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Upon completion of this chapter, the student should be able to answer the following questions:
What are the similarities and differences in the general organizations of the parasympathetic and sympathetic systems?
What are the respective actions of the parasympathetic and sympathetic innervation of the eye, and what symptoms arise when the parasympathetic or sympathetic innervation is lost?
What are the changes in the balance of parasympathetic and sympathetic activity to the bladder that occur during micturation?
What is meant by a “servomechanism”?
What are the specific feedback loops that regulate body temperature, feeding and body weight, and water intake?
What is the role of the hypothalamus in each of these feedback loops?
The main function of the autonomic nervous system is to assist the body in maintaining a stable internal environment (homeostasis). When internal stimuli signal that regulation of the body’s environment is required, the central nervous system (CNS) and its autonomic outflow issue commands that lead to compensatory actions. For example, a sudden increase in systemic blood pressure activates the baroreceptors, which in turn modify the activity of the autonomic nervous system so that the blood pressure is lowered toward its previous level (see Chapter 17 ).
The autonomic nervous system has both sensory and motor divisions. The motor division is further divided into the sympathetic and parasympathetic divisions. Because much of the autonomic nervous system’s actions relate to control of the viscera, it is sometimes called the visceral nervous system .
In service of its homeostatic function, the autonomic nervous system mediates visceral reflexes (e.g., the gastrocolic reflex, where stomach distention triggers peristalsis in the intestines) and provides sensory information to the CNS of the perception of the state of our viscera, a percept known to anyone who has eaten too much at a meal. More generally, activation of autonomic receptors can evoke a variety of sensory experiences such as pain, hunger, thirst, nausea, and a sense of visceral distention; these perceptions can then lead to compensatory voluntary behaviors that assist in maintaining homeostasis.
In addition to its central role in homeostasis, the autonomic nervous system also participates in appropriate and coordinated responses to external stimuli that are required for the optimal functioning of the somatic nervous system in performing voluntary behaviors. For example, the autonomic nervous system helps regulate pupil size in response to different intensities of ambient light, thus helping the visual system to operate over a large range of light intensity.
In this chapter, the enteric nervous system is also considered part of the autonomic nervous system, although it is sometimes considered a separate entity (see also Chapter 27 ). In addition, because the autonomic nervous system is under CNS control, the central components of the autonomic nervous system are discussed in this chapter. These central components include the hypothalamus and higher levels of the limbic system, which are associated with emotions (see Chapter 10 ) and with many visceral types of behavior (e.g., feeding, drinking, thermoregulation, reproduction, defense, and aggression) that have survival value.
The sensory autonomic neurons are located in the dorsal root ganglia and in the cranial nerve ganglia. Like the other neurons of the dorsal root ganglia, they are pseudounipolar cells with a peripheral axonal branch extended to one of the viscera and a central branch that enters the CNS. With regard to autonomic motor output, both the sympathetic and parasympathetic nervous systems use a two-neuron motor pathway, which consists of a preganglionic neuron, whose cell body is located in the CNS, and a postganglionic neuron, whose cell body is located in one of the autonomic ganglia ( Figs. 11.1 and 11.2 ). The targets of this motor pathway are smooth muscle, cardiac muscle, and glands. The enteric nervous system includes the neurons and nerve fibers in the myenteric and submucosal plexuses, which are located in the wall of the gastrointestinal tract.
The sympathetic and parasympathetic nervous systems often regulate organ function through opposing actions. To highlight this contrast, the sympathetic and parasympathetic systems are sometimes referred to as the “fight or flight” and the “rest and digest” systems, respectively. Indeed, the fight-or-flight response to a threat to the organism reflects an intense activation of the sympathetic nervous system, which leads to a variety of responses, including increased heart rate and blood pressure, redistribution of blood to the muscles, decreased peristalsis and gastrointestinal secretions, pupil dilation, and sweating.
However, under most conditions, the two parts of the autonomic control system work in a coordinated manner—sometimes acting reciprocally and sometimes synergistically—to regulate visceral function. Furthermore, not all visceral structures are innervated by both systems. For example, the smooth muscles and glands in the skin and most of the blood vessels in the body receive sympathetic innervation exclusively; only a small fraction of the blood vessels have parasympathetic innervation. Indeed, the parasympathetic nervous system innervates not the body wall, but only structures in the head and in the thoracic, abdominal, and pelvic cavities.
