(Redirected from Chemoreception)A 'chemosensor', also known as 'chemoreceptor', is a
cell or group of cells that
transduce a chemical signal into an
action potential. Or, more generally, a chemosensor detects certain chemical stimuli in the environment.
Classes
There are two main classes of the chemosensor: direct and distance.
★ Examples of ''distance chemoreceptors'' are:
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olfactory receptor neurons in the
olfactory system
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★ neurons in the
vomeronasal organ that detect
pheromones
★ Examples of ''direct chemoreceptors'' include
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taste buds in the
gustatory system
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carotid bodies and
aortic bodies that detect changes in
pH inside the body.
Systems affected
Breathing rate
Chemoreceptors detect the levels of
carbon dioxide in the blood. To do this, they monitor the concentration of
hydrogen ions in the blood, which decreases the
pH of the blood, as a direct consequence of the raised carbon dioxide concentration.
The response is that the inspiratory centre (in the medulla), sends
nervous impulses to the external
intercostal muscles and the
diaphragm, via the
phrenic nerve to increase breathing rate and the volume of the lungs during inhalation.
Chemoreceptors which affect breathing rate are broken down into two categories.
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central chemoreceptors (in the
medulla) do not respond to a drop in oxygen, and eventually desensitize.
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peripheral chemoreceptors (
carotid arteries and
aorta) do respond to extreme drops in oxygen, and do not desensitize. Their effect on breathing rate is less than that of the central chemoreceptors.
Heart rate
Chemoreceptors in the
medulla oblongata,
carotid arteries and
aortic arch, detect the levels of
carbon dioxide in the blood, in the same way as applicable in the Breathing Rate section.
In response to this high concentration, a nervous impulse is sent to the
cardiovascular centre in the
medulla, which will then feedback to the
sympathetic ganglia, increasing nervous impulses here, and prompting the
sinoatrial node to stimulate more contractions of the myogenic cardiac muscle increase heart rate.
Sense organs
In
taste sensation, the tongue is composed of 5 different taste buds: salty, sour, sweet, bitter, and
savory . The salty and sour tastes work directly through the ion channels, the sweet and bitter taste work through
G protein-coupled receptors, and the savoury sensation is activated by
glutamate.
Noses in vertebrates and
antennae in many invertebrates act as distance chemoreceptors. Molecules diffused through the air and bind to specific receptors on ''olfactory sensory neurons'', activating an opening ion channel via G-proteins.
When inputs from the environment are significant to the survival of the organism the input must be detected. As all life processes are ultimately based on
chemistry it is natural that detection and passing on of the external input will involve chemical events. The chemistry of the environment is, of course, relevant to survival, and detection of chemical input from the outside may well articulate directly with cell chemicals.
For example: The emissions of a predator's food source, such as
odors or
pheromones, may be in the air or on a surface where the food source has been. Cells in the head, usually the air passages or mouth, have chemical receptors on their surface that change when in contact with the emissions. The change does not stop there. It passes in either chemical or electrochemical form to the central processor, the
brain or
spinal cord. The resulting output from the CNS (
central nervous system) makes body actions that will engage the food and enhance survival.
See also
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Sensory receptor
External links
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