<P> In order to enable fast and efficient transduction of electrical signals in the nervous system, certain neuronal axons are covered with myelin sheaths . Myelin is a multilamellar membrane that enwraps the axon in segments separated by intervals known as nodes of Ranvier . It is produced by specialized cells: Schwann cells exclusively in the peripheral nervous system, and oligodendrocytes exclusively in the central nervous system . Myelin sheath reduces membrane capacitance and increases membrane resistance in the inter-node intervals, thus allowing a fast, saltatory movement of action potentials from node to node . Myelination is found mainly in vertebrates, but an analogous system has been discovered in a few invertebrates, such as some species of shrimp . Not all neurons in vertebrates are myelinated; for example, axons of the neurons comprising the autonomous nervous system are not, in general, myelinated . </P> <P> Myelin prevents ions from entering or leaving the axon along myelinated segments . As a general rule, myelination increases the conduction velocity of action potentials and makes them more energy - efficient . Whether saltatory or not, the mean conduction velocity of an action potential ranges from 1 meter per second (m / s) to over 100 m / s, and, in general, increases with axonal diameter . </P> <P> Action potentials cannot propagate through the membrane in myelinated segments of the axon . However, the current is carried by the cytoplasm, which is sufficient to depolarize the first or second subsequent node of Ranvier . Instead, the ionic current from an action potential at one node of Ranvier provokes another action potential at the next node; this apparent "hopping" of the action potential from node to node is known as saltatory conduction . Although the mechanism of saltatory conduction was suggested in 1925 by Ralph Lillie, the first experimental evidence for saltatory conduction came from Ichiji Tasaki and Taiji Takeuchi and from Andrew Huxley and Robert Stämpfli . By contrast, in unmyelinated axons, the action potential provokes another in the membrane immediately adjacent, and moves continuously down the axon like a wave . </P> <P> Myelin has two important advantages: fast conduction speed and energy efficiency . For axons larger than a minimum diameter (roughly 1 micrometre), myelination increases the conduction velocity of an action potential, typically tenfold . Conversely, for a given conduction velocity, myelinated fibers are smaller than their unmyelinated counterparts . For example, action potentials move at roughly the same speed (25 m / s) in a myelinated frog axon and an unmyelinated squid giant axon, but the frog axon has a roughly 30-fold smaller diameter and 1000-fold smaller cross-sectional area . Also, since the ionic currents are confined to the nodes of Ranvier, far fewer ions "leak" across the membrane, saving metabolic energy . This saving is a significant selective advantage, since the human nervous system uses approximately 20% of the body's metabolic energy . </P>

During an action potential of a neuron what directly causes the different channels to open and close