Carotid body

Carotid body

Section of part of human glomus caroticum. Highly magnified. Numerous blood vessels are seen in section among the gland cells.

Diagram showing the origins of the main branches of the carotid arteries.
Details
Identifiers
Latin glomus caroticum
TA A12.2.04.007
FMA 50095

Anatomical terminology

The carotid body (carotid glomus or glomus caroticum) is a small cluster of chemoreceptors and supporting cells located near the fork (bifurcation) of the carotid artery (which runs along both sides of the throat).

The carotid body detects changes in the composition of arterial blood flowing through it, mainly the partial pressure of oxygen, but also of carbon dioxide. Furthermore, it is also sensitive to changes in pH and temperature.

Structure

The carotid body is made up of two types of cells, called glomus cells: glomus type I (chief) cells, and glomus type II (sustentacular cells).

The carotid body contains the most vascularized tissue in the human body . The thyroid gland is very vascular, but not quite as much as the carotid body.

Function

The carotid body functions as a sensor: it responds to a stimulus, primarily O2 partial pressure, which is detected by the type I (glomus) cells, and triggers an action potential through the afferent fibers of the glossopharyngeal nerve, which relays the information to the central nervous system.

Stimulus

While the central chemoreceptors in the brainstem are highly sensitive to CO2, the carotid body is a peripheral chemoreceptor that mainly provides afferent input to the respiratory center that is highly O2 dependent. However, the carotid body also senses increases in CO2 partial pressure and decreases in arterial pH, but to a lesser degree than for O2

The output of the carotid bodies is low at an oxygen partial pressure above about 100mmHg (13,3 kPa) (at normal physiological pH), but below 60mmHg the activity of the type I (glomus) cells increases rapidly due to a decrease in hemoglobin-oxygen saturation below 90%.

Detection

The mechanism for detecting reductions in PO2 has yet to be identified, there may be multiple mechanisms and could vary between species.[2] Hypoxia detection has been shown to depend upon increased hydrogen sulfide generation produced by cystathionine gamma-lyase as hypoxia detection is reduced in mice in which this enzyme is knocked out or pharmacologically inhibited. The process of detection involves the interaction of cystathionine gamma-lyase with hemeoxygenase-2 and the production of carbon monoxide.[3] Yet, some studies show that physiologic concentration of hydrogen sulfide may not be strong enough to trigger such responses.

Other theories suggest it may involve mitochondrial oxygen sensors and the haem-containing cytochromes that undergo reversible one-electron reduction during oxidative-phosphorylation. Haem reversibly binds O2 with an affinity similar to that of the carotid body, suggesting that haem containing proteins may have a role in O2, potentially this could be one of the complexes involved in oxidative-phosphorylation. This leads to increases in reactive oxygen species and rises in intracellular Ca2+. However, whether hypoxia leads to an increase or decrease in reactive oxygen species is unknown. The role of reactive oxygen species in hypoxia sensing is also under question.[4]

The oxygen dependent enzyme haem-oxidase has also been put forward as a hypoxia sensor. In normoxia, haem-oxygenase generates carbon monoxide (CO), CO activates the large conductance calcium-activated potassium channel, BK. Falls in CO that occur as a consequence of hypoxia would lead to closure of this potassium channel and this would lead to membrane depolarisation and consequence activation of the carotid body.[5] A role for the "energy sensor" AMP-activated protein kinase (AMPK) has also been proposed in hypoxia sensing. This enzyme is activated during times of net energy usage and metabolic stress, including hypoxia. AMPK has a number of targets and it appears that, in the carotid body, when AMPK is activated by hypoxia, it leads to downstream potassium channel closure of both O2-sentive TASK-like and BK channels[6]

An increased pCO2 is detected because the CO2 diffuses into the cell, where it increases the concentration of carbonic acid and thus protons. The precise mechanism of CO2 sensing is unknown, however it has been demonstrated that CO2 and low pH inhibit a TASK-like potassium conductance, reducing potassium current. This leads to depolarisation of the cell membrane which leads to Ca2+ entry, excitation of glomus cells and consequent neurotransmitter release.[7]

Arterial acidosis (either metabolic or from altered PCO2) inhibits acid-base transporters (e.g. Na+-H+) which raise intracellular pH, and activates transporters (e.g. Cl-HCO3) which decrease it. Changes in proton concentration caused by acidosis (or the opposite from alkalosis) inside the cell stimulates the same pathways involved in PCO2 sensing.