The sympathetic preganglionic neurons are located in the thoracic and upper lumbar segments of the spinal cord. For this reason, the sympathetic nervous system is sometimes referred to as the thoracolumbar division of the autonomic nervous system. Specifically, sympathetic preganglionic neurons are concentrated in the intermediolateral cell column (lateral horn) in the thoracic and upper lumbar segments of the spinal cord (see Fig. 11.2 ). Some neurons may also be found in the C8 segment. In addition to the intermediolateral cell column, groups of sympathetic preganglionic neurons are found in other locations, including the lateral funiculus, the intermediate gray matter, and the gray matter dorsal to the central canal. Sympathetic postganglionic neurons are generally found in the paravertebral or prevertebral ganglia. The paravertebral ganglia form two sets of ganglia, each lateral to one side of the vertebral column. The individual ganglia on each side are linked by longitudinally running axons that form a sympathetic trunk (see Figs. 11.1 and 11.2 ). Prevertebral ganglia are located in the abdominal cavity and include the celiac and superior and inferior mesenteric ganglia (see Fig. 11.1 ). Thus paravertebral and prevertebral ganglia are located at some distance from their target organs.
The axons of preganglionic neurons are often small, myelinated nerve fibers known as B fibers (see Table 5.1 ), although some are unmyelinated C fibers. They leave the spinal cord in the ventral root and enter the paravertebral ganglion at the same segmental level through a white communicating ramus. White rami are found only from the levels of T1 to L2. The preganglionic axon may synapse on postganglionic neurons in the ganglion at its level of entry; may travel rostrally or caudally within the sympathetic trunk and give off collaterals to the ganglia that it passes; or may pass through the ganglion, exit the sympathetic trunk, and enter a splanchnic nerve to travel to a prevertebral ganglion (see Figs. 11.1 and 11.2 ). Splanchnic nerves innervate the viscera; they contain both visceral afferents and autonomic motor fibers (sympathetic or parasympathetic).
Postganglionic neurons whose somata lie in paravertebral ganglia generally send their axons through a gray communicating ramus to enter a spinal nerve (see Fig. 11.2 ). Each of the 31 pairs of spinal nerves has a gray ramus. Postganglionic axons are distributed through the peripheral nerves to effectors, such as piloerector muscles, blood vessels, and sweat glands, located in the skin, muscle, and joints. Postganglionic axons are generally unmyelinated (C fibers), although some exceptions exist. The names white and gray rami reflect the relative contents of myelinated and unmyelinated axons in these rami.
Preganglionic axons in a splanchnic nerve often travel to a prevertebral ganglion and synapse, or they may pass through the ganglion and an autonomic plexus and end in a more distant ganglion. Some preganglionic axons pass through a splanchnic nerve and end directly on cells of the adrenal medulla, which are equivalent to postganglionic cells.
The organization of the sympathetic ganglion extending bilaterally from the cervical level to the coccygeal level forms a ganglionated chain and is often referred to as the sympathetic chain. This arrangement serves as a distribution system that enables preganglionic neurons, which are limited to the thoracic and upper lumbar segments, to activate postganglionic neurons that innervate all body segments. However, there are fewer paravertebral ganglia than there are spinal segments because some of the segmental ganglia fuse during development. For example, the superior cervical sympathetic ganglion represents the fused ganglia of C1 through C4; the middle cervical sympathetic ganglion is the fused ganglia of C5 and C6; and the inferior cervical sympathetic ganglion is a combination of the ganglia at C7 and C8. The term stellate ganglion refers to fusion of the inferior cervical sympathetic ganglion with the ganglion of T1. The superior cervical sympathetic ganglion provides postganglionic innervation to the head and neck, and the middle cervical and stellate ganglia innervate the heart, lungs, and bronchi.
In general, the sympathetic preganglionic neurons are distributed to ipsilateral ganglia, and thus control autonomic function on the same side of the body. Important exceptions are the sympathetic innervation of the intestines and the pelvic viscera, which are both bilateral. As with motor neurons to skeletal muscle, sympathetic preganglionic neurons that control a particular organ are spread over several segments. For example, the sympathetic preganglionic neurons that control sympathetic functions in the head and neck region are distributed at levels C8 to T5. Similarly, those that control adrenal gland are distributed at levels T4 to T12.
The parasympathetic preganglionic neurons are found in several of the cranial nerve nuclei of brainstem and in the sacral spinal cord (S3-S4) gray matter (see Fig. 11.1 ). Hence, this part of the autonomic nervous system is sometimes called the craniosacral division. The cranial nerve nuclei that contain parasympathetic preganglionic neurons are the Edinger-Westphal nucleus (cranial nerve III), the superior (cranial nerve VII) and inferior (cranial nerve IX) salivatory nuclei, and the dorsal motor nucleus of the vagus and nucleus ambiguus (cranial nerve X). Postganglionic parasympathetic cells are located in cranial ganglia, including the ciliary ganglion (preganglionic input is from the Edinger-Westphal nucleus), the pterygopalatine and submandibular ganglia (input is from the superior salivatory nucleus), and the otic ganglion (input is from the inferior salivatory nucleus). The ciliary ganglion innervates the pupillary sphincter and ciliary muscles in the eye. The pterygopalatine ganglion supplies the lacrimal gland, as well as glands in the nasal and oral pharynx. The submandibular ganglion projects to the submandibular and sublingual salivary glands and to glands in the oral cavity. The otic ganglion innervates the parotid salivary gland and glands in the mouth.
Other parasympathetic postganglionic neurons are located near or in the walls of visceral organs in the thoracic, abdominal, and pelvic cavities. Neurons of the enteric plexus include cells that can also be considered parasympathetic postganglionic neurons. All of these cells receive input from the vagus or pelvic nerves. The vagus nerves innervate the heart, lungs, bronchi, liver, pancreas, and gastrointestinal tract from the esophagus to the splenic flexure of the colon. The remainder of the colon and rectum, as well as the urinary bladder and reproductive organs, is supplied by sacral parasympathetic preganglionic neurons that travel through the pelvic nerves to postganglionic neurons in the pelvic ganglia.
The parasympathetic preganglionic neurons that project to the viscera of the thorax and part of the abdomen are located in the dorsal motor nucleus of the vagus (see Fig. 4.6 E ) and the nucleus ambiguus. The dorsal motor nucleus is largely secretomotor (it activates glands), whereas the nucleus ambiguus is visceromotor (it modifies the activity of cardiac muscle). The dorsal motor nucleus supplies visceral organs in the neck (pharynx, larynx), thoracic cavity (trachea, bronchi, lungs, heart, and esophagus), and abdominal cavity (including much of the gastrointestinal tract, liver, and pancreas). Electrical stimulation of the dorsal motor nucleus results in gastric acid secretion, as well as secretion of insulin and glucagon by the pancreas. Although projections to the heart have been described, their function is uncertain. The nucleus ambiguus contains two groups of neurons: (1) a dorsal group (branchiomotor) that activates striated muscle in the soft palate, pharynx, larynx, and esophagus; and (2) a ventrolateral group that innervates and slows the heart (see also Chapter 18 ).
The visceral motor fibers in the autonomic nerves are accompanied by visceral afferent fibers. Most of these afferent fibers supply information that originates from sensory receptors in the viscera. The activity of these sensory receptors only rarely reaches the level of consciousness; however, these receptors initiate the afferent limb of reflex arcs. Both viscerovisceral and viscerosomatic reflexes are elicited by these afferent fibers. Even though these visceral reflexes generally operate at a subconscious level, they are very important for homeostatic regulation and adjustment to external stimuli.
The fast-acting neurotransmitters released by visceral afferent fibers are not well documented, although many of these neurons release the excitatory neurotransmitter, glutamate. Visceral afferent fibers also contain many neuropeptides or combinations of neuropeptides, including angiotensin II, arginine vasopressin, bombesin, calcitonin gene–related peptide, cholecystokinin, galanin, substance P, enkephalin, oxytocin, somatostatin, and vasoactive intestinal polypeptide.
Visceral afferent fibers that can mediate conscious sensation include nociceptors that travel in sympathetic nerves, such as the splanchnic nerves. Visceral pain is caused by excessive distention of hollow viscera, contraction against an obstruction, or ischemia. The origin of visceral pain is often difficult to localize because of the diffuse nature of the pain and its tendency to be referred to somatic structures (see Chapter 7 ). Visceral nociceptors in sympathetic nerves reach the spinal cord via the sympathetic chain, white rami, and dorsal roots. The terminals of nociceptive afferent fibers project to the dorsal horn and to the region surrounding the central canal. They activate local interneurons, which participate in reflex arcs, and also projection cells, which include spinothalamic tract cells that signal pain to the brain.
