Tensor tympani muscle

The tensor tympani is a muscle within the ear, located in the bony canal above the osseous portion of the auditory tube. Its role is to damp loud sounds, such as those produced from chewing, shouting, or thunder. Because its reaction time is not fast enough, the muscle cannot protect against hearing damage caused by sudden loud sounds, like explosions or gunshots.

Tensor tympani muscle
The right membrana tympani with the hammer and the chorda tympani, viewed from within, from behind, and from above.
The medial wall and part of the posterior and anterior walls of the right tympanic cavity, lateral view. (Label for "Tensor tympani muscle" is at right, second from bottom.)
Details
OriginAuditory tube
InsertionHandle of the malleus
ArterySuperior tympanic artery
NerveMedial pterygoid nerve from the mandibular nerve (V3)
ActionsTensing the tympanic membrane
Identifiers
LatinMusculus tensor tympani
MeSHD013719
TAA15.3.02.061
FMA49028
Anatomical terms of muscle

Structure

Insertion of the tensor tympani muscle onto the malleus. . AA’ ( two fibrous collagenic layers); B épidermis; C mucous membrane; D head of malleus; E incus; F stapes; G tensor tympani; H lateral process of malleus; I Manubrium of malleus; J stapedius muscle.

The tensor tympani arises from the cartilaginous portion of the auditory tube, and the adjoining part of the great wing of the sphenoid, as well as from the osseous canal in which it is contained. Passing backward through the canal, it ends in a slender tendon which enters the tympanic cavity, makes a sharp bend around the extremity of the septum, known as the processus cochleariformis, and is inserted into the upper part of the medial surface of the handle of malleus.[1][2]

The tensor tympani is the larger of the two muscles of the tympanic cavity, the other being the stapedius.

Innervation

Innervation of the tensor tympani is from the tensor tympani nerve, a branch of the mandibular division of the trigeminal nerve.[1] As the tensor tympani is innervated by motor fibers of the trigeminal nerve, it does not receive fibers from the trigeminal ganglion, which has sensory fibers only.

Development

The tensor tympani muscle develops from mesodermal tissue in the 1st pharyngeal arch.[3]

Function

The tensor tympani acts to dampen the noise produced by chewing. When tensed, the muscle pulls the malleus medially, tensing the tympanic membrane and damping vibration in the ear ossicles and thereby reducing the perceived amplitude of sounds.[1]

Voluntary control

Contracting muscles produce vibration and sound.[4] Slow twitch fibers produce 10 to 30 contractions per second (equivalent to 10 to 30 Hz sound frequency). Fast twitch fibers produce 30 to 70 contractions per second (equivalent to 30 to 70 Hz sound frequency).[5] The vibration can be witnessed and felt by highly tensing one's muscles, as when making a firm fist. The sound can be heard by pressing a highly tensed muscle against the ear, again a firm fist is a good example. The sound is usually described as a rumbling sound.

Some individuals can voluntarily produce this rumbling sound by contracting the tensor tympani muscle of the middle ear. The rumbling sound can also be heard when the neck or jaw muscles are highly tensed as when yawning deeply. This phenomenon has been known since (at least) 1884.[6]

Involuntary control (tympanic reflex)

The tympanic reflex helps prevent damage to the inner ear by muffling the transmission of vibrations from the tympanic membrane to the oval window. The reflex has a response time of 40 milliseconds, not fast enough to protect the ear from sudden loud noises such as an explosion or gunshot. Thus, the reflex most likely developed to protect early humans from loud thunder claps which do not happen in a split second.[7]

The reflex works by contracting the muscles of the middle ear, the tensor tympani and the stapedius. This pulls the manubrium of the malleus inwards and tightens it. This tightening prevents the vibrations from disturbing the perilymph. Withdrawal from drugs such as benzodiazepines had been known to cause tonic tensor tympani syndrome (TTTS) during withdrawal. The tympanic reflex will also activate when loud vibrations are generated by the person themselves. The tensor tympani can often be observed vibrating while shouting at an increased volume, dampening the sound somewhat.

Clinical significance

In many people with hyperacusis, an increased activity develops in the tensor tympani muscle in the middle ear as part of the startle response to some sounds. This lowered reflex threshold for tensor tympani contraction is activated by the perception/anticipation of loud sound, and is called tonic tensor tympani syndrome (TTTS). In some people with hyperacusis, the tensor tympani muscle can contract just by thinking about a loud sound. Following exposure to intolerable sounds, this contraction of the tensor tympani muscle tightens the ear drum, which can lead to the symptoms of ear pain/a fluttering sensation/a sensation of fullness in the ear (in the absence of any middle or inner ear pathology).

The mechanisms behind dysfunction of the tympanic tensor muscle and their consequences are hypotheses. However, in a published study, researchers studied the case of an acoustic shock whose mechanisms suggest dysfunction of the tympanic tensor muscle. This study appears to be the first to provide experimental support suggesting that middle ear muscles (MEM) may behave abnormally after an acoustic shock. It is suggested that abnormal contractions (e.g. tonic contractions) of the tympanic tensor muscle may trigger neurogenic inflammation. Indeed, fibers with substances P and CGRP were found in close proximity.[8][9]

See also

References

This article incorporates text in the public domain from page 1046 of the 20th edition of Gray's Anatomy (1918)

  1. Drake, Richard L.; Vogl, Wayne; Tibbitts, Adam; W.M. Mitchell (2005). Gray's anatomy for students. Illustrations by Richard; Richardson, Paul (Pbk. ed.). Philadelphia: Elsevier/Churchill Livingstone. pp. 862–3. ISBN 978-0-443-06612-2.
  2. Standring, Susan (2015-08-07). Gray's Anatomy E-Book: The Anatomical Basis of Clinical Practice. Elsevier Health Sciences. ISBN 9780702068515.
  3. Moore, Keith (2003). The Developing Human: Clinically Oriented Embryology (7th ed.). Philadelphia, Pennsylvania: Saunders. pp. 204–208. ISBN 0-7216-9412-8.
  4. Barry DT (1992). "Vibrations and sounds from evoked muscle twitches". Electromyography and Clinical Neurophysiology. 32 (1–2): 35–40. PMID 1541245.
  5. September 2009 - Welcome to racewalkingnewzealand.org, PROGRAM FITNESS NEWSLETTER September 2009 by Gary Little
  6. cf : Tillaux Paul Jules, Traité d’Anatomie topographique avec applications à la chirurgie, Paris Asselin et Houzeau publishers (4°ed. 1884, p. 125 )
  7. Saladin, Kenneth (2012). Anatomy and Physiology: The Unity of Form and Function (6th ed.). New York: McGraw-Hill. p. 601. ISBN 978-0-07-337825-1.
  8. Londero A, Charpentier N, Ponsot D, Fournier P, Pezard L and Noreña AJ (2017) A Case of Acoustic Shock with Post-trauma Trigeminal-Autonomic Activation. Front. Neurol. 8:420. doi: 10.3389/fneur.2017.00420
  9. Yamazaki M, Sato I. Distribution of substance P and the calcitonin gene-related peptide in the human tensor tympani muscle. European Archives of Oto-Rhino-Laryngology. 2014;271(5):905-911. doi:10.1007/s00405-013-2469-1.
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