Difference between revisions of "Somatic nervous system" - New World Encyclopedia
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==Overview== | ==Overview== | ||
| − | The somatic nervous system is one of two subsystems of the [[peripheral nervous system]], the other being the [[autonomic nervous system]]. The | + | The somatic nervous system is one of two subsystems of the [[peripheral nervous system]], the other being the [[autonomic nervous system]]. The autonomic nervous system is responsible for maintenance functions ([[metabolism]], cardiovascular activity, temperature regulation, digestion) that have a reputation for being outside of conscious control. It consists of nerves in cardiac [[muscle]], smooth muscle, and exocrine and [[endocrine system|endocrine]] glands. The somatic nervous system consists of cranial and spinal nerves that innervate skeletal muscle tissue and are more under voluntary control (Anissimov 2006; Towle 1989), as well as the sensory receptors. |
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| − | The system includes all the [[neuron]]s connected with [[muscle]]s, [[skin]] and [[Sensory system|sense organs]]. The somatic nervous system consists of [[efferent nerve]]s responsible for sending brain signals for [[muscle contraction]]. | + | The somatic nervous system includes all the [[neuron]]s connected with [[muscle]]s, [[skin]], and [[Sensory system|sense organs]]. The somatic nervous system processes sensory information and controls all [[voluntary muscle|voluntary muscular]] systems within the body, with the exception of [[reflex arc]]s. The somatic nervous system consists of [[efferent nerve]]s responsible for sending brain signals for [[muscle contraction]]. |
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==Nerve signal transmission== | ==Nerve signal transmission== | ||
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The basic route of [[nerve signal]]s within the [[efferent]] somatic nervous system involves a sequence that begins in the upper [[Cell (biology)|cell bodies]] of [[motor neuron]]s ([[upper motor neuron]]s) within the [[Brodmann area 4|precentral gyrus]] (which approximates the [[primary motor cortex]]). Stimuli from the precentral gyrus are transmitted from upper motor neurons and down the [[corticospinal tract]], via [[axon]]s to control skeletal (voluntary) muscles. These stimuli are conveyed from upper motor neurons through the [[ventral horn]] of the [[spinal cord]], and across [[synapse]]s to be received by the [[sensory receptor]]s of [[alpha motor neuron]] (large [[lower motor neuron]]s) of the [[brainstem]] and [[spinal cord]]. | The basic route of [[nerve signal]]s within the [[efferent]] somatic nervous system involves a sequence that begins in the upper [[Cell (biology)|cell bodies]] of [[motor neuron]]s ([[upper motor neuron]]s) within the [[Brodmann area 4|precentral gyrus]] (which approximates the [[primary motor cortex]]). Stimuli from the precentral gyrus are transmitted from upper motor neurons and down the [[corticospinal tract]], via [[axon]]s to control skeletal (voluntary) muscles. These stimuli are conveyed from upper motor neurons through the [[ventral horn]] of the [[spinal cord]], and across [[synapse]]s to be received by the [[sensory receptor]]s of [[alpha motor neuron]] (large [[lower motor neuron]]s) of the [[brainstem]] and [[spinal cord]]. | ||
Revision as of 22:27, 7 November 2008
The somatic nervous system, or voluntary nervous system, is that part of the peripheral nervous system that regulates body movement through control of skeletal (voluntary) muscles and also relates the organism with the environment through the reception of external stimuli, such as through the senses of vision, hearing, taste, and smell. The somatic nervous system controls such voluntary actions as walking and smiling through the use of efferent motor nerves, in contrast with the function of the autonomic nervous system, which largely acts independent of conscious control in innervating cardiac muscle and exocrine and endocrine glands.
Overview
The somatic nervous system is one of two subsystems of the peripheral nervous system, the other being the autonomic nervous system. The autonomic nervous system is responsible for maintenance functions (metabolism, cardiovascular activity, temperature regulation, digestion) that have a reputation for being outside of conscious control. It consists of nerves in cardiac muscle, smooth muscle, and exocrine and endocrine glands. The somatic nervous system consists of cranial and spinal nerves that innervate skeletal muscle tissue and are more under voluntary control (Anissimov 2006; Towle 1989), as well as the sensory receptors.
The somatic nervous system includes all the neurons connected with muscles, skin, and sense organs. The somatic nervous system processes sensory information and controls all voluntary muscular systems within the body, with the exception of reflex arcs. The somatic nervous system consists of efferent nerves responsible for sending brain signals for muscle contraction.
Nerve signal transmission
The basic route of nerve signals within the efferent somatic nervous system involves a sequence that begins in the upper cell bodies of motor neurons (upper motor neurons) within the precentral gyrus (which approximates the primary motor cortex). Stimuli from the precentral gyrus are transmitted from upper motor neurons and down the corticospinal tract, via axons to control skeletal (voluntary) muscles. These stimuli are conveyed from upper motor neurons through the ventral horn of the spinal cord, and across synapses to be received by the sensory receptors of alpha motor neuron (large lower motor neurons) of the brainstem and spinal cord.
Upper motor neurons release a neurotransmitter, acetylcholine, from their axon terminal knobs, which are received by nicotinic receptors of the alpha motor neurons. In turn, alpha motor neurons relay the stimuli received down their axons via the ventral root of the spinal cord. These signals then proceed to the neuromuscular junctions of skeletal muscles.
From there, acetylcholine is released from the axon terminal knobs of alpha motor neurons and received by postsynaptic receptors (Nicotinic acetylcholine receptors) of muscles, thereby relaying the stimulus to contract muscle fibers.
Vertebrate and invertebrate differences
In invertebrates, depending on the neurotransmitter released and the type of receptor it binds, the response in the muscle fiber could either be excitatory or inhibitory. For vertebrates, however, the response of a muscle fiber to a neurotransmitter (always acetylcholine (ACh)) can only be excitatory or, in other words, contractile. jkoj
Reflex arcs
A reflex arc is an automatic reaction that allows an organism to protect itself reflexively when an imminent danger is perceived. In response to certain stimuli, such as touching a hot surface, these reflexes are 'hard wired' through the spinal cord. A reflexive impulse travels up afferent nerves, through a spinal interneuron, and back down appropriate efferent nerves.
See also
ReferencesISBN links support NWE through referral fees
- Anissimov, M. 2007. How does the nervous system work? Conjecture Corporation: Wise Geek. Retrieved May 13, 2007.
- Chamberlin, S. L., and B. Narins. 2005. The Gale Encyclopedia of Neurological Disorders. Detroit: Thomson Gale. ISBN 078769150X
- Towle, A. 1989. Modern Biology. Austin, TX: Holt, Rinehart and Winston. ISBN 0030139198
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