Autonomic Nervous System Regulation

4.2 Autonomic Nervous System Regulation Concepts

Open Resources for Nursing (Open RN)

This section will review key anatomy concepts in the autonomic nervous system (ANS) related to the mechanism of action of medications. For more detailed information regarding the concepts reviewed, use the links provided to review detailed autonomic nervous system content in the Open Stax Anatomy and Physiology book:[1]

Review the basic structure and function of the nervous system

Review the anatomy of sensory perception.

Review the anatomy of motor responses.

Review the divisions of the autonomic nervous system.

Review autonomic reflexes and homeostasis.

Review information on a few drugs that affect the autonomic nervous system.

Components and Functions of the Nervous System

Outline of human body showing Central and Peripheral Nervous systems, with labels indicating locations of brain, spinal cord, ganglion, and nerves.
Figure 4.2a Central and Peripheral Nervous System

The nervous system has two major components: the central nervous system (CNS) and the peripheral nervous system. See Figure 4.2a.[2] The central nervous system (CNS) is composed of the brain and the spinal cord. The peripheral nervous system includes nerves outside the brain and spinal cord and consists of sensory neurons and motor neurons. Sensory neurons sense the environment and conduct signals to the brain that become a conscious perception of that stimulus. This conscious perception may lead to a motor response that is conducted from the brain to the peripheral nervous system via motor neurons to cause a movement. Motor neurons consist of the somatic nervous system that stimulates voluntary movement of muscles and the autonomic nervous system[3] that controls involuntary responses. This chapter will focus on the autonomic nervous system.

The two divisions[4] of the autonomic nervous system are the sympathetic division (SNS) and the parasympathetic division (PNS). The SNS contains alpha and beta receptors, and the PNS contains nicotinic and muscarinic receptors. Each type of receptor has a specific action when stimulated (see Figure 4.2b for an image of the divisions of the nervous system and the receptors in the ANS).

 

Concept map showing central and peripheral nervous systems, their functions and component parts.
Figure 4.2b Components of the Nervous System and ANS receptors

SNS and PNS Functions and Homeostasis

The sympathetic system is associated with the "fight-or-flight" response, and parasympathetic activity is often referred to as “rest and digest.” See Figure 4.2c[5] to compare the effects on PNS and SNS stimulation on target organs.  The autonomic nervous system regulates many of the internal organs through a balance of these two divisions and is instrumental in homeostatic mechanisms in the body.[6]

 

Diagram showing parts of parasympathetic and sympathetic stimulation on labeled target organs.
Figure 4.2c Effects of PNS and SNS Stimulation on Target Organs

Stimulation of SNS primarily produces increased heart rate, increased blood pressure via the constriction of blood vessels, and bronchial dilation. In comparison, stimulation of the PNS causes slowing of the heart, lowering of blood pressure due to vasodilation, bronchial constriction, and focuses on stimulating intestinal motility, salivation, and relaxation of the bladder.

Homeostasis is the balance between the two systems. At each target organ, dual innervation determines activity. For example, the heart receives connections from both the sympathetic and parasympathetic divisions. SNS stimulation causes the heart rate to increase, whereas PNS stimulation causes the heart rate to decrease.

To respond to a threat – to “fight or flight” – the sympathetic system stimulates many different target organs to achieve this purpose. For example, if a person sees a grizzly bear in the wilderness, the individual has the choice to stand and fight the bear or to run away. For either choice, several things must occur for additional oxygen and glucose to be delivered to skeletal muscle to fight or run. The respiratory, cardiovascular, and musculoskeletal systems are all activated to breathe rapidly, cause bronchodilation in the lungs to inhale more oxygen, stimulate the heart to pump more blood, and increase blood pressure to deliver it to the muscles.[7] The liver creates more glucose for energy for the muscles to use. The pupils dilate to see the threat (or the escape route) more clearly. Sweating prevents the body from overheating from excess muscle contraction.  Since the digestive system is not needed during this time of threat, the body shunts oxygen-rich blood to the skeletal muscles. To coordinate all these targeted responses, catecholamines such as epinephrine and norepinephrine are released in the sympathetic system and disperse to the many neuroreceptors on the target organs simultaneously.[8]

Chemical Signaling in the Autonomic Nervous System

Image showing Autonomic System neurons conduct signals via the preganglionic neurons to postganglionic neurons to the target organs.
Figure 4.2d Autonomic System neurons conduct signals via the preganglionic neurons to postganglionic neurons to the target organs

Neurons conduct impulses to the synapse of a target organ. The synapse is a connection between the neuron and its target cell. See Figures 4.2e[9] and 4.5[10] for images of synapse connections.