A major visceral nociceptive pathway from the pelvis involves a relay in the gray matter of the lumbosacral spinal cord. These neurons send axons into the fasciculus gracilis that terminate in the nucleus gracilis; therefore, the dorsal columns not only contain primary afferents for fine touch, vibration, and proprioception sensation (their main component), but also second-order neurons of the visceral pain pathway (recall that second-order axons for somatic pain travel in the lateral funiculus as part of the spinothalamic tract). Visceral nociceptive signals are then transmitted to the ventral posterior lateral (VPL) nucleus of the thalamus, and presumably from the VPL to the cerebral cortex. Interruption of this pathway accounts for the beneficial effects of surgically induced lesions of the dorsal column at lower thoracic levels to relieve pain produced by cancer of the pelvic organs.
Other visceral afferent fibers travel in parasympathetic nerves. These fibers are generally involved in reflexes rather than sensation (except for taste afferent fibers; see Chapter 8 ). For example, the baroreceptor afferent fibers that innervate the carotid sinus are in the glossopharyngeal nerve. They enter the brainstem, pass through the solitary tract, and terminate in the nucleus of the solitary tract (see Fig. 4.6 E ). These neurons connect with interneurons in the brainstem reticular formation. The interneurons, in turn, project to the autonomic preganglionic neurons that control heart rate and blood pressure (see Chapter 18 ).
The nucleus of the solitary tract receives information from all visceral organs, except those in the pelvis. This nucleus is subdivided into several areas that receive information from specific visceral organs.
The enteric nervous system, which is located in the wall of the gastrointestinal tract, contains about 100 million neurons. The enteric nervous system is subdivided into the myenteric plexus, which lies between the longitudinal and circular muscle layers of the gut, and the submucosal plexus, which lies in the submucosa of the gut. The neurons of the myenteric plexus primarily control gastrointestinal motility (see Chapter 27 ), whereas those in the submucosal plexus primarily regulate body fluid homeostasis (see Chapter 35 ).
The types of neurons found in the myenteric plexus include not only excitatory and inhibitory motor neurons (which can be considered parasympathetic postganglionic neurons) but also interneurons and primary afferent neurons. Afferent neurons supply mechanoreceptors within the wall of the gastrointestinal tract. These mechanoreceptors are the beginning of the afferent limb of reflex arcs within the enteric plexus. Local excitatory and inhibitory interneurons participate in these reflexes, and the output is sent through the motor neurons to smooth muscle cells. Excitatory motor neurons release acetylcholine and substance P; inhibitory motor neurons release dynorphin and vasoactive intestinal polypeptide. The circuitry of the enteric plexus is so extensive that it can coordinate the movements of an intestine that has been completely removed from the body. However, normal function requires innervation by the autonomic preganglionic neurons and regulation by the CNS.
Activity in the enteric nervous system is modulated by the sympathetic nervous system. Sympathetic postganglionic neurons that contain norepinephrine inhibit intestinal motility, those that contain norepinephrine and neuropeptide Y regulate blood flow, and those that contain norepinephrine and somatostatin control intestinal secretion. Feedback is provided by intestinofugal neurons that project back from the myenteric plexus to the sympathetic ganglia.
The submucosal plexus regulates ion and water transport across the intestinal epithelium and glandular secretion. It also communicates with the myenteric plexus to ensure coordination of the functions of the two components of the enteric nervous system. The neurons and neural circuits of the submucosal plexus are not as well understood as those of the myenteric plexus, but many of the neurons contain neuropeptides, and the neural networks are well organized.
The main type of neuron in autonomic ganglia is the postganglionic neuron. These cells receive synaptic connections from preganglionic neurons, and they project to autonomic effector cells. However, many autonomic ganglia also contain interneurons. These interneurons process information within the autonomic ganglia; the enteric plexus can be regarded as an elaborate example of this kind of processing. One type of interneuron found in some autonomic ganglia contains a high concentration of catecholamines; hence, these interneurons have been called small, intensely fluorescent (SIF) cells. SIF cells are believed to be inhibitory.
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