Autonomic Nervous System - Anatomy & Physiology
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Introduction
The peripheral nervous system found in most domestic species can be segregated into three sub-systems; the sensory system, the somatic motor system and the autonomic system. The autonomic nervous system (ANS) regulates the internal environment of the body including factors such as body temperature, blood pressure and concentrations of many substances. The ANS is responsible for mobilising the body's resources during stressful situations. It controls gland cells, cardiac muscle cells and smooth muscle cells. Control of this nervous system is involuntary and regulation is via autonomic reflexes. The autonomic reflex arc system is very similar to that of the somatic motor system, i.e. there are sensory (afferent) nerve fibres, an information integration centre, motor (efferent) fibres and effector cells. Any levels of increased activity within the autonomic nervous system can result in both stimulation or inhibition of effector cells, although it is only the efferent part of the reflex arc that is actually considered autonomic.
The autonomic nervous system is made up of the Sympathetic Nervous System (SNS) and the Parasympathetic Nervous System (PNS). The SNS is activated during critical situations, such as fight or flight responses whilst the PNS is activated whilst at rest, such as during food digestion after eating.
Autonomic Nervous System: Basic Principles
Within the somatic nervous system, the link between the skeletal muscle cell and the central nervous system consists of a single nerve fibre. Within the ANS, efferent signals are transmitted by two neurons between the CNS and the effector cells. The first neuron is a preganglionic neuron with a cell body in the CNS (either brain stem or spinal cord). The second neuron is postganglionic and connects the effector cell with the autonomic ganglia found outside the CNS.
The ANS reflex arcs maintain homeostasis via a process of negative feedback in which a sensory cell from within the peripheral nervous system takes a measurement, for example body temperature. This temperature reading is then relayed to the CNS where it is compared to a reference value. The CNS then uses efferent fibres to generate a response from effector cells given the comparison to the reference and thus adjusting the internal environment.
Sympathetic Nervous System
The SNS is activated in stressful or physically demanding situations and can temporarily enhance the physical performance of the body in order to better cope with the stressor. The preganglionic neurons (see Basics section) of the SNS are found within the lateral horns of the spinal cord within the full length of the thoracic vertebrae and the cranial lumbar vertebrae. The number of vertebral segments containing SNS preganglionic neurones has wide variation depending on the species in question; horses have 18 thoracic segments, canines have 13 and humans have 12. In most domestic species, the cranial most 4 to 6 lumbar vertebrae contain SNS segments. These preganglionic segments are located like a string of beads along either side of the spinal cord and are referred to as sympathetic chain ganglia. In most cases the number of sympathetic ganglia exceeds the number of spinal cord vertebrae containing the preganglionic cell bodies. Within the abdominal cavity ventral to the lumbar vertebrae there are three sympathetic ganglia called the prevertebral ganglia.
These preganglionic fibres then branch out to form synapses with postganglionic neurons, but in doing this each preganglionic fibre actually interconnects between neighbouring sympathetic chain ganglia. Therefore presynaptic nerve fibres from one segment of the spinal cord terminate in several ganglia and therefore activity in individual ganglia may affect many areas of the body. Postsganglionic neurones then extend to target organs spread throughout the body. The exception to this rule is the adrenal medulla as this endocrine gland receives sympathetic input directly from preganglionic nerve fibres, directly from the spinal cord. In this case, the adrenal glands are effectively modified post-ganglionic sympathetic neurons that do not have axons.
Parasympathetic Nervous System
The PNS is only activated during rest and can be used to regulate systems during functions such as digestion. Preganglionic parasympathetic neurons have cell bodies that are located in two seperate parts of the CNS, rather than running almost the full length of the CNS as the SNS does. The PNS has preganglionic neurons located in the brain stem and the sacral part of the spinal cord. Four of the cranial nerves supply parasympathetic innervation to the majority of the bodies glands and internal organs. In particular the vagus nerve (tenth cranial nerve) is responsible for a major proportion of PNS innervation. The PNS fibres located within the lateral horns of 2 or 3 sacral segments are responsible for innervation of the sex organs, urinary bladder and the rectum. PNS ganglia are located either adjacent to or within thwe wall of target organs and in contrast to SNS ganglia, there are no interconnections between ganglia in the PNS.
Enteric Nervous system
Postganglionic parasympathetic neurons that lead to the digestive tract differ from other organ connections with the PNS as within the GI tract they become part of a plexus of neurons within the walls of the tract. This complex network of neurons is referred to as the enteric nervous system (ENS). The ENS includes sensory and motor components and is therefore of vital importance in regulating smooth muscle within the GI tract. The wall of the GI tract contains numerous sensory cells that are able to react to different stimuli including; wall stretch, changes in nutrient concentrations, osmolarity, pH and irritation of the mucosal membrane. Stimulation of these sensory cells initiates reflexes which coordinate various elements of the GI tract such as smooth muscle activity, exocrine cells and endocrine (hormone producing) cells.
Digestive processes are coordinated by both neural and hormonal processes and neural regulation involves two different types of reflex arcs that together contribute to control of the GI tract. Short reflex arcs exist where both the sensory and motor nerve cells are contained within the wall of the digestive tract making up the ENS. (Long reflex arcs also exist that connect the GI tract to the CNS and whilst part of the PNS, are not part of the ENS). The ENS (short reflex arc) consists of two nerve plexuses within the wall of the GI tract in which the nerve cells form synapses with one another allowing sensory cells and motor cells to communicate. The simplest short reflex arcs involve a single sensory cell and a single motor cell, with a simple cause and effect. More complex short reflex arcs involve nerve impulses being propagated along a length of the GI tract by interneurons. An example of this would be the stimulation of sensory cells in the upper GI tract affecting motor function and secretion in lower parts of the GI tract. Since these more complex reflex arcs do not connect directly with the CNS, these reflexes are considered part of the ENS.
Therefore the ENS provides the GI tract with a certain degree of self-regulation, although most of these short reflex arcs provide a stimulatory influence, utilising acetylcholine. Some inhibitory reflexes do exist within the ENS including sphincter relaxation.