Neurons are the cells that make up nervous tissue. They are responsible for the chemical and electrical signals that communicate information about sensations, that produce movements, and induce thought processes within the brain. Learn more about neurons and how they work.
Neurons
Image by TheVisualMD
Neurons
The Brain's Couriers
Image by TheVisualMD
The Brain's Couriers
How Do Nerve Cells Work? Nerve cells talk to each other via a complex system of electrical impulses and chemical signals. They are supported by another type of cell, called glia. Their work is so important that glia outnumber nerve cells in the brain and spinal cord. Types of Nerve Cells (Neurons) Nerve cells fall into one of three types. Sensory neurons are responsible for relaying information from the senses—eyes, ears, nose, tongue and skin—to the brain to register sight, sound, smell, taste and touch. Motor neurons link the brain and spinal cord to the various muscles throughout the body, including those in our fingers and toes. Interneurons are intermediaries that bridge sensory or motor neurons to their neighbors. Anatomy of a Nerve Cell (Neuron) Soma Also known as the cell body, the soma is the anatomical hub of the nerve cell and contains its DNA. The cell body collects incoming information and transmits it as electrical impulses along the nerve cell’s axon. Axon This fiber is the workhorse of the nerve cell. Like a fiber-optic cable loaded with information, axons carry out-going messages from brain nerve cells to other parts of the body. They can measure over a foot in length. Dendrites While each nerve cell has only one axon, it may have multiple dendrites, which resemble the branches of a tree. Dendrites collect incoming information for nerve cells from the environment, such as smells or sounds. Dendritic Spine Just as a tree’s health depends on the strength and robustness of its branches, the major limbs of a nerve cell’s dendrites, or spines, may determine how well it functions in relaying incoming information to the soma. Synapse When nerve cells communicate with each other, they don’t physically come into contact. Instead, they send chemicals across a small space known as a synapse, and special structures located at the ends of axons are designed to release and absorb these agents and translate them into the electrical signals that continue on their way along the nerve cell highway.
Image by TheVisualMD
Neurons
Neurons
Neurons are the cells considered to be the basis of nervous tissue. They are responsible for the electrical signals that communicate information about sensations, and that produce movements in response to those stimuli, along with inducing thought processes within the brain. An important part of the function of neurons is in their structure, or shape. The three-dimensional shape of these cells makes the immense numbers of connections within the nervous system possible.
Parts of a Neuron
The main part of a neuron is the cell body, which is also known as the soma (soma = “body”). The cell body contains the nucleus and most of the major organelles. But what makes neurons special is that they have many extensions of their cell membranes, which are generally referred to as processes. Neurons are usually described as having one, and only one, axon—a fiber that emerges from the cell body and projects to target cells. That single axon can branch repeatedly to communicate with many target cells. It is the axon that propagates the nerve impulse, which is communicated to one or more cells. The other processes of the neuron are dendrites, which receive information from other neurons at specialized areas of contact called synapses. The dendrites are usually highly branched processes, providing locations for other neurons to communicate with the cell body. Information flows through a neuron from the dendrites, across the cell body, and down the axon. This gives the neuron a polarity—meaning that information flows in this one direction. The image below shows the relationship of these parts to one another.
Where the axon emerges from the cell body, there is a special region referred to as the axon hillock. This is a tapering of the cell body toward the axon fiber. Within the axon hillock, the cytoplasm changes to a solution of limited components called axoplasm. Because the axon hillock represents the beginning of the axon, it is also referred to as the initial segment.
Many axons are wrapped by an insulating substance called myelin, which is actually made from glial cells. Myelin acts as insulation much like the plastic or rubber that is used to insulate electrical wires. A key difference between myelin and the insulation on a wire is that there are gaps in the myelin covering of an axon. Each gap is called a node of Ranvier and is important to the way that electrical signals travel down the axon. The length of the axon between each gap, which is wrapped in myelin, is referred to as an axon segment. At the end of the axon is the axon terminal, where there are usually several branches extending toward the target cell, each of which ends in an enlargement called a synaptic end bulb. These bulbs are what make the connection with the target cell at the synapse.
Types of Neurons
There are many neurons in the nervous system—a number in the trillions. And there are many different types of neurons. They can be classified by many different criteria. The first way to classify them is by the number of processes attached to the cell body. Using the standard model of neurons, one of these processes is the axon, and the rest are dendrites. Because information flows through the neuron from dendrites or cell bodies toward the axon, these names are based on the neuron's polarity (image below).
Unipolar cells have only one process emerging from the cell. True unipolar cells are only found in invertebrate animals, so the unipolar cells in humans are more appropriately called “pseudo-unipolar” cells. Invertebrate unipolar cells do not have dendrites. Human unipolar cells have an axon that emerges from the cell body, but it splits so that the axon can extend along a very long distance. At one end of the axon are dendrites, and at the other end, the axon forms synaptic connections with a target. Unipolar cells are exclusively sensory neurons and have two unique characteristics. First, their dendrites are receiving sensory information, sometimes directly from the stimulus itself. Secondly, the cell bodies of unipolar neurons are always found in ganglia. Sensory reception is a peripheral function (those dendrites are in the periphery, perhaps in the skin) so the cell body is in the periphery, though closer to the CNS in a ganglion. The axon projects from the dendrite endings, past the cell body in a ganglion, and into the central nervous system.
Bipolar cells have two processes, which extend from each end of the cell body, opposite to each other. One is the axon and one the dendrite. Bipolar cells are not very common. They are found mainly in the olfactory epithelium (where smell stimuli are sensed), and as part of the retina.
Multipolar neurons are all of the neurons that are not unipolar or bipolar. They have one axon and two or more dendrites (usually many more). With the exception of the unipolar sensory ganglion cells, and the two specific bipolar cells mentioned above, all other neurons are multipolar. Some cutting edge research suggests that certain neurons in the CNS do not conform to the standard model of “one, and only one” axon. Some sources describe a fourth type of neuron, called an anaxonic neuron. The name suggests that it has no axon (an- = “without”), but this is not accurate. Anaxonic neurons are very small, and if you look through a microscope at the standard resolution used in histology (approximately 400X to 1000X total magnification), you will not be able to distinguish any process specifically as an axon or a dendrite. Any of those processes can function as an axon depending on the conditions at any given time. Nevertheless, even if they cannot be easily seen, and one specific process is definitively the axon, these neurons have multiple processes and are therefore multipolar.
Neurons can also be classified on the basis of where they are found, who found them, what they do, or even what chemicals they use to communicate with each other. Some neurons referred to in this section on the nervous system are named on the basis of those sorts of classifications (image below). For example, a multipolar neuron that has a very important role to play in a part of the brain called the cerebellum is known as a Purkinje (commonly pronounced per-KIN-gee) cell. It is named after the anatomist who discovered it (Jan Evangilista Purkinje, 1787–1869).
Source: CNX OpenStax
Additional Materials (44)
Neurons
Neurons
Image by TheVisualMD
Neurons or nerve cells - Structure function and types of neurons | Human Anatomy | 3D Biology
Video by Elearnin/YouTube
Human Neurons Continue to Migrate After Birth
Video by UC San Francisco (UCSF)/YouTube
Regenerating Neurons | Science: Out of the Box
Video by Johns Hopkins Medicine/YouTube
Types of Neurons by Structure - Neuroanatomy Basics - Anatomy Tutorial
Video by AnatomyZone/YouTube
Neurons and Glial Cells
Glial cells support neurons and maintain their environment. Glial cells of the (a) central nervous system include oligodendrocytes, astrocytes, ependymal cells, and microglial cells. Oligodendrocytes form the myelin sheath around axons. Astrocytes provide nutrients to neurons, maintain their extracellular environment, and provide structural support. Microglia scavenge pathogens and dead cells. Ependymal cells produce cerebrospinal fluid that cushions the neurons. Glial cells of the (b) peripheral nervous system include Schwann cells, which form the myelin sheath, and satellite cells, which provide nutrients and structural support to neurons.
Image by CNX Openstax
Neurons, Brain Cells
Image by geralt/Pixabay
Myelinated neurons are faster than unmyelinated neurons because of Saltatory motion.
Myelinated neurons are faster than unmyelinated neurons because of Saltatory motion.
Image by Dr. Jana
Neurons and Glia
This image shows neurons (blue) and different types of glia (red and green) from the hippocampus of a rat.
Image by NICHD/J. Cohen
Neurons and Covid
Neurons and Covid
Image by TheVisualMD/CDC
Brain Neuron
Medical visualization of a cluster of neurons in the brain. The brain chiefly consists of neurons - a major type of cell in the nervous system. Neurons vary widely in appearance, but all are comprised of cell bodies, dendrites, and axons. Because they have excitable membranes, neurons are able to generate and propagate electrical impulses, which allow them to process and transmit information. Therefore, they are responsible for communication between the different regions of the brain and body. Neurons in the brain also conduct such tasks as converting testosterone to estrogen.
Image by TheVisualMD
Neurons and Neurotransmitters
Image by National Institute on Aging/National Institutes of Health
Synapse of neurons
Synapse of neurons
Image by TheVisualMD
Different kinds of neurons
Different kinds of neurons:1 Unipolar neuron2 Bipolar neuron3 Multipolar neuron4 Pseudounipolar neuron
Image by Jonathan Haas
Neurons and Glia
Beta lobe neurons - Two pairs of beta lobe neurons (one blue, one orange) in the brain of a locust. These neurons process olfactory information. Toward the top are mushroom bodies, brain areas associated with learning and memory.
Image by NICHD
Neurons
neurons and glia cells
Image by OpenStax College
Neurons from Hippocampus
This image shows a group of pyramidal neurons from the CA1 region of the hippocampus, with individual neurons receiving impulses across synapses from below. Creating memories is one of the brain's most remarkable functions. By relying on an intricate network of connected nerves in different parts of the brain, we can record an experience, store it like a biological file stuffed with emotions and sensory legacies and then recall it at will. The hippocampus serves as the hub for making and storing memories.
Image by TheVisualMD
Neurons in Hippocampus
This image shows a group of pyramidal neurons from the CA1 region of the hippocampus, with individual neurons receiving impulses across synapses from below. Creating memories is one of the brain's most remarkable functions. By relying on an intricate network of connected nerves in different parts of the brain, we can record an experience, store it like a biological file stuffed with emotions and sensory legacies and then recall it at will. The hippocampus serves as the hub for making and storing memories.
Image by TheVisualMD
Circadian rhythm neurons in the fruit fly brain
Some nerve cells (neurons) in the brain keep track of the daily cycle. This time-keeping mechanism, called the circadian clock, is found in all animals including us. The circadian clock controls our daily activities such as sleep and wakefulness. Researchers are interested in finding the neuron circuits involved in this time keeping and how the information about daily time in the brain is relayed to the rest of the body. In this image of a brain of the fruit fly Drosophila, the time-of-day information flowing through the brain has been visualized by staining the neurons involved: clock neurons (shown in blue) function as "pacemakers" by communicating with neurons that produce a short protein called leucokinin (LK) (red), which, in turn, relays the time signal to other neurons, called LK-R neurons (green). This signaling cascade set in motion by the pacemaker neurons helps synchronize the fly's daily activity with the 24-hour cycle.
To learn more about what scientist have found out about circadian pacemaker neurons in the fruit fly see this news release by New York University. A study describing the discovery of the neuron circuits involved has been published in the journal Nature Neuroscience
This work was featured in the Biomedical Beat blog post Cool Image: A Circadian Circuit.
Image by NIGMS/Matthieu Cavey and Justin Blau, New York University
Neurons
Image by OpenStax College
Neurons from human ES cells 02
These neurons were derived from human embryonic stem cells. The neural cell bodies with axonal projections are visible in red, and the nuclei in blue. Some of the neurons have become dopaminergic neurons (yellow), the type that degenerate in people with Parkinson's disease.
Image and caption information courtesy of the California Institute for Regenerative Medicine.
Image by Xianmin Zeng lab, Buck Institute for Age Research, via CIRM
Glial Cells of the CNS
The CNS has astrocytes, oligodendrocytes, microglia, and ependymal cells that support the neurons of the CNS in several ways.
Image by CNX Openstax
Neurons and Glial Cells
Nervous systems vary in structure and complexity. In (a) cnidarians, nerve cells form a decentralized nerve net. In (b) echinoderms, nerve cells are bundled into fibers called nerves. In animals exhibiting bilateral symmetry such as (c) planarians, neurons cluster into an anterior brain that processes information. In addition to a brain, (d) arthropods have clusters of nerve cell bodies, called peripheral ganglia, located along the ventral nerve cord. Mollusks such as squid and (e) octopi, which must hunt to survive, have complex brains containing millions of neurons. In (f) vertebrates, the brain and spinal cord comprise the central nervous system, while neurons extending into the rest of the body comprise the peripheral nervous system. (credit e: modification of work by Michael Vecchione, Clyde F.E. Roper, and Michael J. Sweeney, NOAA; credit f: modification of work by NIH)
Image by CNX Openstax
Neurons
Montage of an image of neurons, captured using a confocal microscop. Neurons and nuclei shown.
