Larynx

For the remotely piloted vehicle, see RAE Larynx.
Larynx

Anatomy of the larynx, anterolateral view
Details
Identifiers
Latin larynx[1]
Greek λάρυγξ (lárynx)[1]
MeSH D007830
TA A06.2.01.001
FMA 55097

Anatomical terminology

The larynx /ˈlærɪŋks/ (plural larynges; from the Greek λάρυγξ lárynx),[1] commonly called the voice box, is an organ in the neck of amphibians, reptiles, and mammals involved in breathing, sound production, and protecting the trachea against food aspiration. It manipulates pitch and volume. The larynx houses the vocal folds (vocal cords), which are essential for phonation. The vocal folds are situated just below where the tract of the pharynx splits into the trachea and the oesophagus.

Vocal cords abducted and adducted
Basic parts of the human larynx

Structure

Cartilages

Posterior view of the larynx; disarticulated cartilages (left) and intrinsic muscles (right)

There are nine cartilages, three unpaired and three paired, that support the mammalian larynx and form its skeleton.

Unpaired cartilages:

Paired cartilages:

Muscles

The muscles of the larynx are divided into intrinsic and extrinsic muscles.

The intrinsic muscles are divided into respiratory and the phonatory muscles (the muscles of phonation). The respiratory muscles move the vocal cords apart and serve breathing. The phonatory muscles move the vocal cords together and serve the production of voice. The extrinsic, passing between the larynx and parts around; and intrinsic, confined entirely. The main respiratory muscles are the posterior cricoarytenoid muscles. The phonatory muscles are divided into adductors (lateral cricoarytenoid muscles, arytenoid muscles) and tensors (cricothyroid muscles, thyroarytenoid muscles).

Intrinsic

The intrinsic laryngeal muscles are responsible for controlling sound production.

Notably, the only muscle capable of separating the vocal cords for normal breathing is the posterior cricoarytenoid. If this muscle is incapacitated on both sides, the inability to pull the vocal folds apart (abduct) will cause difficulty breathing. Bilateral injury to the recurrent laryngeal nerve would cause this condition. It is also worth noting that all muscles are innervated by the recurrent laryngeal branch of the vagus except the cricothyroid muscle, which is innervated by the external laryngeal branch of the superior laryngeal nerve (a branch of the vagus).

Extrinsic

The extrinsic laryngeal muscles support and position the larynx within the trachea.

Extrinsic laryngeal muscles

Innervation

The larynx is innervated by branches of the vagus nerve on each side. Sensory innervation to the glottis and laryngeal vestibule is by the internal branch of the superior laryngeal nerve. The external branch of the superior laryngeal nerve innervates the cricothyroid muscle. Motor innervation to all other muscles of the larynx and sensory innervation to the subglottis is by the recurrent laryngeal nerve. While the sensory input described above is (general) visceral sensation (diffuse, poorly localized), the vocal fold also receives general somatic sensory innervation (proprioceptive and touch) by the superior laryngeal nerve.

Injury to the external laryngeal nerve causes weakened phonation because the vocal folds cannot be tightened. Injury to one of the recurrent laryngeal nerves produces hoarseness, if both are damaged the voice may or may not be preserved, but breathing becomes difficult.

Development

In adult humans, the larynx is found in the anterior neck at the level of the C3–C6 vertebrae. It connects the inferior part of the pharynx (hypopharynx) with the trachea. The laryngeal skeleton consists of nine cartilages: three single (epiglottic, thyroid and cricoid) and three paired (arytenoid, corniculate, and cuneiform). The hyoid bone is not part of the larynx, though the larynx is suspended from the hyoid. The larynx extends vertically from the tip of the epiglottis to the inferior border of the cricoid cartilage. Its interior can be divided in supraglottis, glottis and subglottis.

In newborn infants, the larynx is initially at the level of the C2–C3 vertebrae, and is further forward and higher relative to its position in the adult body.[3] The larynx descends as the child grows.[4][5]

Function

Sound generation

Sound is generated in the larynx, and that is where pitch and volume are manipulated. The strength of expiration from the lungs also contributes to loudness.

Manipulation of the larynx is used to generate a source sound with a particular fundamental frequency, or pitch. This source sound is altered as it travels through the vocal tract, configured differently based on the position of the tongue, lips, mouth, and pharynx. The process of altering a source sound as it passes through the filter of the vocal tract creates the many different vowel and consonant sounds of the world's languages as well as tone, certain realizations of stress and other types of linguistic prosody. The larynx also has a similar function to the lungs in creating pressure differences required for sound production; a constricted larynx can be raised or lowered affecting the volume of the oral cavity as necessary in glottalic consonants.