Another mechanism is through oxygen sensitive potassium channels. A drop in dissolved oxygen lead to closing of these channels which results in depolarization. This leads to release of the neurotransmitter dopamine in the glossopharyngeal and vagus afferente to the vasomotor area.

Action potential

The type I (glomus) cells in the carotid (and aortic bodies) are derived from neuroectoderm and are thus electrically excitable. A decrease in oxygen partial pressure, an increase in carbon dioxide partial pressure, and a decrease in arterial pH can all cause depolarization of the cell membrane, and they affect this by blocking potassium currents. This reduction in the membrane potential opens voltage-gated calcium channels, which causes a rise in intracellular calcium concentration. This causes exocytosis of vesicles containing a variety of neurotransmitters, including acetylcholine, noradrenaline, dopamine, adenosine, ATP, substance P, and met-enkephalin. These act on receptors on the afferent nerve fibres which lie in apposition to the glomus cell to cause an action potential.

Relay

The feedback from the carotid body is sent to the cardiorespiratory centers in the medulla oblongata via the afferent branches of the Glossopharyngeal nerve. The afferent fibres of the aortic body chemoreceptors are relayed by the Vagus nerve. These centers, in turn, regulate breathing and blood pressure, with hypoxia causing an increase in ventilation.

Clinical significance

Micrograph of a carotid body tumor.

Paraganglioma

Main article: Paraganglioma

A paraganglioma is a tumor that may involve the carotid body and is usually benign. Rarely, a malignant neuroblastoma may originate from the carotid body.

Innervated by Glossopharyngeal Nerve (cranial nerve IX).

See also

References

  1. Gonzalez C, Almaraz L, Obeso A, Rigual R (1994). "Carotid body chemoreceptors: from natural stimuli to sensory discharges". Physiol. Rev. 74 (4): 829–98. PMID 7938227.
  2. Ward JP (2008). "Oxygen sensors in context.". Biochim Biophys Acta. 1777 (1): 1–14. doi:10.1016/j.bbabio.2007.10.010. PMID 18036551.
  3. Peng Y-J, Nanduri J, Raghuraman G, Souvannakitti D, Gadalla M.M, Kumar GK, Snyder SH, Prabhakar NR. (2010). H2S mediates O2 sensing in the carotid body PNAS 107 (23) 10719-10724. doi:10.1073/pnas.1005866107
  4. Gonzalez C, Sanz-Alfayate G, Agapito MT, Gomez-Niño A, Rocher A, Obeso A (2002). "Oxygen sensors in context.". Respir Physiol Neurobiol. 132 (1): 17–41. doi:10.1016/S1569-9048(02)00047-2. PMID 12126693.
  5. Williams SE, Wootton P, Mason HS, Bould J, Iles DE, Riccardi D, Peers C, Kemp PJ (2004). "Hemoxygenase-2 is an oxygen sensor for a calcium-sensitive potassium channel". Science. 306 (5704): 2093–7. doi:10.1126/science.1105010. PMID 15528406.
  6. Wyatt CN, Mustard KJ, Pearson SA, Dallas ML, Atkinson L, Kumar P, Peers C, Hardie DG, Evans AM (2007). "AMP-ACTIVATED PROTEIN KINASE MEDIATES CAROTID BODY EXCITATION BY HYPOXIA". J Biol Chem. 282 (11): 8092–8. doi:10.1074/jbc.M608742200. PMC 1832262Freely accessible. PMID 17179156.
  7. Buckler KJ, Williams BA, Honore E (2000). "An oxygen-, acid- and anaesthetic-sensitive TASK-like background potassium channel in rat arterial chemoreceptor cells". J. Physiol. 525 (1): 135–142. doi:10.1111/j.1469-7793.2000.00135.x. PMC 2269923Freely accessible. PMID 10811732.
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