Image by Enricobagnoli
ALS Disease Pathology and Proposed Disease Mechanisms
This figure is from the journal article "Modelling amyotrophic lateral sclerosis: progress and possibilities" and shows ten proposed disease mechanisms for ALS.
Fig. 1. ALS disease pathology and proposed disease mechanisms. At the level of cell pathology, ALS is characterized by axonal retraction and cell body loss of upper and lower motor neurons, surrounded by astrogliosis and microgliosis (see Box 2), with ubiquitin- and p62-positive inclusions in surviving neurons. Proposed disease mechanisms contributing to motor neuron degeneration are:
Alterations in nucleocytoplasmic transport of RNA molecules and RNA-binding proteins.
Altered RNA metabolism: several important RNA-binding proteins become mislocalized in ALS, with cytosolic accumulation and nuclear depletion. The nuclear depletion causes defects in transcription and splicing. Some RNA-binding proteins can undergo liquid- liquid phase separation and can be recruited to stress granules (TDP-43, FUS, ATXN2, hnRNPA1/A2). Altered dynamics of stress granule formation or disassembly can propagate cytoplasmic aggregate formation.
Impaired proteostasis with accumulation of aggregating proteins (TDP-43, FUS, SOD1, DPRs). Overload of the proteasome system and reduced autophagy may contribute and/or cause this accumulation.
Impaired DNA repair: two recently identified ALS genes (see main text for details) work together in DNA repair, suggesting that impaired DNA repair could also contribute to ALS pathogenesis.
Mitochondrial dysfunction and oxidative stress: several ALS- related proteins (SOD1, TDP-43, C9orf72) can enter mitochondria and disrupt normal functioning, with increased formation of reactive oxygen species (ROS) as a consequence.
Oligodendrocyte dysfunction and degeneration, leading to reduced support for motor neurons.
Neuroinflammation: activated astrocytes and microglia secrete fewer neuroprotective factors and more toxic factors.
Defective axonal transport: several ALS-related mutations cause disorganization of the cytoskeletal proteins and disrupt axonal transport.
Defective vesicular transport: several ALS-related proteins (VABP, ALS2, CHMP2B, UNC13A) are involved in vesicular transport, suggesting that impaired vesicular transport contributes to ALS pathogenesis.
Excitotoxicity: loss of the astroglial glutamate transporter EAAT2 causes accumulation of extracellular glutamate, which causes excessive stimulation of glutamate receptors (e.g. AMPA receptors) and excessive calcium influx.
Image by Philip Van Damme, Wim Robberecht, and Ludo Van Den Bosch/Wikimedia
Neurons from Hippocampus
This image shows a group of pyramidal neurons from the CA1 region of the hippocampus, with individual neurons receiving impulses across synapses from below. Creating memories is one of the brain's most remarkable functions. By relying on an intricate network of connected nerves in different parts of the brain, we can record an experience, store it like a biological file stuffed with emotions and sensory legacies and then recall it at will. The hippocampus serves as the hub for making and storing memories.
Hand drawing of the main types of neurons, illustrating the four regions of each neuron: Input (red), Integrative (yellow), Conductive (blue) and Output (green)
Image by Miguel Iglesias
Action potential
As a nerve impulse travels down the axon, there is a change in polarity across the membrane. The Na+ and K+ gated ion channels open and close in response to a signal from another neuron. At the beginning of action potential, the Na+ gates open and Na+ moves into the axon. This is depolarization. Repolarization occurs when the K+ gates open and K+ moves outside the axon. This creates a change in polarity between the outside of the cell and the inside. The impulse continuously travels down the axon in one direction only, through the axon terminal and to other neurons.
Image by Laurentaylorj
Pyramidal neurons
GFP expressing pyramydal cell in mouse cortex.
Image by Original uploader was Nrets at en.wikipedia
Motor Neuron
Extensor digitorum reflex is basically an example of monosynaptic as same as biceps reflex and brachioradialis reflex. Extensor digitoium reflex arc involves-receptor (muscle spindle in extensor digitoium), afferent (Iα fiber), center (Spinal cord C6, C7), efferent (alpha motor neurons), effector organ (skeletal muscle---extensor digitoium), while dynamic stretch reflexes of biceps reflex and brachioradialis reflex involving the spinal segment C5,C6.
Image by Zhang MJ, Zhu CZ, Duan ZM, Niu X. Department of Cardiology, Second Affiliated Hospital, School of Medicine, Xian Jiao Tong University, China. zhangmingjuan@mail.xjtu.edu.cn
Nerve Cell, Neuron, Brain, Neurons
Image by ColiN00B/Pixabay
Golgi stained neurons in the dentate gyrus of an epilepsy patient
Golgi stained neurons in the dentate gyrus of an epilepsy patient. 40 times magnification.
Image by MethoxyRoxy
Neuron Development
Each neuron begins life as a progenitor cell. These cells form in the central part of the developing brain and then move outward along the supportive glial cells until they reach their pre-programmed location in the brain. As a progenitor cell reaches its destination, its status changes and it now is \"committed\" to become one of numerous types of neurons. The neuron begins to grow axons and dendrites. These fibers will eventually form a synapse, or connection, with those of other neurons. Once the neuron has taken on its specialized function, it is considered \"differentiated.\"
Image by TheVisualMD
Nerve Support Cell Astrocyte
Along with neurons, the brain also contains glial cells, which support neurons from their progenitor state through their lifetime. With quantities greater than ten times the number neurons in the brain, glial cells make up the brain's neural support system, providing nutrients, holding neurons in place and insulating them, digesting dead cells, creating guidance paths taken by migrating neurons in the embryo, and performing other functions necessary to maintain the brain's structural and functional integrity.
Image by TheVisualMD
Nerve Support Cell Ependymal
Along with neurons, the brain also contains glial cells, which support neurons from their progenitor state through their lifetime. With quantities greater than ten times the number neurons in the brain, glial cells make up the brain's neural support system, providing nutrients, holding neurons in place and insulating them, digesting dead cells, creating guidance paths taken by migrating neurons in the embryo, and performing other functions necessary to maintain the brain's structural and functional integrity.
Image by TheVisualMD
Nerve Support Cell Mircoglial
Along with neurons, the brain also contains glial cells, which support neurons from their progenitor state through their lifetime. With quantities greater than ten times the number neurons in the brain, glial cells make up the brain's neural support system, providing nutrients, holding neurons in place and insulating them, digesting dead cells, creating guidance paths taken by migrating neurons in the embryo, and performing other functions necessary to maintain the brain's structural and functional integrity.
Image by TheVisualMD
Nerve Support Cell Oligodendrocite
Along with neurons, the brain also contains glial cells, which support neurons from their progenitor state through their lifetime. With quantities greater than ten times the number neurons in the brain, glial cells make up the brain's neural support system, providing nutrients, holding neurons in place and insulating them, digesting dead cells, creating guidance paths taken by migrating neurons in the embryo, and performing other functions necessary to maintain the brain's structural and functional integrity.
Image by TheVisualMD
Nerve Support Cell Schwann
Along with neurons, the brain also contains glial cells, which support neurons from their progenitor state through their lifetime. With quantities greater than ten times the number neurons in the brain, glial cells make up the brain's neural support system, providing nutrients, holding neurons in place and insulating them, digesting dead cells, creating guidance paths taken by migrating neurons in the embryo, and performing other functions necessary to maintain the brain's structural and functional integrity.
Image by TheVisualMD
Communication Between Neurons
Video by DeBacco University/YouTube
Upper motor neurons | Organ Systems | MCAT | Khan Academy
Video by khanacademymedicine/YouTube
Motor neurons | Muscular-skeletal system physiology | NCLEX-RN | Khan Academy
Video by khanacademymedicine/YouTube
Neurology - Neuron
Video by Armando Hasudungan/YouTube
Neurons
TheVisualMD
4:09
Neurons or nerve cells - Structure function and types of neurons | Human Anatomy | 3D Biology
Elearnin/YouTube
1:06
Human Neurons Continue to Migrate After Birth
UC San Francisco (UCSF)/YouTube
7:11
Regenerating Neurons | Science: Out of the Box
Johns Hopkins Medicine/YouTube
5:06
Types of Neurons by Structure - Neuroanatomy Basics - Anatomy Tutorial
AnatomyZone/YouTube
Neurons and Glial Cells
CNX Openstax
Neurons, Brain Cells
geralt/Pixabay
Myelinated neurons are faster than unmyelinated neurons because of Saltatory motion.
Dr. Jana
Neurons and Glia
NICHD/J. Cohen
Neurons and Covid
TheVisualMD/CDC
Brain Neuron
TheVisualMD
Neurons and Neurotransmitters
National Institute on Aging/National Institutes of Health
Synapse of neurons
TheVisualMD
Different kinds of neurons
Jonathan Haas
Neurons and Glia
NICHD
Neurons
OpenStax College
Neurons from Hippocampus
TheVisualMD
Neurons in Hippocampus
TheVisualMD
Circadian rhythm neurons in the fruit fly brain
NIGMS/Matthieu Cavey and Justin Blau, New York University
Neurons
OpenStax College
Neurons from human ES cells 02
Xianmin Zeng lab, Buck Institute for Age Research, via CIRM
Glial Cells of the CNS
CNX Openstax
Neurons and Glial Cells
CNX Openstax
Neurons
Enricobagnoli
ALS Disease Pathology and Proposed Disease Mechanisms
Philip Van Damme, Wim Robberecht, and Ludo Van Den Bosch/Wikimedia
Neurons from Hippocampus
TheVisualMD
Pyramidal neurons
UC Regents Davis campus
Neuroanatomy
Aceofhearts1968
Neuron Classification
Miguel Iglesias
Action potential
Laurentaylorj
Pyramidal neurons
Original uploader was Nrets at en.wikipedia
Motor Neuron
Zhang MJ, Zhu CZ, Duan ZM, Niu X. Department of Cardiology, Second Affiliated Hospital, School of Medicine, Xian Jiao Tong University, China. zhangmingjuan@mail.xjtu.edu.cn
Nerve Cell, Neuron, Brain, Neurons
ColiN00B/Pixabay
Golgi stained neurons in the dentate gyrus of an epilepsy patient
MethoxyRoxy
Neuron Development
TheVisualMD
Nerve Support Cell Astrocyte
TheVisualMD
Nerve Support Cell Ependymal
TheVisualMD
Nerve Support Cell Mircoglial
TheVisualMD
Nerve Support Cell Oligodendrocite
TheVisualMD
Nerve Support Cell Schwann
TheVisualMD
4:45
Communication Between Neurons
DeBacco University/YouTube
13:41
Upper motor neurons | Organ Systems | MCAT | Khan Academy
khanacademymedicine/YouTube
7:19
Motor neurons | Muscular-skeletal system physiology | NCLEX-RN | Khan Academy
khanacademymedicine/YouTube
11:21
Neurology - Neuron
Armando Hasudungan/YouTube
Nervous Tissue
Action Potential of Neuron
Image by TheVisualMD
Action Potential of Neuron
Neurons consist of three elements: the cell body, axons, and dendrites. A signal is transmitted from neuron to neuron by an electrical force known as the action potential. The size of the signal is always the same; what varies is whether it's switched \"on\" or \"off.\" When a cell body receives enough stimulation--for example, when you touch a very hot teapot--voltage-gated ion channels open on its surface to let charged particles (ions) into, and then out of, the cell. The flow of these particles causes the cell to generate an electrical discharge that is transmitted down the length of the axon to its end, or terminal.
Image by TheVisualMD
Nervous Tissue Mediates Perception and Response
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 (image below). 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 and modulating their information propagation.
Neurons display distinctive morphology, well suited to their role as conducting cells, with three main parts. The cell body includes most of the cytoplasm, the organelles, and the nucleus. Dendrites branch off the cell body and appear as thin extensions. A long “tail,” the axon, extends from the neuron body and can be wrapped in an insulating layer known as myelin , which is formed by accessory cells. The synapse is the gap between nerve cells, or between a nerve cell and its target, for example, a muscle or a gland, across which the impulse is transmitted 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 target, a response is generated.
The second class of neural cells comprises 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 but are not nervous tissue because they 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 (image below).
Overview
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 speeds up the transmission of the action potential. Other cells in the nervous tissue, the neuroglia, include the astrocytes, microglia, oligodendrocytes, and Schwann cells.
Source: CNX OpenStax
Additional Materials (8)
Sensation and Perception: Crash Course Psychology #5
Video by CrashCourse/YouTube
Neuron action potential description | Nervous system physiology | NCLEX-RN | Khan Academy
Video by khanacademymedicine/YouTube
The Nervous System - CrashCourse Biology #26
Video by CrashCourse/YouTube
The Nervous System, Part 2 - Action! Potential!: Crash Course A&P #9
Video by CrashCourse/YouTube
Neuromuscular Junction
Video by MUSOMGraphicDesign/YouTube
Neuroscience Basics: GABA and Glutamate, Animation
Video by Alila Medical Media/YouTube
Neuroscience Basics: GABA Receptors and GABA Drugs, Animation
An illustration shows the range of motion of a forward kick, with the subject bones and musculature visible from the mid-torso to the feet. The image supports content emphasizing the importance of strength, balance and range of motion in the joints.
Image by TheVisualMD
Motor Units
Every skeletal muscle fiber must be innervated by the axon terminal of a motor neuron in order to contract. Each muscle fiber is innervated by only one motor neuron. The actual group of muscle fibers in a muscle innervated by a single motor neuron is called a motor unit. The size of a motor unit is variable depending on the nature of the muscle.
A small motor unit is an arrangement where a single motor neuron supplies a small number of muscle fibers in a muscle. Small motor units permit very fine motor control of the muscle. The best example in humans is the small motor units of the extraocular eye muscles that move the eyeballs. There are thousands of muscle fibers in each muscle, but every six or so fibers are supplied by a single motor neuron, as the axons branch to form synaptic connections at their individual NMJs. This allows for exquisite control of eye movements so that both eyes can quickly focus on the same object. Small motor units are also involved in the many fine movements of the fingers and thumb of the hand for grasping, texting, etc.
A large motor unit is an arrangement where a single motor neuron supplies a large number of muscle fibers in a muscle. Large motor units are concerned with simple, or "gross," movements, such as powerfully extending the knee joint. The best example is the large motor units of the thigh muscles or back muscles, where a single motor neuron will supply thousands of muscle fibers in a muscle, as its axon splits into thousands of branches.
There is a wide range of motor units within many skeletal muscles, which gives the nervous system a wide range of control over the muscle. The small motor units in the muscle will have smaller, lower-threshold motor neurons that are more excitable, firing first to their skeletal muscle fibers, which also tend to be the smallest. Activation of these smaller motor units, results in a relatively small degree of contractile strength (tension) generated in the muscle. As more strength is needed, larger motor units, with bigger, higher-threshold motor neurons are enlisted to activate larger muscle fibers. This increasing activation of motor units produces an increase in muscle contraction known as recruitment. As more motor units are recruited, the muscle contraction grows progressively stronger. In some muscles, the largest motor units may generate a contractile force of 50 times more than the smallest motor units in the muscle. This allows a feather to be picked up using the biceps brachii arm muscle with minimal force, and a heavy weight to be lifted by the same muscle by recruiting the largest motor units.
When necessary, the maximal number of motor units in a muscle can be recruited simultaneously, producing the maximum force of contraction for that muscle, but this cannot last for very long because of the energy requirements to sustain the contraction. To prevent complete muscle fatigue, motor units are generally not all simultaneously active, but instead some motor units rest while others are active, which allows for longer muscle contractions. The nervous system uses recruitment as a mechanism to efficiently utilize a skeletal muscle.
Motor Units
A series of axon-like swelling, called varicosities or "boutons," from autonomic neurons form motor units through the smooth muscle.
Source: CNX OpenStax
Additional Materials (9)
Neuromuscular Junction
Image by TheVisualMD
Location of lower motor neurons in spinal cord
Location of lower motor neurons in spinal cord
Image by Cervical vertebra blank.svg: Fred the Oyster Polio spinal diagram.PNG: DO11.10 Derived: Angelito7
Motor Neuron
Extensor digitorum reflex is basically an example of monosynaptic as same as biceps reflex and brachioradialis reflex. Extensor digitoium reflex arc involves-receptor (muscle spindle in extensor digitoium), afferent (Iα fiber), center (Spinal cord C6, C7), efferent (alpha motor neurons), effector organ (skeletal muscle---extensor digitoium), while dynamic stretch reflexes of biceps reflex and brachioradialis reflex involving the spinal segment C5,C6.
Image by Zhang MJ, Zhu CZ, Duan ZM, Niu X. Department of Cardiology, Second Affiliated Hospital, School of Medicine, Xian Jiao Tong University, China. zhangmingjuan@mail.xjtu.edu.cn
myelinated vertebrate motor neuron
Diagram of a typical myelinated vertebrate motor neuron
Image by LadyofHats
Motor neurons | Muscular-skeletal system physiology | NCLEX-RN | Khan Academy
Video by khanacademymedicine/YouTube
Neuromuscular junction
A neuromuscular junction (or myoneural junction) is a chemical synapse formed by the contact between a motor neuron and a muscle fiber. It is at the neuromuscular junction that a motor neuron is able to transmit a signal to the muscle fiber, causing muscle contraction.
Image by Doctor Jana
Propagation of action potential along myelinated nerve fiber myelin sheath
Propagation of action potential along myelinated nerve fiber
Image by Helixitta
Motor Neuron
At the NMJ, the axon terminal releases ACh. The motor end-plate is the location of the ACh-receptors in the muscle fiber sarcolemma. When ACh molecules are released, they diffuse across a minute space called the synaptic cleft and bind to the receptors.
Image by OpenStax College
Motor Neuron
Explicative diagram of reflex arc; the journey takes energy and nerve impulse of a stimulus by two or more neurons. The spinal cord(3) receives sensory impulses of the body(2)- here his finger and sent to the central nervous system (afferent pathways(4), which sends impulses to the spinal motor (efferent(5)that sends turn-here the bodies arm muscle through spinal nerves(6). After receiving the order, the organ or the receiver of this command, run the command(7)- here remove the finger.Parts of the scheme:
Image by MartaAguayo
Neuromuscular Junction
TheVisualMD
Location of lower motor neurons in spinal cord
Cervical vertebra blank.svg: Fred the Oyster Polio spinal diagram.PNG: DO11.10 Derived: Angelito7
Motor Neuron
Zhang MJ, Zhu CZ, Duan ZM, Niu X. Department of Cardiology, Second Affiliated Hospital, School of Medicine, Xian Jiao Tong University, China. zhangmingjuan@mail.xjtu.edu.cn
myelinated vertebrate motor neuron
LadyofHats
7:19
Motor neurons | Muscular-skeletal system physiology | NCLEX-RN | Khan Academy
khanacademymedicine/YouTube
Neuromuscular junction
Doctor Jana
Propagation of action potential along myelinated nerve fiber myelin sheath
Helixitta
Motor Neuron
OpenStax College
Motor Neuron
MartaAguayo
Sensory Receptors
Nerve function in the hand
Image by TheVisualMD
Nerve function in the hand
Nerve function in the hand
Image by TheVisualMD
Sensory Receptors
Stimuli in the environment activate specialized receptor cells in the peripheral nervous system. Different types of stimuli are sensed by different types of receptor cells. Receptor cells can be classified into types on the basis of three different criteria: cell type, position, and function. Receptors can be classified structurally on the basis of cell type and their position in relation to stimuli they sense. They can also be classified functionally on the basis of the transduction of stimuli, or how the mechanical stimulus, light, or chemical changed the cell membrane potential.
Structural Receptor Types
The cells that interpret information about the environment can be either (1) a neuron that has a free nerve ending, with dendrites embedded in tissue that would receive a sensation; (2) a neuron that has an encapsulated ending in which the sensory nerve endings are encapsulated in connective tissue that enhances their sensitivity; or (3) a specialized receptor cell, which has distinct structural components that interpret a specific type of stimulus (image). The pain and temperature receptors in the dermis of the skin are examples of neurons that have free nerve endings. Also located in the dermis of the skin are lamellated corpuscles, neurons with encapsulated nerve endings that respond to pressure and touch. The cells in the retina that respond to light stimuli are an example of a specialized receptor, a photoreceptor.
Another way that receptors can be classified is based on their location relative to the stimuli. An exteroceptor is a receptor that is located near a stimulus in the external environment, such as the somatosensory receptors that are located in the skin. An interoceptor is one that interprets stimuli from internal organs and tissues, such as the receptors that sense the increase in blood pressure in the aorta or carotid sinus. Finally, a proprioceptor is a receptor located near a moving part of the body, such as a muscle, that interprets the positions of the tissues as they move.
Functional Receptor Types
A third classification of receptors is by how the receptor transduces stimuli into membrane potential changes. Stimuli are of three general types. Some stimuli are ions and macromolecules that affect transmembrane receptor proteins when these chemicals diffuse across the cell membrane. Some stimuli are physical variations in the environment that affect receptor cell membrane potentials. Other stimuli include the electromagnetic radiation from visible light. For humans, the only electromagnetic energy that is perceived by our eyes is visible light. Some other organisms have receptors that humans lack, such as the heat sensors of snakes, the ultraviolet light sensors of bees, or magnetic receptors in migratory birds.
Receptor cells can be further categorized on the basis of the type of stimuli they transduce. Chemical stimuli can be interpreted by a chemoreceptor that interprets chemical stimuli, such as an object’s taste or smell. Osmoreceptors respond to solute concentrations of body fluids. Additionally, pain is primarily a chemical sense that interprets the presence of chemicals from tissue damage, or similar intense stimuli, through a nociceptor. Physical stimuli, such as pressure and vibration, as well as the sensation of sound and body position (balance), are interpreted through a mechanoreceptor. Another physical stimulus that has its own type of receptor is temperature, which is sensed through a thermoreceptor that is either sensitive to temperatures above (heat) or below (cold) normal body temperature.
Source: CNX OpenStax
Additional Materials (32)
Brain Sensory Nerve Communicating with Ear
Visualization of sensory nerves in the brain that directly communicate with the interior of the ear.
Image by TheVisualMD
The Sensory System
Video by Bozeman Science/YouTube
Skin Tactile Receptors
Skin Lamellated Corpuscle
Ruffini corpuscle
Close up of a Merkell cell and cross section of skin layers
Interactive by Blausen.com staff (2014). "Medical gallery of Blausen Medical 2014"
Transmission of Sound Waves to Cochlea
A sound wave causes the tympanic membrane to vibrate. This vibration is amplified as it moves across the malleus, incus, and stapes. The amplified vibration is picked up by the oval window causing pressure waves in the fluid of the scala vestibuli and scala tympani. The complexity of the pressure waves is determined by the changes in amplitude and frequency of the sound waves entering the ear.
Image by CNX Openstax
Linear Acceleration Coding by Maculae
The maculae are specialized for sensing linear acceleration, such as when gravity acts on the tilting head, or if the head starts moving in a straight line. The difference in inertia between the hair cell stereocilia and the otolithic membrane in which they are embedded leads to a shearing force that causes the stereocilia to bend in the direction of that linear acceleration.
The hair cell is a mechanoreceptor with an array of stereocilia emerging from its apical surface. The stereocilia are tethered together by proteins that open ion channels when the array is bent toward the tallest member of their array, and closed when the array is bent toward the shortest member of their array.
Image by CNX Openstax
Frequency Coding in the Cochlea
The standing sound wave generated in the cochlea by the movement of the oval window deflects the basilar membrane on the basis of the frequency of sound. Therefore, hair cells at the base of the cochlea are activated only by high frequencies, whereas those at the apex of the cochlea are activated only by low frequencies.
Image by CNX Openstax
Rotational Coding by Semicircular Canals
Rotational movement of the head is encoded by the hair cells in the base of the semicircular canals. As one of the canals moves in an arc with the head, the internal fluid moves in the opposite direction, causing the cupula and stereocilia to bend. The movement of two canals within a plane results in information about the direction in which the head is moving, and activation of all six canals can give a very precise indication of head movement in three dimensions.
Image by CNX Openstax
The Eye in the Orbit
The eye is located within the orbit and surrounded by soft tissues that protect and support its function. The orbit is surrounded by cranial bones of the skull.
Topographic Mapping of the Retina onto the Visual Cortex
The visual field projects onto the retina through the lenses and falls on the retinae as an inverted, reversed image. The topography of this image is maintained as the visual information travels through the visual pathway to the cortex.
Image by CNX Openstax
Sensory Neurons: Testing the Water
(1) The sensory neuron has endings in the skin that sense a stimulus such as water temperature. The strength of the signal that starts here is dependent on the strength of the stimulus. (2) The graded potential from the sensory endings, if strong enough, will initiate an action potential at the initial segment of the axon (which is immediately adjacent to the sensory endings in the skin). (3) The axon of the peripheral sensory neuron enters the spinal cord and contacts another neuron in the gray matter. The contact is a synapse where another graded potential is caused by the release of a chemical signal from the axon terminals. (4) An action potential is initiated at the initial segment of this neuron and travels up the sensory pathway to a region of the brain called the thalamus. Another synapse passes the information along to the next neuron. (5) The sensory pathway ends when the signal reaches the cerebral cortex. (6) After integration with neurons in other parts of the cerebral cortex, a motor command is sent from the precentral gyrus of the frontal cortex. (7) The upper motor neuron sends an action potential down to the spinal cord. The target of the upper motor neuron is the dendrites of the lower motor neuron in the gray matter of the spinal cord. (8) The axon of the lower motor neuron emerges from the spinal cord in a nerve and connects to a muscle through a neuromuscular junction to cause contraction of the target muscle.
Image by CNX Openstax
Krause's End Bulb
Medical visualization of a Krause's end bulb. Krause's end bulbs are encapsulated sensory nerve endings that are found in the superficial layers of the dermis. This rapidly adapting receptor is thought to be sensitive to light touch and cold.
Image by TheVisualMD
Pacinian Corpuscle
Visualization of a pacinian corpuscle. Found mostly in the skin of the hands, feet, genitals, and nipples, these rapidly adapting sensory receptors respond to deep pressure and vibration.
Image by TheVisualMD
Ruffini Ending
Medical visualization of Ruffini endings. Ruffini endings are touch receptors that are found in the dermis and subcutaneous tissue of the skin. This slowly adapting receptor responds to stretch and pressure, and may also be sensitive to heat.
Image by TheVisualMD
Olfactory Bulb
3D visualization of an olfactory bulb. The special sensory organs of smell, the olfactory bulbs, are located above the anterior aspect of the nasal cavity on the ethmoid bone. Nerve extensions of the bulb protrude through the 20 or so openings in the bone to the nasal cavities where they receive chemical information from circulating odor molecules and convey the signals to the cerebral cortex to be processed.
Image by TheVisualMD
Base of Brain Showing Cranial Nerve
Ventral aspect of the brain showing the cranial nerves. Fanning out in pairs like the axes on a sundial, 12 skeins of nerve fibers sprout from the undersurface of the brain, most relating to activities in the head and neck. Each pair coordinates a specific sensory and/or motor activity, connecting at the far end either with muscle cells, glands or organs or else with specialized nerve clusters, such as taste buds and light receptors in the eye.
Image by TheVisualMD
Meissner Corpuscle
Visualization of a Meissner corpuscle. Found mainly in the dermal papillae of the skin, these tactile sensory receptors respond to fine discriminative touch.
Image by TheVisualMD
3D visualization of an olfactory bulb.
The special sensory organs of smell, the olfactory bulbs, are located above the anterior aspect of the nasal cavity on the ethmoid bone. Nerve extensions of the bulb protrude through the 20 or so openings in the bone to the nasal cavities where they receive chemical information from circulating odor molecules and convey the signals to the cerebral cortex to be processed.
Image by TheVisualMD
Free Nerve Ending
Visualization of free nerve endings. Free nerve endings are sensory neurons that exist in most connective tissue in the body including skin, ligaments, muscle tissue, and in the cornea of the eye. These nerve endings detect temperature, pain, pressure and motion and can receive information from eternal or internal stimuli.
Image by TheVisualMD
Neuron
GIF visualizing the growth of the first neuron mapped by a community
Image by AmyLeeRobinson
Neuron Cell Body
Neuron Cell Body
Image by BruceBlaus
Pacinian Corpuscle
Lamellated Corpuscle
Image by Blausen.com staff (2014). \"Medical gallery of Blausen Medical 2014\". WikiJournal of Medicine 1 (2). DOI:10.15347/wjm/2014.010. ISSN 2002-4436
What Makes You Unique?
Image by TheVisualMD
Retina close up cross section
The retina is the innermost layer of the eye and is composed of several layers of neurons interconnected by synapses. The only neurons that are directly sensitive to light are the photoreceptor cells, mainly of two types: rods and cones. Light energy creates an image of the visual world on the retina, triggering nerve impulses that are sent to the visual centers of the brain through the optic nerve.The retina and the optic nerve are really parts of the brain and grow out from it during embryonic development. Two fatty acids found in breast milk are particularly critical for development of the infant eye: docosahexaenoic acid (DHA) and arachidonic acid (ARA). Unlike fats that are burned for energy, DHA and ARA play key roles as structural and signaling components in cell membranes in the brain and eye.
Image by TheVisualMD
Neurons in Hippocampus
This image shows a group of pyramidal neurons from the CA1 region of the hippocampus, with individual neurons receiving impulses across synapses from below. Creating memories is one of the brain's most remarkable functions. By relying on an intricate network of connected nerves in different parts of the brain, we can record an experience, store it like a biological file stuffed with emotions and sensory legacies and then recall it at will. The hippocampus serves as the hub for making and storing memories.
Image by TheVisualMD
3D Visualization of a young neuron
3D Visualization of a young neuron from Confocal Laser Scanner surrounded by the vascular supply
Image by TheVisualMD
Afferent Pathway of Pain
In the afferent pathway, afferent neurons (sensory or receptor neurons), carry nerve impulses from receptors or sense organs toward the central nervous system.
Image by TheVisualMD
Taste Buds
Taste, it turns out, is a marvel of chemosensory perception. Every time you eat something, whether it's a hot dog at a ballgame or an 8-course meal in a fancy restaurant, five primary tastes-salty, sweet, sour, bitter and umami-give you vital information about what you just put into your mouth. The combination of these basic tastes plus the thousands of different smells you can detect is what creates your flavor experience of that food. The sensory network that delivers that flavor experience includes microscopic taste buds clustered within the tiny bumps (papillae) on your tongue, as well as olfactory nerves that carry information from odor molecules.
Image by TheVisualMD
Taste and Smell
(a) Foliate, circumvallate, and fungiform papillae are located on different regions of the tongue. (b) Foliate papillae are prominent protrusions on this light micrograph. (credit a: modification of work by NCI; scale-bar data from Matt Russell)
Image by CNX Openstax
Taste and Smell
Pores in the tongue allow tastants to enter taste pores in the tongue. (credit: modification of work by Vincenzo Rizzo)
Image by CNX Openstax (credit: modification of work by Vincenzo Rizzo)
Brain Sensory Nerve Communicating with Ear
TheVisualMD
10:32
The Sensory System
Bozeman Science/YouTube
Skin Sensory neurons
Blausen.com staff (2014). "Medical gallery of Blausen Medical 2014"
Transmission of Sound Waves to Cochlea
CNX Openstax
Linear Acceleration Coding by Maculae
CNX Openstax
The Olfactory System
CNX Openstax
Hair Cell
CNX Openstax
Frequency Coding in the Cochlea
CNX Openstax
Rotational Coding by Semicircular Canals
CNX Openstax
The Eye in the Orbit
CNX Openstax
Photoreceptor
CNX Openstax
Topographic Mapping of the Retina onto the Visual Cortex
CNX Openstax
Sensory Neurons: Testing the Water
CNX Openstax
Krause's End Bulb
TheVisualMD
Pacinian Corpuscle
TheVisualMD
Ruffini Ending
TheVisualMD
Olfactory Bulb
TheVisualMD
Base of Brain Showing Cranial Nerve
TheVisualMD
Meissner Corpuscle
TheVisualMD
3D visualization of an olfactory bulb.
TheVisualMD
Free Nerve Ending
TheVisualMD
Neuron
AmyLeeRobinson
Neuron Cell Body
BruceBlaus
Pacinian Corpuscle
Blausen.com staff (2014). \"Medical gallery of Blausen Medical 2014\". WikiJournal of Medicine 1 (2). DOI:10.15347/wjm/2014.010. ISSN 2002-4436
What Makes You Unique?
TheVisualMD
Retina close up cross section
TheVisualMD
Neurons in Hippocampus
TheVisualMD
3D Visualization of a young neuron
TheVisualMD
Afferent Pathway of Pain
TheVisualMD
Taste Buds
TheVisualMD
Taste and Smell
CNX Openstax
Taste and Smell
CNX Openstax (credit: modification of work by Vincenzo Rizzo)
Communication Between Neurons
Synapse Between Nerve Cells
Image by TheVisualMD
Synapse Between Nerve Cells
A synapse is the junction between 2 nerve cells (neurons). Presynaptic neurons end at their axonal terminals in bulbous swellings called synaptic boutons, across the very narrow synaptic cleft lies the postsynaptic neuron. Nerve impulses spread across synapses from neuron to neuron.
Image by TheVisualMD
Communication Between Neurons
The electrical changes taking place within a neuron are similar to a light switch being turned on. A stimulus starts the depolarization, but the action potential runs on its own once a threshold has been reached. The question is now, “What flips the light switch on?” Temporary changes to the cell membrane voltage can result from neurons receiving information from the environment, or from the action of one neuron on another. These special types of potentials influence a neuron and determine whether an action potential will occur or not. Many of these transient signals originate at the synapse.
Graded Potentials
Local changes in the membrane potential are called graded potentials and are usually associated with the dendrites of a neuron. The amount of change in the membrane potential is determined by the size of the stimulus that causes it. In the example of testing the temperature of the shower, slightly warm water would only initiate a small change in a thermoreceptor, whereas hot water would cause a large amount of change in the membrane potential.
Graded potentials can be of two sorts, either they are depolarizing or hyperpolarizing (image). For a membrane at the resting potential, a graded potential represents a change in that voltage either above -70 mV or below -70 mV. Depolarizing graded potentials are often the result of Na+ or Ca2+ entering the cell. Both of these ions have higher concentrations outside the cell than inside; because they have a positive charge, they will move into the cell causing it to become less negative relative to the outside. Hyperpolarizing graded potentials can be caused by K+ leaving the cell or Cl- entering the cell. If a positive charge moves out of a cell, the cell becomes more negative; if a negative charge enters the cell, the same thing happens.
Types of Graded Potentials
For the unipolar cells of sensory neurons—both those with free nerve endings and those within encapsulations—graded potentials develop in the dendrites that influence the generation of an action potential in the axon of the same cell. This is called a generator potential. For other sensory receptor cells, such as taste cells or photoreceptors of the retina, graded potentials in their membranes result in the release of neurotransmitters at synapses with sensory neurons. This is called a receptor potential.
A postsynaptic potential (PSP) is the graded potential in the dendrites of a neuron that is receiving synapses from other cells. Postsynaptic potentials can be depolarizing or hyperpolarizing. Depolarization in a postsynaptic potential is called an excitatory postsynaptic potential (EPSP) because it causes the membrane potential to move toward threshold. Hyperpolarization in a postsynaptic potential is an inhibitory postsynaptic potential (IPSP) because it causes the membrane potential to move away from threshold.
Summation
All types of graded potentials will result in small changes of either depolarization or hyperpolarization in the voltage of a membrane. These changes can lead to the neuron reaching threshold if the changes add together, or summate. The combined effects of different types of graded potentials are illustrated in image. If the total change in voltage in the membrane is a positive 15 mV, meaning that the membrane depolarizes from -70 mV to -55 mV, then the graded potentials will result in the membrane reaching threshold.
For receptor potentials, threshold is not a factor because the change in membrane potential for receptor cells directly causes neurotransmitter release. However, generator potentials can initiate action potentials in the sensory neuron axon, and postsynaptic potentials can initiate an action potential in the axon of other neurons. Graded potentials summate at a specific location at the beginning of the axon to initiate the action potential, namely the initial segment. For sensory neurons, which do not have a cell body between the dendrites and the axon, the initial segment is directly adjacent to the dendritic endings. For all other neurons, the axon hillock is essentially the initial segment of the axon, and it is where summation takes place. These locations have a high density of voltage-gated Na+ channels that initiate the depolarizing phase of the action potential.
Summation can be spatial or temporal, meaning it can be the result of multiple graded potentials at different locations on the neuron, or all at the same place but separated in time. Spatial summation is related to associating the activity of multiple inputs to a neuron with each other. Temporal summation is the relationship of multiple action potentials from a single cell resulting in a significant change in the membrane potential. Spatial and temporal summation can act together, as well.
Synapses
There are two types of connections between electrically active cells, chemical synapses and electrical synapses. In a chemical synapse, a chemical signal—namely, a neurotransmitter—is released from one cell and it affects the other cell. In an electrical synapse, there is a direct connection between the two cells so that ions can pass directly from one cell to the next. If one cell is depolarized in an electrical synapse, the joined cell also depolarizes because the ions pass between the cells. Chemical synapses involve the transmission of chemical information from one cell to the next. This section will concentrate on the chemical type of synapse.
An example of a chemical synapse is the neuromuscular junction (NMJ) described in the chapter on muscle tissue. In the nervous system, there are many more synapses that are essentially the same as the NMJ. All synapses have common characteristics, which can be summarized in this list:
presynaptic element
neurotransmitter (packaged in vesicles)
synaptic cleft
receptor proteins
postsynaptic element
neurotransmitter elimination or re-uptake
For the NMJ, these characteristics are as follows: the presynaptic element is the motor neuron's axon terminals, the neurotransmitter is acetylcholine, the synaptic cleft is the space between the cells where the neurotransmitter diffuses, the receptor protein is the nicotinic acetylcholine receptor, the postsynaptic element is the sarcolemma of the muscle cell, and the neurotransmitter is eliminated by acetylcholinesterase. Other synapses are similar to this, and the specifics are different, but they all contain the same characteristics.
Neurotransmitter Release
When an action potential reaches the axon terminals, voltage-gated Ca2+ channels in the membrane of the synaptic end bulb open. The concentration of Ca2+ increases inside the end bulb, and the Ca2+ ion associates with proteins in the outer surface of neurotransmitter vesicles. The Ca2+ facilitates the merging of the vesicle with the presynaptic membrane so that the neurotransmitter is released through exocytosis into the small gap between the cells, known as the synaptic cleft.
Once in the synaptic cleft, the neurotransmitter diffuses the short distance to the postsynaptic membrane and can interact with neurotransmitter receptors. Receptors are specific for the neurotransmitter, and the two fit together like a key and lock. One neurotransmitter binds to its receptor and will not bind to receptors for other neurotransmitters, making the binding a specific chemical event (image).
Neurotransmitter Systems
There are several systems of neurotransmitters that are found at various synapses in the nervous system. These groups refer to the chemicals that are the neurotransmitters, and within the groups are specific systems.
The first group, which is a neurotransmitter system of its own, is the cholinergic system. It is the system based on acetylcholine. This includes the NMJ as an example of a cholinergic synapse, but cholinergic synapses are found in other parts of the nervous system. They are in the autonomic nervous system, as well as distributed throughout the brain.
The cholinergic system has two types of receptors, the nicotinic receptor is found in the NMJ as well as other synapses. There is also an acetylcholine receptor known as the muscarinic receptor. Both of these receptors are named for drugs that interact with the receptor in addition to acetylcholine. Nicotine will bind to the nicotinic receptor and activate it similar to acetylcholine. Muscarine, a product of certain mushrooms, will bind to the muscarinic receptor. However, nicotine will not bind to the muscarinic receptor and muscarine will not bind to the nicotinic receptor.
Another group of neurotransmitters are amino acids. This includes glutamate (Glu), GABA (gamma-aminobutyric acid, a derivative of glutamate), and glycine (Gly). These amino acids have an amino group and a carboxyl group in their chemical structures. Glutamate is one of the 20 amino acids that are used to make proteins. Each amino acid neurotransmitter would be part of its own system, namely the glutamatergic, GABAergic, and glycinergic systems. They each have their own receptors and do not interact with each other. Amino acid neurotransmitters are eliminated from the synapse by reuptake. A pump in the cell membrane of the presynaptic element, or sometimes a neighboring glial cell, will clear the amino acid from the synaptic cleft so that it can be recycled, repackaged in vesicles, and released again.
Another class of neurotransmitter is the biogenic amine, a group of neurotransmitters that are enzymatically made from amino acids. They have amino groups in them, but no longer have carboxyl groups and are therefore no longer classified as amino acids. Serotonin is made from tryptophan. It is the basis of the serotonergic system, which has its own specific receptors. Serotonin is transported back into the presynaptic cell for repackaging.
Other biogenic amines are made from tyrosine, and include dopamine, norepinephrine, and epinephrine. Dopamine is part of its own system, the dopaminergic system, which has dopamine receptors. Dopamine is removed from the synapse by transport proteins in the presynaptic cell membrane. Norepinephrine and epinephrine belong to the adrenergic neurotransmitter system. The two molecules are very similar and bind to the same receptors, which are referred to as alpha and beta receptors. Norepinephrine and epinephrine are also transported back into the presynaptic cell. The chemical epinephrine (epi- = “on”; “-nephrine” = kidney) is also known as adrenaline (renal = “kidney”), and norepinephrine is sometimes referred to as noradrenaline. The adrenal gland produces epinephrine and norepinephrine to be released into the blood stream as hormones.
A neuropeptide is a neurotransmitter molecule made up of chains of amino acids connected by peptide bonds. This is what a protein is, but the term protein implies a certain length to the molecule. Some neuropeptides are quite short, such as met-enkephalin, which is five amino acids long. Others are long, such as beta-endorphin, which is 31 amino acids long. Neuropeptides are often released at synapses in combination with another neurotransmitter, and they often act as hormones in other systems of the body, such as vasoactive intestinal peptide (VIP) or substance P.
The effect of a neurotransmitter on the postsynaptic element is entirely dependent on the receptor protein. First, if there is no receptor protein in the membrane of the postsynaptic element, then the neurotransmitter has no effect. The depolarizing or hyperpolarizing effect is also dependent on the receptor. When acetylcholine binds to the nicotinic receptor, the postsynaptic cell is depolarized. This is because the receptor is a cation channel and positively charged Na+ will rush into the cell. However, when acetylcholine binds to the muscarinic receptor, of which there are several variants, it might cause depolarization or hyperpolarization of the target cell.
The amino acid neurotransmitters, glutamate, glycine, and GABA, are almost exclusively associated with just one effect. Glutamate is considered an excitatory amino acid, but only because Glu receptors in the adult cause depolarization of the postsynaptic cell. Glycine and GABA are considered inhibitory amino acids, again because their receptors cause hyperpolarization.
The biogenic amines have mixed effects. For example, the dopamine receptors that are classified as D1 receptors are excitatory whereas D2-type receptors are inhibitory. Biogenic amine receptors and neuropeptide receptors can have even more complex effects because some may not directly affect the membrane potential, but rather have an effect on gene transcription or other metabolic processes in the neuron. The characteristics of the various neurotransmitter systems presented in this section are organized in image.
The important thing to remember about neurotransmitters, and signaling chemicals in general, is that the effect is entirely dependent on the receptor. Neurotransmitters bind to one of two classes of receptors at the cell surface, ionotropic or metabotropic (image). Ionotropic receptors are ligand-gated ion channels, such as the nicotinic receptor for acetylcholine or the glycine receptor. A metabotropic receptor involves a complex of proteins that result in metabolic changes within the cell. The receptor complex includes the transmembrane receptor protein, a G protein, and an effector protein. The neurotransmitter, referred to as the first messenger, binds to the receptor protein on the extracellular surface of the cell, and the intracellular side of the protein initiates activity of the G protein. The G protein is a guanosine triphosphate (GTP) hydrolase that physically moves from the receptor protein to the effector protein to activate the latter. An effector protein is an enzyme that catalyzes the generation of a new molecule, which acts as the intracellular mediator of the signal that binds to the receptor. This intracellular mediator is called the second messenger.
Different receptors use different second messengers. Two common examples of second messengers are cyclic adenosine monophosphate (cAMP) and inositol triphosphate (IP3). The enzyme adenylate cyclase (an example of an effector protein) makes cAMP, and phospholipase C is the enzyme that makes IP3. Second messengers, after they are produced by the effector protein, cause metabolic changes within the cell. These changes are most likely the activation of other enzymes in the cell. In neurons, they often modify ion channels, either opening or closing them. These enzymes can also cause changes in the cell, such as the activation of genes in the nucleus, and therefore the increased synthesis of proteins. In neurons, these kinds of changes are often the basis of stronger connections between cells at the synapse and may be the basis of learning and memory.
Met-enkephalin, beta-endorphin, VIP, Substance P, etc.
Receptors
Nicotinic and muscarinic receptors
Glu receptors, gly receptors, GABA receptors
5-HT receptors, D1 and D2 receptors, α-adrenergic and β-adrenergic receptors
Receptors are too numerous to list, but are specific to the peptides.
Elimination
Degradation by acetylcholinesterase
Reuptake by neurons or glia
Reuptake by neurons
Degradation by enzymes called peptidases
Postsynaptic effect
Nicotinic receptor causes depolarization. Muscarinic receptors can cause both depolarization or hyperpolarization depending on the subtype.
Glu receptors cause depolarization. Gly and GABA receptors cause hyperpolarization.
Depolarization or hyperpolarization depends on the specific receptor. For example, D1 receptors cause depolarization and D2 receptors cause hyperpolarization.
Depolarization or hyperpolarization depends on the specific receptor.
Review
The basis of the electrical signal within a neuron is the action potential that propagates down the axon. For a neuron to generate an action potential, it needs to receive input from another source, either another neuron or a sensory stimulus. That input will result in opening ion channels in the neuron, resulting in a graded potential based on the strength of the stimulus. Graded potentials can be depolarizing or hyperpolarizing and can summate to affect the probability of the neuron reaching threshold.
Graded potentials can be the result of sensory stimuli. If the sensory stimulus is received by the dendrites of a unipolar sensory neuron, such as the sensory neuron ending in the skin, the graded potential is called a generator potential because it can directly generate the action potential in the initial segment of the axon. If the sensory stimulus is received by a specialized sensory receptor cell, the graded potential is called a receptor potential. Graded potentials produced by interactions between neurons at synapses are called postsynaptic potentials (PSPs). A depolarizing graded potential at a synapse is called an excitatory PSP, and a hyperpolarizing graded potential at a synapse is called an inhibitory PSP.
Synapses are the contacts between neurons, which can either be chemical or electrical in nature. Chemical synapses are far more common. At a chemical synapse, neurotransmitter is released from the presynaptic element and diffuses across the synaptic cleft. The neurotransmitter binds to a receptor protein and causes a change in the postsynaptic membrane (the PSP). The neurotransmitter must be inactivated or removed from the synaptic cleft so that the stimulus is limited in time.
The particular characteristics of a synapse vary based on the neurotransmitter system produced by that neuron. The cholinergic system is found at the neuromuscular junction and in certain places within the nervous system. Amino acids, such as glutamate, glycine, and gamma-aminobutyric acid (GABA) are used as neurotransmitters. Other neurotransmitters are the result of amino acids being enzymatically changed, as in the biogenic amines, or being covalently bonded together, as in the neuropeptides.
Source: CNX OpenStax
Additional Materials (24)
The Brain's Couriers
How Do Nerve Cells Work? Nerve cells talk to each other via a complex system of electrical impulses and chemical signals. They are supported by another type of cell, called glia. Their work is so important that glia outnumber nerve cells in the brain and spinal cord. Types of Nerve Cells (Neurons) Nerve cells fall into one of three types. Sensory neurons are responsible for relaying information from the senses—eyes, ears, nose, tongue and skin—to the brain to register sight, sound, smell, taste and touch. Motor neurons link the brain and spinal cord to the various muscles throughout the body, including those in our fingers and toes. Interneurons are intermediaries that bridge sensory or motor neurons to their neighbors. Anatomy of a Nerve Cell (Neuron) Soma Also known as the cell body, the soma is the anatomical hub of the nerve cell and contains its DNA. The cell body collects incoming information and transmits it as electrical impulses along the nerve cell’s axon. Axon This fiber is the workhorse of the nerve cell. Like a fiber-optic cable loaded with information, axons carry out-going messages from brain nerve cells to other parts of the body. They can measure over a foot in length. Dendrites While each nerve cell has only one axon, it may have multiple dendrites, which resemble the branches of a tree. Dendrites collect incoming information for nerve cells from the environment, such as smells or sounds. Dendritic Spine Just as a tree’s health depends on the strength and robustness of its branches, the major limbs of a nerve cell’s dendrites, or spines, may determine how well it functions in relaying incoming information to the soma. Synapse When nerve cells communicate with each other, they don’t physically come into contact. Instead, they send chemicals across a small space known as a synapse, and special structures located at the ends of axons are designed to release and absorb these agents and translate them into the electrical signals that continue on their way along the nerve cell highway.
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Neural pathway
Your Brain is Electric : Information, in the form of electrical impulses, travels along neural pathways composed of interconnected neurons. Neuron cells are composed of three basic elements: the cell body, the axon, and the dendrite. Axons are long fibers, sometimes branched, which extend out of the cell body and transmit electrical impulses to the next neuron. Dendrites are highly branched fibers that receive signals from the axons of other neurons. The place where axons and dendrites join is called a synapse. For every neuron, there are between 1,000 and 10,000 synapses. Axons and dendrites don't actually touch at the synapse: there's a microscopic space in between where information is transferred.
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Synapse
Electric Impulses in the Brain : When the cell body receives enough stimulation-when you touch a very hot object, for instance-it generates an electrical impulse that is transmitted to the end of the axon. These impulses travel across the neurons at an amazing rate of speed: less than 1/5,000 of a second. The impulse causes the axon to release chemicals called neurotransmitters into the synapse between the axon and the adjoining dendrite. Neurotransmitters are chemical messengers, carrying information from one neuron to another.
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Neuronal synapses (chemical) | Human anatomy and physiology | Health & Medicine | Khan Academy
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Your Brain Is Electric
Information, in the form of electrical impulses, travels along neural pathways composed of interconnected neurons. Neuron cells are composed of three basic elements: the cell body, the axon, and the dendrite. Axons are long fibers, sometimes branched, which extend out of the cell body and transmit electrical impulses to the next neuron. Dendrites are highly branched fibers that receive signals from the axons of other neurons. The place where axons and dendrites join is called a synapse. For every neuron, there are between 1,000 and 10,000 synapses. Axons and dendrites don't actually touch at the synapse: there's a microscopic space in between where information is transferred.
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Serotonin Reuptake
The neurotransmitter serotonin is released into the synapse between the axon of one neuron and the dendrite of another, where it binds to receptors on the dendrite. Once the neurotransmitter releases from the receptor site, it floats back into the synapse, where it is taken back in by the neuron that originally released it (reuptake).
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Synapse of Neuron
Visualization of a synapse. Firing in collective bursts, neurons are designed to send and receive electrical messages along a variable number of filaments. The longest of these (some reach up to three feet) carry messages away from the cell body, and are called axons. To speed up transmission, axons are padded with packets of fatty insulation, then bundled into gangs, wrapped, and rebundled into cables that can relay a signal at speeds over 200 miles per hour. Knoblike feet at the end of the axon contain sacs of chemicals (neurotransmitters) that further speed the process along.
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Synapse of Neuron
Chemical synapses are specialized junctions through which the cells of the nervous system signal to each other. Chemical synapses allow the neurons of the central nervous system to form interconnected neural circuits. They are thus crucial to perception and thought. They provide the means through which the nervous system connects to and controls the other systems of the body.
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Your Brain Is Electric
Information, in the form of electrical impulses, travels along neural pathways composed of interconnected neurons. Neuron cells are composed of three basic elements: the cell body, the axon, and the dendrite. Axons are long fibers, sometimes branched, which extend out of the cell body and transmit electrical impulses to the next neuron. Dendrites are highly branched fibers that receive signals from the axons of other neurons. The place where axons and dendrites join is called a synapse. For every neuron, there are between 1,000 and 10,000 synapses. Axons and dendrites don't actually touch at the synapse: there's a microscopic space in between where information is transferred.
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Synapse between Neurons with Beta amyloid
Beta amyloid, also called A-beta, is formed after a larger amyloid precursor protein, is severed by enzymes. These beta amyloid proteins accumulate to form large plaques between nerve cells. Eventually, the amyloid deposits block off the nerve cells from their network and cause the cells to die. Researchers believe that amyloid is the key to Alzheimer's disease, and the latest research suggests that it's not that people with Alzheimer's make too much amyloid; rather, they aren't able to clear the protein from the brain properly. While it's clear that amyloid plays a role in the Alzheimer's process, what is less obvious is whether removing the protein can treat the disease. Why? The disease occurs gradually over a long period of time, and the interventions might have simply been used too late. Researchers are currently studying whether these types of treatments might be more effective if introduced earlier in the disease process.
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Neurotransmitters
Synapse between Neurons : Chemical synapses are specialized junctions through which the cells of the nervous system signal to each other. Electrical impulses generated by a presynaptic neuron are transmitted by way of neurotransmitters (messenger chemicals) across the synaptic cleft and to the postsynaptic neuron, which then propagates the electrical signal onward to its eventual destination.
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Nerve Bundle
Visualization of a synapse. Firing in collective bursts, neurons are designed to send and receive electrical messages along a variable number of filaments. The longest of these (some reach up to three feet) carry messages away from the cell body, and are called axons. To speed up transmission, axons are padded with packets of fatty insulation, then bundled into gangs, wrapped, and rebundled into cables that can relay a signal at speeds over 200 miles per hour. Knoblike feet at the end of the axon contain sacs of chemicals (neurotransmitters) that further speed the process along.
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Synapse of Neuron
Chemical synapses are specialized junctions through which the cells of the nervous system signal to each other. Chemical synapses allow the neurons of the central nervous system to form interconnected neural circuits. They are thus crucial to the biological computations that underlie perception and thought. They provide the means through which the nervous system connects to and controls the other systems of the body.
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Synapse of Neuron
Chemical synapses are specialized junctions through which the cells of the nervous system signal to each other. Chemical synapses allow the neurons of the central nervous system to form interconnected neural circuits. They are thus crucial to the biological computations that underlie perception and thought. They provide the means through which the nervous system connects to and controls the other systems of the body.
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Action Potential of Nerve Cell
The action potential travels along the cell membrane. After traveling the whole length of the axon, it reaches a synapse, where it stimulates the release of neurotransmitters. These neurotransmitters can immediately induce an action potential in the next neuron to propagate the signal, but the response is usually more complex.
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Action Potential of Nerve Cell
Action potential- The action potential travels along the cell membrane. After traveling the whole length of the axon, it reaches a synapse, where it stimulates the release of neurotransmitters. These neurotransmitters can immediately induce an action potential in the next neuron to propagate the signal, but the response is usually more complex.
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Action Potential of Nerve Cell
The action potential travels along the cell membrane. After traveling the whole length of the axon, it reaches a synapse, where it stimulates the release of neurotransmitters. These neurotransmitters can immediately induce an action potential in the next neuron to propagate the signal, but the response is usually more complex.
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Synapse of neurons
Synapse of neurons
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Neuron Synapse
Neuron Synapse
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Neurons
Our brains need a continuous supply of fuel in the form of glucose because they can't store energy reserves. Though the brain represents only about 2% of the body's mass, it consumes about 60% of the glucose coursing through our bloodstreams. Our ability to use glucose as a source of energy depends on the hormone insulin, produced by the pancreas; levels of insulin and glucose in the blood must be maintained in careful balance.
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Anatomy of a Neuron
Anatomy of a Neuron
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What Is Alzheimer's Disease?
Who Gets Alzheimer's Disease? Age is a key driver of this brain disorder, and those over the age of 65 are most vulnerable to developing Alzheimer's. How Long Does Alzheimer's Take to Develop? Most experts believe that the first steps toward disease begin in middle age, long before symptoms of Alzheimer's appear in later life. It's a progressive disorder, so the decline in brain function is incremental, and occurs over a period of years, if not decades. The latest imaging technologies can detect some of the early signs of Alzheimer's, and researchers are developing laboratory tests that can diagnose the disease during its beginning stages as well.
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Action Potential of Neuron
Neurons consist of three elements: the cell body, axons, and dendrites. A signal is transmitted from neuron to neuron by an electrical force known as the action potential. The size of the signal is always the same; what varies is whether it's switched \"on\" or \"off.\" When a cell body receives enough stimulation--for example, when you touch a very hot teapot--voltage-gated ion channels open on its surface to let charged particles (ions) into, and then out of, the cell. The flow of these particles causes the cell to generate an electrical discharge that is transmitted down the length of the axon to its end, or terminal.
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Boy with visible Brain highlighting Dopamine Pathway
Boy with visible brain highlighting Norepinephrine Pathway
Boy with visible Brain highlighting Serotonin Pathway
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1) Boy with visible Brain highlighting 1) Dopamine Pathway 2) Norepinephrine Pathway 3) Serotonin Pathway
1) Boy with visible Brain highlighting Dopamine Pathway
2) Boy with visible brain highlighting Norepinephrine Pathway
3) Boy with visible Brain highlighting Serotonin Pathway
A toddler boy is shown in profile with some visible brain anatomy. The pathway for the neurotransmitter norepinephrine, shown in green, overlays the outline of the brain. The image supports content about individual temperament and personality differences, including the balance of brain chemicals, that can affect each person's capacity for positive and negative emotions.
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The Brain's Couriers
TheVisualMD
Neural pathway
TheVisualMD
Synapse
TheVisualMD
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Neuronal synapses (chemical) | Human anatomy and physiology | Health & Medicine | Khan Academy
Khan Academy/YouTube
Your Brain Is Electric
TheVisualMD
Serotonin Reuptake
TheVisualMD
Synapse of Neuron
TheVisualMD
Synapse of Neuron
TheVisualMD
Your Brain Is Electric
TheVisualMD
Synapse between Neurons with Beta amyloid
TheVisualMD
Neurotransmitters
TheVisualMD
Nerve Bundle
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Synapse of Neuron
TheVisualMD
Synapse of Neuron
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Action Potential of Nerve Cell
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Action Potential of Nerve Cell
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Action Potential of Nerve Cell
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Synapse of neurons
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Neuron Synapse
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Neurons
TheVisualMD
Anatomy of a Neuron
TheVisualMD
What Is Alzheimer's Disease?
TheVisualMD
Action Potential of Neuron
TheVisualMD
1) Boy with visible Brain highlighting 1) Dopamine Pathway 2) Norepinephrine Pathway 3) Serotonin Pathway
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Nervous System Basics
Posterior-lateral view of the central nervous system
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Posterior-lateral view of the central nervous system
3D visualization reconstructed from scanned human data of a posterior-lateral view of the central nervous system. The central nervous system is made up of brain and spinal cord. Enclosed within, and protected by, the bony vertebral column, the spinal cord functions primarily in the transmission of neural signals between the brain and the rest of the body.
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Basic Structure and Function of the Nervous System
The picture you have in your mind of the nervous system probably includes the brain, the nervous tissue contained within the cranium, and the spinal cord, the extension of nervous tissue within the vertebral column. That suggests it is made of two organs—and you may not even think of the spinal cord as an organ—but the nervous system is a very complex structure. Within the brain, many different and separate regions are responsible for many different and separate functions. It is as if the nervous system is composed of many organs that all look similar and can only be differentiated using tools such as the microscope or electrophysiology. In comparison, it is easy to see that the stomach is different than the esophagus or the liver, so you can imagine the digestive system as a collection of specific organs.
The Central and Peripheral Nervous Systems
The nervous system can be divided into two major regions: the central and peripheral nervous systems. The central nervous system (CNS) is the brain and spinal cord, and the peripheral nervous system (PNS) is everything else (image below). The brain is contained within the cranial cavity of the skull, and the spinal cord is contained within the vertebral cavity of the vertebral column. It is a bit of an oversimplification to say that the CNS is what is inside these two cavities and the peripheral nervous system is outside of them, but that is one way to start to think about it. In actuality, there are some elements of the peripheral nervous system that are within the cranial or vertebral cavities. The peripheral nervous system is so named because it is on the periphery—meaning beyond the brain and spinal cord. Depending on different aspects of the nervous system, the dividing line between central and peripheral is not necessarily universal.
Nervous tissue, present in both the CNS and PNS, contains two basic types of cells: neurons and glial cells. A glial cell is one of a variety of cells that provide a framework of tissue that supports the neurons and their activities. The neuron is the more functionally important of the two, in terms of the communicative function of the nervous system. To describe the functional divisions of the nervous system, it is important to understand the structure of a neuron. Neurons are cells and therefore have a soma, or cell body, but they also have extensions of the cell; each extension is generally referred to as a process. There is one important process that every neuron has called an axon, which is the fiber that connects a neuron with its target. Another type of process that branches off from the soma is the dendrite. Dendrites are responsible for receiving most of the input from other neurons. Looking at nervous tissue, there are regions that predominantly contain cell bodies and regions that are largely composed of just axons. These two regions within nervous system structures are often referred to as gray matter (the regions with many cell bodies and dendrites) or white matter (the regions with many axons). The image below demonstrates the appearance of these regions in the brain and spinal cord. The colors ascribed to these regions are what would be seen in “fresh,” or unstained, nervous tissue. Gray matter is not necessarily gray. It can be pinkish because of blood content, or even slightly tan, depending on how long the tissue has been preserved. But white matter is white because axons are insulated by a lipid-rich substance called myelin. Lipids can appear as white (“fatty”) material, much like the fat on a raw piece of chicken or beef. Actually, gray matter may have that color ascribed to it because next to the white matter, it is just darker—hence, gray.
The distinction between gray matter and white matter is most often applied to central nervous tissue, which has large regions that can be seen with the unaided eye. When looking at peripheral structures, often a microscope is used and the tissue is stained with artificial colors. That is not to say that central nervous tissue cannot be stained and viewed under a microscope, but unstained tissue is most likely from the CNS—for example, a frontal section of the brain or cross section of the spinal cord.
Regardless of the appearance of stained or unstained tissue, the cell bodies of neurons or axons can be located in discrete anatomical structures that need to be named. Those names are specific to whether the structure is central or peripheral. A localized collection of neuron cell bodies in the CNS is referred to as a nucleus. In the PNS, a cluster of neuron cell bodies is referred to as a ganglion. The image below indicates how the term nucleus has a few different meanings within anatomy and physiology. It is the center of an atom, where protons and neutrons are found; it is the center of a cell, where the DNA is found; and it is a center of some function in the CNS. There is also a potentially confusing use of the word ganglion (plural = ganglia) that has a historical explanation. In the central nervous system, there is a group of nuclei that are connected together and were once called the basal ganglia before “ganglion” became accepted as a description for a peripheral structure. Some sources refer to this group of nuclei as the “basal nuclei” to avoid confusion.
