Chapter 2: Neurons

2.3: Types of Cells in the Brain

Not all neurons are created equal. Sensory neurons help us receive information about the world around us. Motor neurons allow us to initiate movement and behavior, ultimately allowing us to interact with the world around us. Interneurons process sensory input from our environment into meaningful representations, plan behavioral responses, and connect to the motor neurons to execute these behavioral plans.

The main categories of neurons are defined by their specific structure. The structures support their unique functions. Unipolar neurons are structured in a way that is ideal for relaying information forward, so they have one neurite (axon) and no dendrites (Figure 2.4). They are involved in transmission of physiological information from the body’s periphery such as communicating body temperature through the spinal cord up to the brain. Bipolar neurons are involved in sensory perception such as perception of light in the retina of the eye. They have one axon and one dendrite which help acquire and pass sensory information to various centers in the brain. Finally, multipolar neurons  are the most common and they communicate sensory and motor information in the brain. Multipolar neurons have one axon and many dendrites which allows them to communicate with other neurons. One of the most prominent neurons is a pyramidal neuron, which falls under the multipolar category. It gets its name from the triangular or pyramidal shape of its soma (for examples see, Furtak et al., 2007).

 

Illustrations of the Types of Neurons: (1) unipolar, (2) bipolar, (3) multipolar, and (4) pseudounipolar.
Figure 2.4. Types of Neurons: Neurons are broadly divided into a few main types based on the number and placement of axons: (1) unipolar, (2) bipolar, (3) multipolar, and (4) pseudounipolar. CREDIT: types of neurons © Libre Texts Biology is licensed under a CC BY-SA (Attribution ShareAlike) license

In addition to neurons, non-neuronal cells in the nervous system called glia or neuroglia provide support and play essential roles in the functioning of neurons. Glial cells have several functions, just a few of which we will discuss here. One type of glial cell, called oligodendroglia, forms the myelin sheaths that insulate axons (Simons & Trotter, 2007; see Figures 2.5). In the central nervous system (CNS), oligodendroglia wrap their dendritic processes around the axons of neurons many times to form the myelin sheath. One cell will form the myelin sheath on several axons. In the peripheral nervous system (PNS), Schwann cells, another type of glial cell, form the myelin sheath for neurons. One cell will wrap around a singular axon in the PNS. Other types of glial cells, such as microglia and astrocytes, digest debris of dead neurons, carry nutritional support from blood vessels to the neurons, and help to regulate the ionic composition of the extracellular fluid. While glial cells play a vital role in neuronal support, they do not carry electrical signals or participate in the communication between cells as neurons do.

 

Drawing of the Oligodendrocyte
Figure 2.5. An oligodendrocyte myelinating several axons in the central nervous system. CREDIT: Oligodendrocyte © Wikimedia is licensed under a CC BY-SA (Attribution ShareAlike) license

 

 

Drawing of the peripheral nervous system (PNS) has myelinating Schwann cells
Figure 2.6. The peripheral nervous system (PNS) has myelinating Schwann cells. CREDIT: Glial Cells of the PNS © Wikimedia is licensed under a CC BY-SA (Attribution ShareAlike) license
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