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{{Biopsy}}
 
{{Biopsy}}
   
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{{Neuron map|Axon}}
An '''axon''', or '''nerve fiber''', is a long slender projection of a nerve cell, or [[neuron]], that conducts [[action potential|electrical impulses]] away from the neuron's [[cell body]] or soma. Axons are in effect the primary transmission lines of the [[nervous system]], and as bundles they help make up [[nerve]]s. Individual axons are microscopic in diameter - typically about one [[micrometre]] across - but may extend to [[macroscopic]] lengths. The longest axons in the human body, for example, are those of the [[sciatic nerve]], which run from the base of the [[spine (anatomy)|spine]] to the big toe of each foot. These single-cell fibers may extend a metre or even longer.
 
   
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An '''axon''' or '''nerve fiber''', is a long, slender projection
In [[vertebrate]]s, the axons of many neurons are sheathed in [[myelin]], which is formed by either of two types of [[glia|glial cells]]: [[Schwann cell]]s ensheathing [[PNS|peripheral]] neurons and [[oligodendrocyte]]s insulating those of the [[central nervous system]]. Along myelinated nerve fibers, gaps in the sheath known as [[nodes of Ranvier]] occur at evenly-spaced intervals, enabling an especially rapid mode of electrical impulse propagation called [[saltatory conduction|saltation]]. The demyelination of axons is what causes the multitude of neurological symptoms found in the disease [[Multiple Sclerosis]].
 
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of a nerve cell, or [[neuron]], that conducts [[action potential|electrical impulses]]
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away from the neuron's [[cell body]] or soma.
   
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== Anatomy ==
 
Axons are in effect the primary transmission lines of the [[nervous system]], and as bundles they help make up [[nerve]]s. Individual axons are microscopic in diameter - typically about one [[micrometre]] across (1μm) - but may extend to [[macroscopic]] (>1mm) lengths. The longest axons in the human body, for example, are those of the [[sciatic nerve]], which run from the base of the [[spine (anatomy)|spine]] to the big toe of each foot. These single-cell fibers of the [[sciatic nerve]] may extend a meter or even longer.
  +
 
In [[vertebrate]]s, the axons of many neurons are sheathed in [[myelin]], which is formed by either of two types of [[glia|glial cells]]: [[Schwann cell]]s ensheathing [[PNS|peripheral]] neurons and [[oligodendrocyte]]s insulating those of the [[central nervous system]]. Along myelinated nerve fibers, gaps in the sheath known as [[nodes of Ranvier]] occur at evenly-spaced intervals, enabling an especially rapid mode of electrical impulse propagation called [[saltatory conduction|saltation]]. The demyelination of axons is what causes the multitude of neurological symptoms found in the disease [[Multiple Sclerosis]].
 
The axons of some neurons branch to form [[axon collateral]]s, along which the bifurcated impulse travels simultaneously to signal more than one other cell.
 
The axons of some neurons branch to form [[axon collateral]]s, along which the bifurcated impulse travels simultaneously to signal more than one other cell.
   
  +
==Physiology==
==Growth & Development==
 
Growing axons move through their environment via the [[growth cone]], which is at the tip of the axon. The growth cone has a broad sheet like extension called [[lamellipodia]] which contain protrusions called [[filopodia]]. The filopodia are the mechanism by which the entire process adheres to surfaces and explores the surrounding environment. [[Actin]] plays a major role in the mobility of this system.
 
   
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The [[physiology|physiology]] of axons has been studied extensively. Hodgkin and Huxley performed pioneering work with giant squid axons, leading the formulation of the [[Hodgkin-Huxley Model|Hodgkin-Huxley Model]]. The formulas detailing axonal conductance were extended to vertebrates in the Frankenhaeuser-Huxley equations. Erlanger and Gasser later developed a classification system for peripheral nerve fibers, based on axonal conduction velocity, mylenation, fiber size etc. For example, there are slow-conducting unmyelinated [[C fiber|C fibers]] and faster-conducting myelinated [[Aδ fiber|Aδ fibers]]. More complex mathematical modeling continues to be done today. Our understanding of the biochemical basis for action potential propagation has advanced, and now includes many details about individual [[Ion channel|ion channels]].
Environments with high levels of [[cell adhesion molecule]]s or CAM's create an ideal environment for axonal growth. This seems to provide a "sticky" surface for axons to grow along. Examples of CAM's specific to neural systems include [[N-CAM]], neuroglial CAM or [[NgCAM]], [[TAG-1]], [[MAG]], and [[Dicyclohexylcarbodiimide|DCC]], all of which are part of the [[immunoglobulin]] superfamily. Another set of molecules called [[extracellular matrix adhesion molecule]]s also provide a sticky substrate for axons to grow along. Examples of these molecules include [[laminin]], [[fibronectin]], [[tenascin]], and [[perlecan]]. Some of these are surface bound to cells and thus act as short range attractants or repellants. Others are difusible ligands and thus can have long range effects.
 
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==Growth and development==
 
Growing axons move through their environment via the [[growth cone]], which is at the tip of the axon. The growth cone has a broad sheet like extension called [[lamellipodia]] which contain protrusions called [[filopodia]]. The filopodia are the mechanism by which the entire process adheres to surfaces and explores the surrounding environment. [[Actin]] plays a major role in the mobility of this system.
 