Terminology applied to bundles of axons also differs depending on location. A bundle of axons, or fibers, found in the CNS is called a tract whereas the same thing in the PNS would be called a nerve. There is an important point to make about these terms, which is that they can both be used to refer to the same bundle of axons. When those axons are in the PNS, the term is nerve, but if they are CNS, the term is tract. The most obvious example of this is the axons that project from the retina into the brain. Those axons are called the optic nerve as they leave the eye, but when they are inside the cranium, they are referred to as the optic tract. There is a specific place where the name changes, which is the optic chiasm, but they are still the same axons (image below). A similar situation outside of science can be described for some roads. Imagine a road called “Broad Street” in a town called “Anyville.” The road leaves Anyville and goes to the next town over, called “Hometown.” When the road crosses the line between the two towns and is in Hometown, its name changes to “Main Street.” That is the idea behind the naming of the retinal axons. In the PNS, they are called the optic nerve, and in the CNS, they are the optic tract. Table helps to clarify which of these terms apply to the central or peripheral nervous systems.
Optic Nerve Versus Optic Tract
This drawing of the connections of the eye to the brain shows the optic nerve extending from the eye to the chiasm, where the structure continues as the optic tract. The same axons extend from the eye to the brain through these two bundles of fibers, but the chiasm represents the border between peripheral and central.
In 2003, the Nobel Prize in Physiology or Medicine was awarded to Paul C. Lauterbur and Sir Peter Mansfield for discoveries related to magnetic resonance imaging (MRI). This is a tool to see the structures of the body (not just the nervous system) that depends on magnetic fields associated with certain atomic nuclei. The utility of this technique in the nervous system is that fat tissue and water appear as different shades between black and white. Because white matter is fatty (from myelin) and gray matter is not, they can be easily distinguished in MRI images. Try this PhET simulation that demonstrates the use of this technology and compares it with other types of imaging technologies. Also, the results from an MRI session are compared with images obtained from X-ray or computed tomography.
Structures of the CNS and PNS
CNS
PNS
Group of Neuron Cell Bodies (i.e., gray matter)
Nucleus
Ganglion
Bundle of Axons (i.e., white matter)
Tract
Nerve
Functional Divisions of the Nervous System
The nervous system can also be divided on the basis of its functions, but anatomical divisions and functional divisions are different. The CNS and the PNS both contribute to the same functions, but those functions can be attributed to different regions of the brain (such as the cerebral cortex or the hypothalamus) or to different ganglia in the periphery. The problem with trying to fit functional differences into anatomical divisions is that sometimes the same structure can be part of several functions. For example, the optic nerve carries signals from the retina that are either used for the conscious perception of visual stimuli, which takes place in the cerebral cortex, or for the reflexive responses of smooth muscle tissue that are processed through the hypothalamus.
There are two ways to consider how the nervous system is divided functionally. First, the basic functions of the nervous system are sensation, integration, and response. Secondly, control of the body can be somatic or autonomic—divisions that are largely defined by the structures that are involved in the response. There is also a region of the peripheral nervous system that is called the enteric nervous system that is responsible for a specific set of the functions within the realm of autonomic control related to gastrointestinal functions.
Basic Functions
The nervous system is involved in receiving information about the environment around us (sensation) and generating responses to that information (motor responses). The nervous system can be divided into regions that are responsible for sensation (sensory functions) and for the response (motor functions). But there is a third function that needs to be included. Sensory input needs to be integrated with other sensations, as well as with memories, emotional state, or learning (cognition). Some regions of the nervous system are termed integration or association areas. The process of integration combines sensory perceptions and higher cognitive functions such as memories, learning, and emotion to produce a response.
Sensation. The first major function of the nervous system is sensation—receiving information about the environment to gain input about what is happening outside the body (or, sometimes, within the body). The sensory functions of the nervous system register the presence of a change from homeostasis or a particular event in the environment, known as a stimulus. The senses we think of most are the “big five”: taste, smell, touch, sight, and hearing. The stimuli for taste and smell are both chemical substances (molecules, compounds, ions, etc.), touch is physical or mechanical stimuli that interact with the skin, sight is light stimuli, and hearing is the perception of sound, which is a physical stimulus similar to some aspects of touch. There are actually more senses than just those, but that list represents the major senses. Those five are all senses that receive stimuli from the outside world, and of which there is conscious perception. Additional sensory stimuli might be from the internal environment (inside the body), such as the stretch of an organ wall or the concentration of certain ions in the blood.
Response. The nervous system produces a response on the basis of the stimuli perceived by sensory structures. An obvious response would be the movement of muscles, such as withdrawing a hand from a hot stove, but there are broader uses of the term. The nervous system can cause the contraction of all three types of muscle tissue. For example, skeletal muscle contracts to move the skeleton, cardiac muscle is influenced as heart rate increases during exercise, and smooth muscle contracts as the digestive system moves food along the digestive tract. Responses also include the neural control of glands in the body as well, such as the production and secretion of sweat by the eccrine and merocrine sweat glands found in the skin to lower body temperature.
Responses can be divided into those that are voluntary or conscious (contraction of skeletal muscle) and those that are involuntary (contraction of smooth muscles, regulation of cardiac muscle, activation of glands). Voluntary responses are governed by the somatic nervous system and involuntary responses are governed by the autonomic nervous system, which are discussed in the next section.
Integration. Stimuli that are received by sensory structures are communicated to the nervous system where that information is processed. This is called integration. Stimuli are compared with, or integrated with, other stimuli, memories of previous stimuli, or the state of a person at a particular time. This leads to the specific response that will be generated. Seeing a baseball pitched to a batter will not automatically cause the batter to swing. The trajectory of the ball and its speed will need to be considered. Maybe the count is three balls and one strike, and the batter wants to let this pitch go by in the hope of getting a walk to first base. Or maybe the batter’s team is so far ahead, it would be fun to just swing away.
Controlling the Body
The nervous system can be divided into two parts mostly on the basis of a functional difference in responses. The somatic nervous system (SNS) is responsible for conscious perception and voluntary motor responses. Voluntary motor response means the contraction of skeletal muscle, but those contractions are not always voluntary in the sense that you have to want to perform them. Some somatic motor responses are reflexes, and often happen without a conscious decision to perform them. If your friend jumps out from behind a corner and yells “Boo!” you will be startled and you might scream or leap back. You didn’t decide to do that, and you may not have wanted to give your friend a reason to laugh at your expense, but it is a reflex involving skeletal muscle contractions. Other motor responses become automatic (in other words, unconscious) as a person learns motor skills (referred to as “habit learning” or “procedural memory”).
The autonomic nervous system (ANS) is responsible for involuntary control of the body, usually for the sake of homeostasis (regulation of the internal environment). Sensory input for autonomic functions can be from sensory structures tuned to external or internal environmental stimuli. The motor output extends to smooth and cardiac muscle as well as glandular tissue. The role of the autonomic system is to regulate the organ systems of the body, which usually means to control homeostasis. Sweat glands, for example, are controlled by the autonomic system. When you are hot, sweating helps cool your body down. That is a homeostatic mechanism. But when you are nervous, you might start sweating also. That is not homeostatic, it is the physiological response to an emotional state.
There is another division of the nervous system that describes functional responses. The enteric nervous system (ENS) is responsible for controlling the smooth muscle and glandular tissue in your digestive system. It is a large part of the PNS, and is not dependent on the CNS. It is sometimes valid, however, to consider the enteric system to be a part of the autonomic system because the neural structures that make up the enteric system are a component of the autonomic output that regulates digestion. There are some differences between the two, but for our purposes here there will be a good bit of overlap. See image below for examples of where these divisions of the nervous system can be found.
Somatic, Autonomic, and Enteric Structures of the Nervous System
Somatic structures include the spinal nerves, both motor and sensory fibers, as well as the sensory ganglia (posterior root ganglia and cranial nerve ganglia). Autonomic structures are found in the nerves also, but include the sympathetic and parasympathetic ganglia. The enteric nervous system includes the nervous tissue within the organs of the digestive tract.
EVERYDAY CONNECTION
How Much of Your Brain Do You Use?Have you ever heard the claim that humans only use 10 percent of their brains? Maybe you have seen an advertisement on a website saying that there is a secret to unlocking the full potential of your mind—as if there were 90 percent of your brain sitting idle, just waiting for you to use it. If you see an ad like that, don’t click. It isn’t true.
An easy way to see how much of the brain a person uses is to take measurements of brain activity while performing a task. An example of this kind of measurement is functional magnetic resonance imaging (fMRI), which generates a map of the most active areas and can be generated and presented in three dimensions (image below). This procedure is different from the standard MRI technique because it is measuring changes in the tissue in time with an experimental condition or event.
The underlying assumption is that active nervous tissue will have greater blood flow. By having the subject perform a visual task, activity all over the brain can be measured. Consider this possible experiment: the subject is told to look at a screen with a black dot in the middle (a fixation point). A photograph of a face is projected on the screen away from the center. The subject has to look at the photograph and decipher what it is. The subject has been instructed to push a button if the photograph is of someone they recognize. The photograph might be of a celebrity, so the subject would press the button, or it might be of a random person unknown to the subject, so the subject would not press the button.
In this task, visual sensory areas would be active, integrating areas would be active, motor areas responsible for moving the eyes would be active, and motor areas for pressing the button with a finger would be active. Those areas are distributed all around the brain and the fMRI images would show activity in more than just 10 percent of the brain (some evidence suggests that about 80 percent of the brain is using energy—based on blood flow to the tissue—during well-defined tasks similar to the one suggested above). This task does not even include all of the functions the brain performs. There is no language response, the body is mostly lying still in the MRI machine, and it does not consider the autonomic functions that would be ongoing in the background.
Review
The nervous system can be separated into divisions on the basis of anatomy and physiology. The anatomical divisions are the central and peripheral nervous systems. The CNS is the brain and spinal cord. The PNS is everything else. Functionally, the nervous system can be divided into those regions that are responsible for sensation, those that are responsible for integration, and those that are responsible for generating responses. All of these functional areas are found in both the central and peripheral anatomy.
Considering the anatomical regions of the nervous system, there are specific names for the structures within each division. A localized collection of neuron cell bodies is referred to as a nucleus in the CNS and as a ganglion in the PNS. A bundle of axons is referred to as a tract in the CNS and as a nerve in the PNS. Whereas nuclei and ganglia are specifically in the central or peripheral divisions, axons can cross the boundary between the two. A single axon can be part of a nerve and a tract. The name for that specific structure depends on its location.
Nervous tissue can also be described as gray matter and white matter on the basis of its appearance in unstained tissue. These descriptions are more often used in the CNS. Gray matter is where nuclei are found and white matter is where tracts are found. In the PNS, ganglia are basically gray matter and nerves are white matter.
The nervous system can also be divided on the basis of how it controls the body. The somatic nervous system (SNS) is responsible for functions that result in moving skeletal muscles. Any sensory or integrative functions that result in the movement of skeletal muscle would be considered somatic. The autonomic nervous system (ANS) is responsible for functions that affect cardiac or smooth muscle tissue, or that cause glands to produce their secretions. Autonomic functions are distributed between central and peripheral regions of the nervous system. The sensations that lead to autonomic functions can be the same sensations that are part of initiating somatic responses. Somatic and autonomic integrative functions may overlap as well.
A special division of the nervous system is the enteric nervous system, which is responsible for controlling the digestive organs. Parts of the autonomic nervous system overlap with the enteric nervous system. The enteric nervous system is exclusively found in the periphery because it is the nervous tissue in the organs of the digestive system.
Source: CNX OpenStax
Additional Materials (2)
Structure of the nervous system | Organ Systems | MCAT | Khan Academy
Video by khanacademymedicine/YouTube
Brain and Nervous System
Brain and Nervous System : 3D visualization reconstructed from scanned human data of a dorsal view of a seated man revealing the nerves of the central and peripheral nervous systems. The nervous system is the master controlling and communicating system of the body. It's an ultra-high-speed communication network made up of nerve cells (neurons) and their far-reaching fibers (axons) that constantly send infinite numbers of electrical and chemical signals to and from the brain. The nervous system is organized into two principle parts, the central nervous system and the peripheral nervous system. The CNS, consisting of the brain and spinal cord, interprets incoming sensory information and creates responses based on reflexes, past experiences and current conditions. The peripheral nervous system, made up of extensions of the CNS, serves as a communication line that links all parts of the body to the brain.
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Structure of the nervous system | Organ Systems | MCAT | Khan Academy
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Brain and Nervous System
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Introduction - Brain Basics
Progenitor Cell
Committed Cell
Mature Cell
Differentiated Cell
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Maturation of a Neuron
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Progenitor Cell
Committed Cell
Mature Cell
Differentiated Cell
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Maturation of a Neuron
Interactive by TheVisualMD
Introduction - Brain Basics
Until recently, most neuroscientists thought we were born with all the neurons we were ever going to have. As children we might produce some new neurons to help build the pathways - called neural circuits - that act as information highways between different areas of the brain. But scientists believed that once a neural circuit was in place, adding any new neurons would disrupt the flow of information and disable the brain’s communication system.
