner ear.

Importance:

This amplification is necessary because sound waves must transition from the air-filled middle ear to the fluid-filled cochlea. Fluid is denser than air, and without amplification, much of the sound energy would be lost in this transition. The stapes helps overcome this energy loss, ensuring that sound vibrations are strong enough to stimulate the inner ear’s sensory cells.

 Transfer of Vibrations to the Inner Ear Fluids

The stapes is uniquely responsible for transferring sound energy from the middle ear to the fluid-filled inner ear, specifically the perilymph within the cochlea.

Mechanism:

  • As the footplate of the stapes moves in response to sound vibrations, it pushes against the membrane of the oval window. This movement displaces the fluid inside the cochlea, creating pressure waves in the inner ear’s fluids.
  • These pressure waves travel through the cochlear fluid and stimulate sensory hair cells within the cochlea, which then convert the mechanical sound vibrations into electrical signals that are sent to the brain for interpretation as sound.

Importance:

The fluid displacement caused by the stapes’ movement is critical for the activation of the sensory structures within the cochlea, known as hair cells. These cells are responsible for translating the mechanical movements of the stapes into the neural signals that the brain interprets as sound. Without the stapes effectively transferring energy, this process would not occur, resulting in hearing loss.

Fine-Tuned Control of Sound Transmission

The stapes is part of a finely-tuned system that ensures sound vibrations are transmitted accurately and efficiently, even across a wide range of frequencies and intensities.

Mechanism:

  • The movement of the stapes is modulated by the stapedius muscle, which is attached to its neck. The stapedius muscle contracts in response to loud sounds, pulling on the stapes and slightly reducing its movement. This action helps to dampen the transmission of sound vibrations, protecting the inner ear from damage caused by excessive sound levels (a process known as the acoustic reflex).
  • The flexibility of the annular ligament surrounding the stapes’ footplate also allows the stapes to adapt its movement in response to different sound intensities.

Importance:

The stapes’ ability to fine-tune sound transmission is essential for protecting the inner ear from loud noises and preventing over-stimulation of the hair cells. This fine control also helps ensure that sound is transmitted efficiently across different frequency ranges, allowing for a rich auditory experience.

Regulation of Fluid Movement in the Cochlea

By pushing on the oval window, the stapes sets up a chain reaction of fluid movement in the cochlea that is essential for auditory signal processing.

Mechanism:

  • As the footplate of the stapes moves in and out of the oval window, it creates alternating pressure waves in the perilymph of the cochlea. These waves travel through the spiral-shaped cochlea, ultimately stimulating hair cells that detect different sound frequencies.
  • The pressure changes created by the stapes also affect the movement of the round window, a second membrane-covered opening in the cochlea, which compensates for the pressure created by the movement of the stapes in the oval window.

Importance:

Proper regulation of fluid movement in the cochlea is essential for the detection of sound frequencies and the preservation of hearing sensitivity. The stapes’ movement ensures that this fluid movement is precise and allows the ear to process a wide range of sound intensities and frequencies.

 Acoustic Reflex and Hearing Protection

The stapes, in conjunction with the stapedius muscle, is involved in the acoustic reflex, which helps protect the ear from damage due to loud noises.

Mechanism:

  • When exposed to loud sounds, the stapedius muscle contracts, pulling the stapes away from the oval window. This action reduces the movement of the stapes, thereby limiting the amount of sound energy transferred to the inner ear.
  • This reflex helps prevent damage to the delicate hair cells within the cochlea, which can be harmed by excessive vibration from loud sounds.

Importance:

The acoustic reflex involving the stapes is a protective mechanism that helps maintain hearing health by preventing acoustic trauma. This reflex is particularly important in environments with sudden or sustained loud noises, as it helps minimize the risk of inner ear damage.

Clinical Significance

The stapes plays a vital role in hearing, and any disruption to its function can lead to significant hearing loss. One of the most common conditions affecting the stapes is otosclerosis, where abnormal bone growth around the stapes immobilizes its movement, leading to conductive hearing loss. Otosclerosis often requires surgical intervention, such as stapedectomy, where the stapes is either repaired or replaced with a prosthesis to restore hearing.

Additionally, trauma or infection can damage the stapes or its connections, further impairing sound transmission. Conditions like cholesteatoma can also erode the stapes, necessitating surgical treatment to prevent further hearing damage. Given its role in sound amplification and transmission, maintaining the structural and functional integrity of the stapes is crucial for proper auditory function.

In this Article: