6.4: Nervous System Organization

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Central Nervous System

Recall that there are two main subdivisions of the nervous system - the central nervous system and the peripheral nervous system - and that the two parts of the CNS are the brain and the spinal cord (Figure 6.1). The neurons in different regions of these two organs are specialized to contribute to one or more of the main functions of the nervous system. For example, certain areas of gray matter in the brain monitor conditions such as temperature and the level of CO₂, others start impulses that stimulate muscles to contract, and still other areas are for remembering. Myelinated axons in the white matter allow regions of gray matter to communicate with each other.

Peripheral Nervous System

Sensory Portion

The sensory portion of the peripheral nervous system contains sensory neurons, which monitor body conditions outside the brain and spinal cord. They also monitor conditions on the surface of the body and in its surroundings. Each type of sensory neuron is designed to monitor only one type of condition. For example, one kind responds to changes in temperature, while another is activated by pressure. Those in the nose and on the tongue respond to chemicals.

Most sensory neurons are long thin cells that extend through nerves from the regions they monitor to the brain or spinal cord. For example, sensory neurons from the fingertips extend through nerves in the arm all the way up to the middle of the back, where they enter the spinal cord. Once a sensory neuron performs reception in response to a condition, it carries impulses to communicate information about that condition to the brain or spinal cord (Figure 6.5).

Sensory neurons that do not have myelin release two substances (i.e., calcitonin gene-related peptides, substance P) at sites of wound injury. The combined effects are providing adequate inflammation while promoting healing.

Motor Portion

Figure 6.20a Peripheral nervous system; somatic portion (Copyright 2020: Augustine G. DiGiovanna, Ph.D., Salisbury University, Maryland. Used with permission.)

Figure 6.20b Peripheral nervous system; sympathetic portion (Copyright 2020: Augustine G. DiGiovanna, Ph.D., Salisbury University, Maryland. Used with permission.)

Figure 6.20c Peripheral nervous system; parasympathetic portion (Copyright 2020: Augustine G. DiGiovanna, Ph.D., Salisbury University, Maryland. Used with permission.)

The motor portion of the PNS consists of motor neurons that control the activities of muscles and glands. Somatic motor neurons control muscles that are attached to bones. Usually there is voluntary control of these muscles, although sometimes the nervous system causes them to contract involuntarily.

Somatic motor neurons extend from the brain and spinal cord, through nerves, to the muscles they control (Figure 6.20a). For example, the motor neurons that enter and stimulate the muscles in the lower leg begin in the spinal cord just below the middle of the back.

Other motor neurons make up the autonomic portion of the PNS. Autonomic motor neurons control many of the functions of the integumentary, circulatory, respiratory, digestive, urinary, and reproductive systems by regulating many glands and also muscles that are usually not under voluntary control. The sweat glands and salivary glands, for example, are under autonomic control. Muscles under autonomic control include the heart and the smooth muscle in the walls of blood vessels, the bronchi, the stomach, and the urinary bladder.

Autonomic motor neurons are of two types: sympathetic and parasympathetic (Figure 6.20b, Figure 6.20c). Though a few structures (e.g., sweat glands, skin vessels) are controlled by only one type of autonomic motor neuron, most receive both sympathetic and parasympathetic motor neurons. In places where both types are present, one type of autonomic motor neuron stimulates the structure and the other type inhibits it. By balancing the amount of stimulation and inhibition, the autonomic nervous system can precisely control the speed and strength of activity of a structure. For example, sympathetic motor neurons increase the rate and strength of the heartbeat while parasympathetic motor neurons decrease them. By automatically adjusting the ratio between sympathetic and parasympathetic impulses, the autonomic nervous system varies the rate and strength of the heartbeat as the amount of blood flow needed by the body fluctuates.

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