Carotid body

Infobox Anatomy
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Latin = glomus caroticum
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Caption = Section of part of human glomus caroticum. Highly magnified. Numerous bloodvessels are seen in section among the gland cells.


Caption2 = Diagram showing the origins of the main branches of the carotid arteries.
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DorlandsPre = g_07
DorlandsSuf = 12394794
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.

Composition

The carotid body is made up of two types of cell: type I (glomus) cells, and type II (sustentacular) cells. Glomus cells are derived from neural crest,cite journal |author=Gonzalez C, Almaraz L, Obeso A, Rigual R |title=Carotid body chemoreceptors: from natural stimuli to sensory discharges |journal=Physiol. Rev. |volume=74 |issue=4 |pages=829–98 |year=1994 |pmid=7938227 |doi=] which, in turn are derived from neuroectoderm. They release a variety of neurotransmitters, including acetylcholine, ATP, and dopamine that trigger EPSPs in synapsed neurons leading to the respiratory center.

Type II cells resemble glia, express the glial marker S100 and act as supporting cells.

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 in an afferent nerve fiber, the carotid sinus nerve, which relays the information to the central nervous system.

timulus

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 100 mmHg (torr) (at normal physiological pH), but below this the activity of the type I (glomus) cells increases rapidly.

Detection

The mechanism for detecting reductions in PO₂ is not well understood. There may be a heme-containing protein in the glomus cell which responds to the loss of complexed oxygen by reducing the probability of potassium channels being open. Another possibility is that low PO₂ inhibits NADPH oxidase in mitochondria. This would increase the ratio of reduced glutathione to oxidised glutathione, which blocks potassium channels.

An increased PCO₂ is detected because the CO₂ diffuses into the cell, where it increase the concentration of carbonic acid and thus protons. These protons displace calcium from high-conductance calcium channels, reducing potassium current.

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.

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 effect 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 cell bodies of this nerve are located in the petrosal ganglion. The afferent fibres of the aortic body chemoreceptors are relayed by the vagus nerve. These centers, in turn, regulate breathing and blood pressure.

Disorders

A paraganglioma is a tumor that may involve the carotid body.

References

ee also

* Aortic body
* Peripheral chemoreceptors

External links

* [http://www.ursa.kcom.edu/Department/LectureNotes/Summer/ContRespiration.doc Respiratory physiology notes] at Kirksville College of Osteopathic Medicine
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