Pharmacology of drugs acting on peripheral nervous system
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he nervous system is responsible for controlling the functions of the human body, analyzing incoming stimuli, and integrating internal and external responses. The nervous system is composed of the central nervous system (CNS; the brain and spinal cord) and the peripheral nervous system (PNS). The PNS is composed of sensory receptors that bring information into the CNS and motor nerves that carry information away from the CNS to facilitate response to stimuli. The autonomic nervous system, which is discussed in Chapter 29, uses components of the CNS and PNS to regulate automatic or unconscious responses to stimuli. The structural unit of the nervous system is the nerve cell, or neuron. The billions of nerve cells that make up the nervous system are organized to allow movement realization of various sensations; response to internal and external stimuli; and learning, thinking, and emotion. The mechanisms that are involved in all of these processes are not clearly understood. The actions of drugs that are used to affect the functioning of the nerves and the responses that these drugs cause throughout the nervous system provide some of the current theories about the workings of the nervous system. PHYSIOLOGY OF THE NERVOUS SYSTEM The nervous system operates through the use of electrical impulses and chemical messengers to transmit information throughout the body and to respond to internal and external stimuli. The properties and functions of the neuron provide the basis for all nervous system function. Neurons As noted previously, the neuron is the structural unit of the nervous system. The human body contains about 14 billion neurons. About 10 billion of these are located in the brain, and the remainder make up the spinal cord and PNS. Neurons have several distinctive cellular features (Figure 19.1). Each neuron is made up of a cell body, or soma, which contains the cell nucleus, cytoplasm, and various granules and other particles. Short, branch-like projections that cover most of the surface of a neuron are known as dendrites. These structures, which provide increased surface DendritesNucleusAxon Neurilemma Myelin sheath area for the neuron, bring information into the neuron from other neurons. One end of the nerve body extends into a long process that does not branch out until the very end of the process. This elongated process is called the nerve axon, and it emerges from the soma at the axon hillock, a slightly enlarged area of the soma from which the axon emerges. The axon of a nerve can be extremely tiny, or it can extend for several feet. The axon carries information from a nerve to be transmitted to effector cells—cells stimulated by a nerve, which may include a muscle, gland, or another nerve. This transmission occurs at the end of the axon, where the axon branches out in what is called the axon terminal. The axons of many nerves are packed closely together in the nervous system and look like cable or fiber tracts. Afferent fibers are nerve axons that run from peripheral receptors into the CNS. In contrast, efferent fibers are nerve axons that carry nerve impulses from the CNS to the periphery to stimulate muscles or glands. (An easy way to remember the difference between afferent and efferent is to recall that efferent fibers exit from the CNS.) It is currently thought that neurons are unable to reproduce; so, if nerves are destroyed, they are lost. If dendrites and axons are lost, nerves regenerate those structures; however, for this regeneration to occur, the soma and the axon hillock must remain intact. For a clinical example, consider a person who has closed a car door on his or her finger. Sensation and movement may be lost or limited for a certain period, but because the nerve bodies for most of the nerves in the hand are located in ganglia (groups of nerve bodies) in the wrist, they are able to regenerate the damaged axon or dendrites. Over time, sensation and full movement should return. Research on possible ways to stimulate the reproduction of nerves is under way. Although scientists have used nerve growth factor with fetal cell implants to stimulate some nerve growth, it is currently assumed that nerves are unable to reproduce.