The vocal folds can be held close together (by adducting the arytenoid cartilages) so that they vibrate (see phonation). The muscles attached to the arytenoid cartilages control the degree of opening. Vocal fold length and tension can be controlled by rocking the thyroid cartilage forward and backward on the cricoid cartilage (either directly by contracting the cricothyroids or indirectly by changing the vertical position of the larynx), by manipulating the tension of the muscles within the vocal folds, and by moving the arytenoids forward or backward. This causes the pitch produced during phonation to rise or fall. In most males the vocal folds are longer and with a greater mass than most females' vocal folds, producing a lower pitch.

The vocal apparatus consists of two pairs of mucosal folds. These folds are false vocal folds (vestibular folds) and true vocal folds (folds). The false vocal folds are covered by respiratory epithelium, while the true vocal folds are covered by stratified squamous epithelium. The false vocal folds are not responsible for sound production, but rather for resonance. The exceptions to this are found in Tibetan Chant and Kargyraa, a style of Tuvan throat singing. Both make use of the false vocal folds to create an undertone. These false vocal folds do not contain muscle, while the true vocal folds do have skeletal muscle.

Other

Image of endoscopy

The most important role of the larynx is its protecting function; the prevention of foreign objects from entering the lungs by coughing and other reflexive actions. A cough is initiated by a deep inhalation through the vocal folds, followed by the elevation of the larynx and the tight adduction (closing) of the vocal folds. The forced expiration that follows, assisted by tissue recoil and the muscles of expiration, blows the vocal folds apart, and the high pressure expels the irritating object out of the throat. Throat clearing is less violent than coughing, but is a similar increased respiratory effort countered by the tightening of the laryngeal musculature. Both coughing and throat clearing are predictable and necessary actions because they clear the respiratory passageway, but both place the vocal folds under great strain and can be catastrophic to a trained voice.[6]

Another important role of the larynx is abdominal fixation, a kind of Valsalva maneuver in which the lungs are filled with air in order to stiffen the thorax so that forces applied for lifting can be translated down to the legs. This is achieved by a deep inhalation followed by the adduction of the vocal folds. Grunting while lifting heavy objects is the result of some air escaping through the adducted vocal folds ready for phonation.[6]

Abduction of the vocal folds is important during physical exertion. The vocal folds are separated by about 8 mm (0.31 in) during normal respiration, but this width is doubled during forced respiration.[6]

During swallowing, the backward motion of the tongue forces the epiglottis over the glottis' opening to prevent swallowed material from entering the larynx which leads to the lungs; the larynx is also pulled upwards to assist this process. Stimulation of the larynx by ingested matter produces a strong cough reflex to protect the lungs.

In addition, intrinsic laryngeal muscles (ILM) are spared from muscle wasting disorders, such as Duchenne muscular dystrophy, may facilitate the development of novel strategies for the prevention and treatment of muscle wasting in a variety of clinical scenarios. ILM have a calcium regulation system profile suggestive of a better ability to handle calcium changes in comparison to other muscles, and this may provide a mechanistic insight for their unique pathophysiological properties [7]

Clinical significance

Disorders

Endoscopic image of an inflamed human larynx

There are several things that can cause a larynx to not function properly.[8] Some symptoms are hoarseness, loss of voice, pain in the throat or ears, and breathing difficulties. Larynx transplant is a rare procedure. The world's first successful operation took place in 1998 at the Cleveland Clinic,[9] and the second took place in October 2010 at the University of California Davis Medical Center in Sacramento.[10]

Other animals

Cut through the larynx of a horse
(frontal section, posterior view)
1 hyoid bone; 2 epiglottis; 3 vestibular fold; 4 vocal fold; 5 ventricularis muscle; 6 ventricle of larynx; 7 vocalis muscle; 8 Thyroid Cartilage; 9 Cricoid Cartilage; 10 infraglottic cavity; 11 first tracheal cartilage; 12 trachea

Pioneering work on the structure and evolution of the larynx was carried out in the 1920s by the British comparative anatomist Victor Negus, culminating in his monumental work The Mechanism of the Larynx (1929). Negus, however, pointed out that the descent of the larynx reflected the reshaping and descent of the human tongue into the pharynx. This process is not complete until age six to eight years. Some researchers, such as Philip Lieberman, Dennis Klatt, Brant de Boer and Kenneth Stevens using computer-modeling techniques have suggested that the species-specific human tongue allows the vocal tract (the airway above the larynx) to assume the shapes necessary to produce speech sounds that enhance the robustness of human speech. Sounds such as the vowels of the words see and do, [i] and [u], (in phonetic notation) have been shown to be less subject to confusion in classic studies such as the 1950 Peterson and Barney investigation of the possibilities for computerized speech recognition.[15]

In contrast, though other species have low larynges their tongues remains anchored in their mouths and their vocal tracts cannot produce the range of speech sounds of humans. The ability to lower the larynx transiently in some species extends the length of their vocal tract, which as Fitch showed creates the acoustic illusion that they are larger. Research at Haskins Laboratories in the 1960s showed that speech allows humans to achieve a vocal communication rate that exceeds the fusion frequency of the auditory system by fusing sounds together into syllables and words. The additional speech sounds that the human tongue enables us to produce, particularly [i], allow humans to unconsciously infer the length of the vocal tract of the person who is talking, a critical element in recovering the phonemes that make up a word.[15]

