Learning Objectives
Describe the characteristics of nervous tissue and how these enable the unique functions of nervous tissue.
By the end of this section, you will be able to:
- Identify the classes of cells that make up nervous tissue
- Describe the characteristics of nervous tissue
Nervous tissue is characterized as being excitable and capable of sending and receiving electrochemical signals that provide the body with information. Two main classes of cells make up nervous tissue: the neuron and neuroglia (Figure 4.5.1 The Neuron). Neurons propagate information via electrochemical impulses, called action potentials, which are biochemically linked to the release of chemical signals. Neuroglia play an essential role in supporting neurons.
External Website
Follow this link to learn more about nervous tissue. What are the main parts of a nerve cell?
Neurons display distinctive morphology, well suited to their role as conducting cells, with three main parts. The cell body includes most of the cytoplasm, organelles, and nucleus. Dendrites, which receive input from other neurons, branch off the cell body and appear as thin extensions. A long axon extends from the cell body and may be wrapped in an insulating layer known as myelin, which is formed by accessory cells. Axons transmit electrical signals traveling away from the cell body. The synapse is the gap between nerve cells, or between a nerve cell and its target. The signal is transmitted across the synapse by chemical compounds known as neurotransmitters. Neurons categorized as multipolar neurons have several dendrites and a single prominent axon. Bipolar neurons possess a single dendrite and axon with the cell body, while unipolar neurons have only a single process extending out from the cell body, which divides into a functional dendrite and into a functional axon. When a neuron is sufficiently stimulated, it generates an action potential that propagates down the axon towards the synapse. If enough neurotransmitters are released at the synapse to stimulate the next neuron (or muscle, or gland), a response is generated.
The second class of neural cells are the neuroglia or glial cells, which have been characterized as having a simple support role. The word “glia” comes from the Greek word for glue. Recent research is shedding light on the more complex role of neuroglia in the function of the brain and nervous system. Astrocyte cells, named for their distinctive star shape, are abundant in the central nervous system. The astrocytes have many functions, including regulation of ion concentration in the intercellular space, uptake and/or breakdown of some neurotransmitters, and formation of the blood-brain barrier, the membrane that separates the circulatory system from the brain. Microglia protect the nervous system against infection and are related to macrophages. Oligodendrocyte cells produce myelin in the central nervous system (brain and spinal cord) while the Schwann cell produces myelin in the peripheral nervous system (Figure 4.5.2 Nervous Tissue).
Chapter Review
The most prominent cell of the nervous tissue, the neuron, is characterized mainly by its ability to receive stimuli and respond by generating an electrical signal, known as an action potential, which can travel rapidly over great distances in the body. A typical neuron displays a distinctive morphology: a large cell body branches out into short extensions called dendrites, which receive chemical signals from other neurons, and a long tail called an axon, which relays signals away from the cell to other neurons, muscles, or glands. Many axons are wrapped by a myelin sheath, a lipid derivative that acts as an insulator and facilitates the transmission of the action potential. Other cells in the nervous tissue, the neuroglia, include the astrocytes, microglia, oligodendrocytes, and Schwann cells.
Interactive Link Questions
Follow this link to learn more about nervous tissue. What are the main parts of a nerve cell?
Dendrites, cell body, and the axon.
Review Questions
Critical Thinking Questions
Which morphological adaptations of neurons make them suitable for the transmission of nerve impulse?
Neurons are well suited for the transmission of nerve impulses because short extensions, dendrites, receive impulses from other neurons, while a long tail extension, an axon, carries electrical impulses away from the cell to other neurons.
What are the functions of astrocytes?
Astrocytes regulate ions and uptake and/or breakdown of some neurotransmitters and contribute to the formation of the blood-brain-barrier.
References
Stern, P. Focus issue: getting excited about glia. Science [Internet]. 2010 [cited 2012 Dec 4]; 3(147):330-773. Available from:
http://stke.sciencemag.org/cgi/content/abstract/sigtrans;3/147/eg11
Ming GL, Song H. Adult neurogenesis in the mammalian central nervous system. Annu. Rev. Neurosci. 2005 [cited 2012 Dec 4]; 28:223–250.
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