A chemoreceptor is a cellular sensor specialized in detecting and converting chemical signals - coming from both inside and outside the body - into biological signals that will be interpreted by the brain.
Chemoreceptors are responsible for our senses of smell and taste. These receptors take these chemical signals and transform them into a signal for the brain..
Similarly, crucial biological functions, such as the heartbeat and respiration, are controlled by chemoreceptors that detect molecules related to these processes, such as the amount of carbon dioxide, oxygen, and the pH of the blood..
The ability to perceive chemical signals is ubiquitous in the animal kingdom. Particularly in humans, chemoreceptors are not as sensitive as in other mammals. In the course of evolution, we have lost the ability to perceive chemical stimuli related to smell and taste.
Some simpler, non-metazoan organisms, such as bacteria and small protozoa, are capable of taking up chemical stimuli in their environment..
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A receptor is a molecule that is anchored to the plasma membrane of our cells. They have the ability to recognize other molecules with very high specificity. By recognizing the indicated molecule - called the ligand - a series of reactions is triggered that will carry a specific message to the brain.
We have the ability to perceive our environment, since our cells have a significant number of receptors. We can smell and taste food thanks to the chemoreceptors located in the sensory organs of the body.
Chemoreceptors are generally classified into four categories: general, internal, contact, and olfactory chemical receptors. The latter are also known as distance chemoreceptors. We will describe each type below:
These receptors do not have the ability to discriminate and are considered relatively insensitive. When stimulated, they produce a series of responses of the protective type for the body.
For example, if we stimulate the skin of an animal with an aggressive chemical that could damage it, the response would be an immediate flight from the place and prevent the negative stimulus from continuing..
As their name implies, they are responsible for responding to stimuli that occur inside the body..
For example, there are specific receptors to test the concentration of glucose in the blood, receptors inside the digestive system of animals and receptors located in the carotid body that respond to the concentration of oxygen in the blood..
Contact receptors respond to chemicals that are very close to the body. They are characterized by high thresholds and their ligands are molecules in solution..
According to the evidence, these seem to have been the first receptors to appear in evolutionary evolution, and they are the only chemoreceptors that the simplest animals present..
They are related to the feeding behavior of animals. For example, the best known with receptors associated with the sense of taste in vertebrates. They are located mainly in the oral area, since it is the region where food is received..
These receptors can discern between the apparent quality of the food, producing reactions of acceptance or rejection..
Smell receptors are the most sensitive to stimuli and can respond to substances that are at a certain distance.
In animals that live in air environments, the distinction between contact and distance receptors is easy to see. The chemicals that are transmitted through the air are those that manage to stimulate the olfactory receptors, while the chemicals dissolved in liquids stimulate the contact ones.
However, the boundary between both receptors seems to be diffuse, since there are substances that stimulate the receptors at a distance and must be dissolved in a liquid phase..
The limits look even more indefinite in animals that live in aquatic ecosystems. In these cases, all the chemicals will be dissolved in an aqueous medium. However, receptor differentiation is still useful, as these organisms respond differentially to near or far stimuli..
In most mammals there are three separate chemosensory systems, each dedicated to the detection of a particular group of chemicals..
The olfactory epithelium is made up of a dense layer of sensory neurons located in the nasal cavity. Here we find about a thousand different olfactory receptors that interact with the wide diversity of volatile substances present in the environment..
Non-volatile chemicals are perceived differently. The sense of perception of food consists of four or five taste qualities. These "qualities" are commonly called flavors, and include sweet, salty, sour, bitter, and umami. The latter is not very popular and is related to the taste of glutamate.
Sweet and umami flavors - corresponding to sugars and amino acids - are associated with nutritional aspects of food, while acidic flavors are associated with rejection behaviors, since most of the compounds with this flavor are toxic to mammals..
The cells responsible for perceiving these stimuli are found associated in the taste buds - in humans they are located on the tongue and at the back of the mouth. Taste buds contain 50 to 120 cells related to taste.
The vomeronasal organ is the third chemosensory system and is specialized in the detection of pheromones - however, not all pheromones are detected through this system..
The vomeronasal organ has qualities that are reminiscent of both the sense of taste and smell.
Anatomically, it is similar to smell, since it has the cells that express the receptors are neurons and they project directly to the brain. In contrast, the cells that possess the receptors of the tongue are not neurons..
However, the vomeronasal organ perceives non-volatile chemicals through direct contact, in the same way that we perceive the taste of food through the taste system..
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