Non-mammals

Most tetrapod species possess a larynx, but its structure is typically simpler than that found in mammals. The cartilages surrounding the larynx are apparently a remnant of the original gill arches in fish, and are a common feature, but not all are always present. For example, the thyroid cartilage is found only in mammals. Similarly, only mammals possess a true epiglottis, although a flap of non-cartilagenous mucosa is found in a similar position in many other groups. In modern amphibians, the laryngeal skeleton is considerably reduced; frogs have only the cricoid and arytenoid cartilages, while salamanders possess only the arytenoids.[16]

Vocal folds are found only in mammals, and a few lizards. As a result, many reptiles and amphibians are essentially voiceless; frogs use ridges in the trachea to modulate sound, while birds have a separate sound-producing organ, the syrinx.[16]

History

Roman physician Galen first described the larynx, describing it as the "first and supremely most important instrument of the voice"[17]

Additional images

See also

Wikimedia Commons has media related to Larynx.
Look up larynx in Wiktionary, the free dictionary.
This article uses anatomical terminology; for an overview, see Anatomical terminology.

References

Notes

  1. 1 2 3 "Larynx Etymology". Online Etymology Dictionary. Retrieved 25 October 2015.
  2. Collectively, the transverse and oblique arytenoids are known as the interarytenoids.
  3. "GERD and aspiration in the child: diagnosis and treatment". Grand Rounds Presentation. UTMB Dept. of Otolaryngology. February 23, 2005. Retrieved June 16, 2010.
  4. Laitman & Reidenberg 2009
  5. Laitman, Noden & Van De Water 2006
  6. 1 2 3 Seikel, King & Drumright 2010, Nonspeech laryngeal function, pp. 223–225
  7. http://onlinelibrary.wiley.com/doi/10.14814/phy2.12409/full
  8. Laitman & Reidenberg 1993
  9. Jensen, Brenda (January 21, 2011). "Rare transplant gives California woman a voice for the first time in a decade".
  10. Johnson, Avery (January 21, 2011). "Woman Finds Her Voice After Rare Transplant". Wall Street Journal. Retrieved 4 September 2012.
  11. Laitman & Reidenberg 1997
  12. Lipan, Reidenberg & Laitman 2006
  13. http://onlinelibrary.wiley.com/doi/10.1002/mus.20697/abstract
  14. http://onlinelibrary.wiley.com/doi/10.1002/mus.21154/abstract
  15. 1 2 Lieberman 2006
  16. 1 2 Romer & Parsons 1977, pp. 214–215, 336
  17. Hydman, Jonas (2008). Recurrent laryngeal nerve injury. Stockholm. p. 8. ISBN 978-91-7409-123-6.

Sources

  • Laitman, J.T.; Noden, D.M.; Van De Water, T.R. (2006). "Formation of the larynx: from homeobox genes to critical periods". In Rubin, J.S.; Sataloff, R.T.; Korovin, G.S. Diagnosis & Treatment Voice Disorders. San Diego: Plural. pp. 3–20. ISBN 9781597560078. OCLC 63279542. 
  • Laitman, J.T.; Reidenberg, J.S. (1993). "Specializations of the human upper respiratory and upper digestive tract as seen through comparative and developmental anatomy". Dysphagia 8 (4): 318–325. doi:10.1007/BF01321770. PMID 8269722. 
  • Laitman, J.T.; Reidenberg, J.S. (1997). "The human aerodigestive tract and gastroesophageal reflux: An evolutionary perspective". Am. J. Med. 103 (Suppl 5A): 3–11. doi:10.1016/s0002-9343(97)00313-6. PMID 9422615. 
  • Laitman, J.T.; Reidenberg, J.S. (2009). "The evolution of the human larynx: Nature’s great experiment". In Fried, M.P.; Ferlito, A. The Larynx (3rd ed.). San Diego: Plural. pp. 19–38. ISBN 1597560626. OCLC 183609898. 
  • Lieberman, P. (2006). Toward an Evolutionary Biology of Language. Harvard University Press. ISBN 0-674-02184-3. OCLC 62766735. 
  • Lipan, M.; Reidenberg, J.S; Laitman, J.T. (2006). "The anatomy of reflux: A growing health problem affecting structures of the head and neck". Anat Rec B New Anat. 289 (6): 261–270. doi:10.1002/ar.b.20120. OCLC 110307385. PMID 17109421. 
  • Romer, A.S.; Parsons, T.S. (1977). The Vertebrate Body. Philadelphia, PA: Holt-Saunders International. ISBN 0-03-910284-X. 
  • Seikel, J.A.; King, D.W.; Drumright, D.G. (2010). Anatomy & Physiology for Speech, Language, and Hearing (4th ed.). Delmar, NY: Cengage Learning. ISBN 1-4283-1223-4. 
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