Environments with high levels of [[cell adhesion molecule]]s or CAM's create an ideal environment for axonal growth. This seems to provide a "sticky" surface for axons to grow along. Examples of CAM's specific to neural systems include [[Neural Cell Adhesion Molecule|N-CAM]], neuroglial CAM or [[NgCAM]], [[TAG-1]], [[MAG (neural)|MAG]], and [[Dicyclohexylcarbodiimide|DCC]], all of which are part of the [[immunoglobulin]] superfamily. Another set of molecules called [[extracellular matrix adhesion molecule]]s also provide a sticky substrate for axons to grow along. Examples of these molecules include [[laminin]], [[fibronectin]], [[tenascin]], and [[perlecan]]. Some of these are surface bound to cells and thus act as short range attractants or repellents. Others are difusible ligands and thus can have long range effects.
   
 
Cells called [[guidepost cells]] assist in the guidance of neuronal axon growth. These cells are typically other, sometimes immature, neurons.
 
Cells called [[guidepost cells]] assist in the guidance of neuronal axon growth. These cells are typically other, sometimes immature, neurons.
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==History==
 
==History==
 
Some of the first intracellular recordings in a nervous system were made in the late 1930's by K. Cole and H. Curtis. [[Alan Hodgkin]] and [[Andrew Huxley]] also employed the [[squid giant axon]] (1939) and by 1952 they had obtained a full quantitative description of the ionic basis of the action potential.
 
Some of the first intracellular recordings in a nervous system were made in the late 1930's by K. Cole and H. Curtis. [[Alan Hodgkin]] and [[Andrew Huxley]] also employed the [[squid giant axon]] (1939) and by 1952 they had obtained a full quantitative description of the ionic basis of the action potential.
Hodgkin and Huxley were awarded jointly the [[Nobel Prize in Physiology or Medicine|Nobel Prize]] for this work in 1963.
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Hodgkin and Huxley were awarded jointly the [[Nobel Prize in Physiology or Medicine|Nobel Prize]] for this work in [[1963]].
   
 
==See also==
 
==See also==
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== External links ==
 
== External links ==
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* {{OklahomaHistology|3_09}} - "Slide 3 [[Spinal cord]]"
* http://www.sfn.org/wrensite/projects/patch_clamp/index.htm
 
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{{Nervous tissue}}
   
 
[[Category:Neurons]]
 
[[Category:Neurons]]
[[Category:Neuroscience]]
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[[Category:Neurophysiology]]
   
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{{enWP| Axon}}
 
{{enWP| Axon}}

Revision as of 08:40, 7 June 2007

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Axon
Structure of a typical neuron


An axon or nerve fiber, is a long, slender projection of a nerve cell, or neuron, that conducts electrical impulses away from the neuron's cell body or soma.

Anatomy

Axons are in effect the primary transmission lines of the nervous system, and as bundles they help make up nerves. Individual axons are microscopic in diameter - typically about one micrometre across (1μm) - but may extend to macroscopic (>1mm) lengths. The longest axons in the human body, for example, are those of the sciatic nerve, which run from the base of the spine to the big toe of each foot. These single-cell fibers of the sciatic nerve may extend a meter or even longer.

In vertebrates, the axons of many neurons are sheathed in myelin, which is formed by either of two types of glial cells: Schwann cells ensheathing peripheral neurons and oligodendrocytes insulating those of the central nervous system. Along myelinated nerve fibers, gaps in the sheath known as nodes of Ranvier occur at evenly-spaced intervals, enabling an especially rapid mode of electrical impulse propagation called saltation. The demyelination of axons is what causes the multitude of neurological symptoms found in the disease Multiple Sclerosis. The axons of some neurons branch to form axon collaterals, along which the bifurcated impulse travels simultaneously to signal more than one other cell.

Physiology

The physiology of axons has been studied extensively. Hodgkin and Huxley performed pioneering work with giant squid axons, leading the formulation of the Hodgkin-Huxley Model. The formulas detailing axonal conductance were extended to vertebrates in the Frankenhaeuser-Huxley equations. Erlanger and Gasser later developed a classification system for peripheral nerve fibers, based on axonal conduction velocity, mylenation, fiber size etc. For example, there are slow-conducting unmyelinated C fibers and faster-conducting myelinated Aδ fibers. More complex mathematical modeling continues to be done today. Our understanding of the biochemical basis for action potential propagation has advanced, and now includes many details about individual ion channels.

Growth and development

Growing axons move through their environment via the growth cone, which is at the tip of the axon. The growth cone has a broad sheet like extension called lamellipodia which contain protrusions called filopodia. The filopodia are the mechanism by which the entire process adheres to surfaces and explores the surrounding environment. Actin plays a major role in the mobility of this system. Environments with high levels of cell adhesion molecules or CAM's create an ideal environment for axonal growth. This seems to provide a "sticky" surface for axons to grow along. Examples of CAM's specific to neural systems include N-CAM, neuroglial CAM or NgCAM, TAG-1, MAG, and DCC, all of which are part of the immunoglobulin superfamily. Another set of molecules called extracellular matrix adhesion molecules also provide a sticky substrate for axons to grow along. Examples of these molecules include laminin, fibronectin, tenascin, and perlecan. Some of these are surface bound to cells and thus act as short range attractants or repellents. Others are difusible ligands and thus can have long range effects.

Cells called guidepost cells assist in the guidance of neuronal axon growth. These cells are typically other, sometimes immature, neurons.

History

Some of the first intracellular recordings in a nervous system were made in the late 1930's by K. Cole and H. Curtis. Alan Hodgkin and Andrew Huxley also employed the squid giant axon (1939) and by 1952 they had obtained a full quantitative description of the ionic basis of the action potential. Hodgkin and Huxley were awarded jointly the Nobel Prize for this work in 1963.

See also

External links


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