In 1962, scientist Joseph Altman challenged this belief when he saw evidence of neurogenesis (the birth of neurons) in a region of the adult rat brain called the hippocampus. He later reported that newborn neurons migrated from their birthplace in the hippocampus to other parts of the brain. In 1979, another scientist, Michael Kaplan, confirmed Altman’s findings in the rat brain, and in 1983 he found neural precursor cells in the forebrain of an adult monkey.
These discoveries about neurogenesis in the adult brain were surprising to other researchers who didn’t think they could be true in humans. But in the early 1980s, a scientist trying to understand how birds learn to sing suggested that neuroscientists look again at neurogenesis in the adult brain and begin to see how it might make sense. In a series of experiments, Fernando Nottebohm and his research team showed that the numbers of neurons in the forebrains of male canaries dramatically increased during the mating season. This was the same time in which the birds had to learn new songs to attract females.
Why did these bird brains add neurons at such a critical time in learning? Nottebohm believed it was because fresh neurons helped store new song patterns within the neural circuits of the forebrain, the area of the brain that controls complex behaviors. These new neurons made learning possible. If birds made new neurons to help them remember and learn, Nottebohm thought the brains of mammals might too.
Other scientists believed these findings could not apply to mammals, but Elizabeth Gould later found evidence of newborn neurons in a distinct area of the brain in monkeys, and Fred Gage and Peter Eriksson showed that the adult human brain produced new neurons in a similar area.
For some neuroscientists, neurogenesis in the adult brain is still an unproven theory. But others think the evidence offers intriguing possibilities about the role of adult-generated neurons in learning and memory.
Source: Brain Basics: The Life and Death of a Neuron | National Institute of Neurological Disorders and Stroke
The Architecture of the Neuron
Action Potential of Nerve Cell
Action Potential of Nerve Cell
Action Potential of Nerve Cell
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Action Potential of Nerve Cell
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Action Potential of Nerve Cell
Action Potential of Nerve Cell
Action Potential of Nerve Cell
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Action Potential of Nerve Cell
The action potential travels along the cell membrane. After traveling the whole length of the axon, it reaches a synapse, where it stimulates the release of neurotransmitters. These neurotransmitters can immediately induce an action potential in the next neuron to propagate the signal, but the response is usually more complex.
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The Architecture of the Neuron
The central nervous system (which includes the brain and spinal cord) is made up of two basic types of cells: neurons (1) and glia (4) & (6). Glia outnumber neurons in some parts of the brain, but neurons are the key players in the brain.
Neurons are information messengers. They use electrical impulses and chemical signals to transmit information between different areas of the brain, and between the brain and the rest of the nervous system. Everything we think and feel and do would be impossible without the work of neurons and their support cells, the glial cells called astrocytes (4) and oligodendrocytes (6).
Neurons have three basic parts: a cell body and two extensions called an axon (5) and a dendrite (3). Within the cell body is a nucleus (2), which controls the cell’s activities and contains the cell’s genetic material. The axon looks like a long tail and transmits messages from the cell. Dendrites look like the branches of a tree and receive messages for the cell. Neurons communicate with each other by sending chemicals, called neurotransmitters, across a tiny space, called a synapse, between the axons and dendrites of adjacent neurons.
There are three classes of neurons:
Sensory neurons carry information from the sense organs (such as the eyes and ears) to the brain.
Motor neurons control voluntary muscle activity such as speaking and carry messages from nerve cells in the brain to the muscles.
All the other neurons are called interneurons.
Scientists think that neurons are the most diverse kind of cell in the body. Within these three classes of neurons are hundreds of different types, each with specific message-carrying abilities.
How these neurons communicate with each other by making connections is what makes each of us unique in how we think, and feel, and act.
Source: Brain Basics: The Life and Death of a Neuron | National Institute of Neurological Disorders and Stroke
Grey matter is distributed at the surface of the cerebral hemispheres (cerebral cortex) and of the cerebellum (cerebellar cortex), Grey matter routes sensory or motor stimulus to interneurons of the CNS
Cortical neuron stained with antibody to neurofilament subunit NF-L in green. In red are neuronal stem cells stained with antibody to alpha-internexin. Image created using antibodies from EnCor Biotechnology Inc.
Image by GerryShaw
Birth
The extent to which new neurons are generated in the brain is a controversial subject among neuroscientists. Although the majority of neurons are already present in our brains by the time we are born, there is evidence to support that neurogenesis (the scientific word for the birth of neurons) is a lifelong process.
Neurons are born in areas of the brain that are rich in concentrations of neural precursor cells (also called neural stem cells). These cells have the potential to generate most, if not all, of the different types of neurons and glia found in the brain.
Neuroscientists have observed how neural precursor cells behave in the laboratory. Although this may not be exactly how these cells behave when they are in the brain, it gives us information about how they could be behaving when they are in the brain’s environment.
The science of stem cells is still very new, and could change with additional discoveries, but researchers have learned enough to be able to describe how neural stem cells generate the other cells of the brain. They call it a stem cell’s lineage and it is similar in principle to a family tree.
Neural stem cells increase by dividing in two and producing either two new stem cells, or two early progenitor cells, or one of each.
When a stem cell divides to produce another stem cell, it is said to self-renew. This new cell has the potential to make more stem cells.
When a stem cell divides to produce an early progenitor cell, it is said to differentiate. Differentiation means that the new cell is more specialized in form and function. An early progenitor cell does not have the potential of a stem cell to make many different types of cells. It can only make cells in its particular lineage.
Early progenitor cells can self-renew or go in either of two ways. One type will give rise to astrocytes. The other type will ultimately produce neurons or oligodendrocytes.
Source: Brain Basics: The Life and Death of a Neuron | National Institute of Neurological Disorders and Stroke
Neural Tissue. See a full animation of this medical topic.
Image by Blausen.com staff (2014). \"Medical gallery of Blausen Medical 2014\". WikiJournal of Medicine 1 (2). DOI:10.15347/wjm/2014.010. ISSN 2002-4436
Blausen.com staff (2014). \"Medical gallery of Blausen Medical 2014\". WikiJournal of Medicine 1 (2). DOI:10.15347/wjm/2014.010. ISSN 2002-4436
Migration
Anatomy of a Neuron
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Anatomy of a Neuron
Anatomy of a Neuron
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Migration
Once a neuron is born it has to travel to the place in the brain where it will do its work.
How does a neuron know where to go? What helps it get there?
Scientists have seen that neurons use at least two different methods to travel:
Some neurons migrate by following the long fibers of cells called radial glia. These fibers extend from the inner layers to the outer layers of the brain. Neurons glide along the fibers until they reach their destination.
Neurons also travel by using chemical signals. Scientists have found special molecules on the surface of neurons -- adhesion molecules -- that bind with similar molecules on nearby glial cells or nerve axons. These chemical signals guide the neuron to its final location.
Not all neurons are successful in their journey. Scientists think that only a third reach their destination. Some cells die during the process of neuronal development.
Some neurons survive the trip, but end up where they shouldn’t be. Mutations in the genes that control migration create areas of misplaced or oddly formed neurons that can cause disorders such as childhood epilepsy. Some researchers suspect that schizophrenia and the learning disorder dyslexia are partly the result of misguided neurons.
Source: Brain Basics: The Life and Death of a Neuron | National Institute of Neurological Disorders and Stroke
Each neuron begins life as a progenitor cell. These cells form in the central part of the developing brain and then move outward along the supportive glial cells until they reach their pre-programmed location in the brain. As a progenitor cell reaches its destination, its status changes and it now is \"committed\" to become one of numerous types of neurons. The neuron begins to grow axons and dendrites. These fibers will eventually form a synapse, or connection, with those of other neurons. Once the neuron has taken on its specialized function, it is considered \"differentiated.\"
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Neuron types and their functionality
Neuron types and their functionality : The nerve cell is the hub for all of the activity that occurs in the brain, and the connections between neurons create a living, dynamic framework for everything that we see, hear, taste, smell, touch and experience.
Rat primary cortical neuron culture, deconvolved z-stack overlay
Image by ZEISS Microscopy
Rat primary cortical neuron culture, deconvolved z-stack overlay
Image of rat primary cortical neurons in culture using ZEISS Celldiscoverer 7 with 40x/0.95 Autocorr objective. Antibody-staining of bIII-tubulin (Cy2) and DCX (Cy3). Nuclei Dapi-stained, mounted on standard slides with coverslip. Image shows a projection (EDF) of a 4 channel z-stack with deconvolved images using GPU-based deconvolution. www.zeiss.com/celldiscoverer
Image by ZEISS Microscopy
Differentiation
Once a neuron reaches its destination, it has to settle in to work. This final step of differentiation is the least well-understood part of neurogenesis.
Neurons are responsible for the transport and uptake of neurotransmitters - chemicals that relay information between brain cells.
Depending on its location, a neuron can perform the job of a sensory neuron, a motor neuron, or an interneuron, sending and receiving specific neurotransmitters.
In the developing brain, a neuron depends on molecular signals from other cells, such as astrocytes, to determine its shape and location, the kind of transmitter it produces, and to which other neurons it will connect. These freshly born cells establish neural circuits - or information pathways connecting neuron to neuron - that will be in place throughout adulthood.
But in the adult brain, neural circuits are already developed and neurons must find a way to fit in. As a new neuron settles in, it starts to look like surrounding cells. It develops an axon and dendrites and begins to communicate with its neighbors.
Source: Brain Basics: The Life and Death of a Neuron | National Institute of Neurological Disorders and Stroke
Additional Materials (2)
Cells of the Nervous System
This illustration shows a prototypical neuron, which is being myelinated.
Image by CNX Openstax
Healthy Neuron
Image by National Institute on Aging/National Institutes of Health
Cells of the Nervous System
CNX Openstax
Healthy Neuron
National Institute on Aging/National Institutes of Health
Death
3D Visualization of a young neuron
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3D Visualization of a young neuron
3D Visualization of a young neuron from Confocal Laser Scanner surrounded by the vascular supply
Image by TheVisualMD
Death
Although neurons are the longest living cells in the body, large numbers of them die during migration and differentiation.
The lives of some neurons can take abnormal turns. Some diseases of the brain are the result of the unnatural deaths of neurons.
- In Parkinson’s disease, neurons that produce the neurotransmitter dopamine die off in the basal ganglia, an area of the brain that controls body movements. This causes difficulty initiating movement.
- In Huntington’s disease, a genetic mutation causes over-production of a neurotransmitter called glutamate, which kills neurons in the basal ganglia. As a result, people twist and writhe uncontrollably.
- In Alzheimer’s disease, unusual proteins build up in and around neurons in the neocortex and hippocampus, parts of the brain that control memory. When these neurons die, people lose their capacity to remember and their ability to do everyday tasks. Physical damage to the brain and other parts of the central nervous system can also kill or disable neurons.
- Blows to the brain, or the damage caused by a stroke, can kill neurons outright or slowly starve them of the oxygen and nutrients they need to survive.
- Spinal cord injury can disrupt communication between the brain and muscles when neurons lose their connection to axons located below the site of injury. These neurons may still live, but they lose their ability to communicate.
Source: Brain Basics: The Life and Death of a Neuron | National Institute of Neurological Disorders and Stroke
Additional Materials (4)
Synapse of Neuron
Chemical synapses are specialized junctions through which the cells of the nervous system signal to each other. Chemical synapses allow the neurons of the central nervous system to form interconnected neural circuits. They are thus crucial to the biological computations that underlie perception and thought. They provide the means through which the nervous system connects to and controls the other systems of the body.
Image by TheVisualMD
Synapse of Neuron
Chemical synapses are specialized junctions through which the cells of the nervous system signal to each other. Chemical synapses allow the neurons of the central nervous system to form interconnected neural circuits. They are thus crucial to the biological computations that underlie perception and thought. They provide the means through which the nervous system connects to and controls the other systems of the body.
Image by TheVisualMD
Microtubule Disassembly with Tau
The long axons that extend from a nerve's cell body to connect with other neurons maintain their shape thanks to internal structures known as microtubules. As Alzheimer's progresses, however, the tight structure of these microtubules starts to fall apart. A normal component of nerve cells, a protein called tau, undergoes pathologic changes which are associated with neurofibrillary tangle formation. These neurofibrillary tangles accumulate in the neuron's cell body and, combined with growing deposits of amyloid plaques, start to disrupt the function of nerve cells. These cells eventually die, leading to loss of essential brain functions.
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Interneurons
Interneurons create circuits that enable communication between sensory or motor neurons and the central nervous system. Here, numerous subpopulations of interneurons (green) are present in a section of a mouse hippocampus.
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Neurons
Neurons are the cells that make up nervous tissue. They are responsible for the chemical and electrical signals that communicate information about sensations, that produce movements, and induce thought processes within the brain. Learn more about neurons and how they work.