Unipolar neurons: characteristics and functions
Neurons are the basic unit of our nervous system. It is a type of cell through which information is transmitted both at the level of the nervous system as in relation to the rest of the body systems, to which said system controls.
But not all neurons are the same, but rather there are various types classified according to different criteria. One of these types are known as unipolar neurons., which this article deals with.
- Related article: "Types of neurons: characteristics and functions"
The basic unit of the nervous system
The neuron is a specialized cell that, as we have already said, is the basic unit of the nervous system. This type of cell allows the transmission of information of various types through bioelectric impulses, thanks to which our body can function.
The neuron consists of a nucleus located in the soma or perikaryon, in which a large part of the reactions and the synthesis of proteins that allow its functioning occur, in a axon or prolongation that starts from this and that allows the transport of the bioelectric signal to other neurons or organs and some
dendrites, structures in the form of branches that receive information from the previous neurons.There are neurons of different types. They can be classified in different ways, as for example according to the type of information they transmit, or by their morphology, and they can be found in different parts of the organism. Within the classification based on morphology, we can find multipolar, bipolar or unipolar neurons.
Unipolar and pseudounipolar neurons: morphological characteristics
Unipolar neurons are understood to be those neurons in which only a prolongation or extension arises from the soma. neurite, which will act as an axon and at the same time will have dendrites with which it can both receive and transmit information. This type of neurons is usually the main one in invertebrate animals., but also appear to a lesser extent in vertebrates.
As we have said, the unipolar neuron has only one neurite or extension that acts as an axon. However, this neurite usually divides into two branches. In this case we would be talking about pseudounipolar neurons., a variant of a unipolar neuron that has two ends that function as axons (which arise from the same process and not from the soma, so it would still be a unipolar neuron).
These branches derived from the neurite usually have a differentiated function: one will be dedicated to receiving information and the other to transmitting it. Specifically, the branch dedicated to reception tends to connect with peripheral elements, while the one that transmits information goes to the nervous system. At the end of the first, also called peripheral branch, you can find the dendrites. The second, the central branch, acts as an axon transmitting information. Such transmission has a peculiarity: the nerve impulse can jump from the dendrites to the axon without going through the soma.
Location in the nervous system
Unipolar and pseudounipolar neurons are types of neuron that are rare and infrequent in the human body, but we have them in different locations.
You can find each other forming part of the root of the spinal nerves and in the ganglia, specifically in the dorsal root, where they connect the nervous system with the peripheral organs. Thus, they are part of autonomic nervous system. In addition, neurons of this type have been found in the retina.
Function of unipolar neurons
Unipolar neurons, despite their relatively low presence compared to other types of neuron, have an important function in our body. we are before fibers that have the function of receiving information from peripheral organs and transmit it to the nervous system. That is, they are neurons afferents.
In this way, in human beings they usually have a relevant role in perception. They actively participate in the detection of tactile stimuli, both at the level of touch itself and the detection of pain. They are also linked to the sense of sight, being able to be found in the retina.
Bibliographic references:
- Cardinali, D.P. (2007). Applied neuroscience. Its fundamentals. Panamerican Medical Editorial. Buenos Aires.
- Gomez, M. (2012). Psychobiology. CEDE Preparation Manual PIR.12. CEDE: Madrid.
- Kandel, E.R.; Schwartz, J.H. & Jessell, T.M. (2001). Principles of neuroscience. Fourth edition. McGraw-Hill Interamericana. Madrid.