Illustration of the synapse with labels for synaptic vesticles, synaptic cleft, neurons, neurotransmitters, and Ligand gated channels.
Figure 4.2e The synapse is the connection between a neuron and its target cell where neurotransmitters are released

Preganglionic Neurons

The synapse is composed of a preganglionic (presynaptic) neuron and a postganglionic (postsynaptic) neuron. Preganglionic neurons release acetylcholine (ACh) onto nicotinic receptors on the postganglionic neuron.  Nicotine, found in tobacco products, also binds to and activates nicotinic receptors, mimicking the effects of ACh. This is worth noting, because if medications were developed to impact the nicotinic receptors, then it would impact both the SNS and PNS systems at the preganglionic level. Instead, most medications target the postganglionic neurons, because each type of postganglionic neuron has different neurotransmitters and different target receptors.

Postganglionic Neurons

There are different types of postganglionic neurons in the SNS and PNS branches of the autonomic nervous system. Postganglionic neurons of the PNS branch are classified as cholinergic, meaning that acetylcholine (ACh) is released, whereas postganglionic neurons of the SNS are classifed as adrenergic, meaning that norepinephrine (NE) is released. The terms cholinergic and adrenergic refer not only to the signal that is released, but also to the class of neuroreceptors that each binds. (See Figure 4.2f for an image of the release of ACh and NE and their attachment to the corresponding adrenergic or nicotinic receptors.)

The cholinergic system of the PNS includes two classes of postganglionic neuroreceptors: the nicotinic receptor and the muscarinic receptor. Both receptor types bind to ACh and cause changes in the target cell. The situation is similar to locks and keys. Imagine two locks—one for a classroom and the other for an office—opened by two separate keys. The classroom key will not open the office door, and the office key will not open the classroom door. This is similar to the specificity of nicotine and muscarine for their receptors. However, a master key can open multiple locks, such as a master key for the biology department that opens both the classroom and the office doors. This is similar to ACh that binds to both types of receptors.

The adrenergic system of the SNS has two major types of neuroreceptors: the alpha (α)-adrenergic receptor and beta (β)-adrenergic receptor. There are two types of α-adrenergic receptors, termed α1 and α2, and there are two types of β-adrenergic receptors, termed β1 and β2. An additional aspect of the adrenergic system is that there is a second neurotransmitter in addition to norepinephrine. The second neurotransmitter is called epinephrine. The chemical difference between norepinephrine and epinephrine is the addition of a methyl group (CH3) in epinephrine. The prefix “nor-” actually refers to this chemical difference in which a methyl group is missing. [11]

The term adrenergic should remind you of the word adrenaline, which is associated with the fight-or-flight response described earlier. Adrenaline and epinephrine are two names for the same molecule. The adrenal gland (in Latin, ad- = “on top of”; renal = “kidney”) secretes adrenaline. The ending “-ine” refers to the chemical being derived, or extracted, from the adrenal gland.[12]

Adrenergic & Nicotinic Receptors
Figure 4.2f Sympathetic and Parasympathetic Pre-and Postganglionic Fibers and Neuroreceptors

 

 Interactive Activity

ANS Neuroreceptors and Effects

The effects of stimulating each type of neuroreceptor are outlined in this section and sample uses of medications are provided.

Sympathetic Nervous System

SNS receptors include Alpha-1, Alpha-2, Beta-1, and Beta-2 receptors. Epinephrine and norepinephrine stimulate these receptors, causing the overall fight-or-flight response in various target organs. Medications causing similar effects are called adrenergic agonists, or sympathomimetics, because they mimic the effects of the body’s natural SNS stimulation. On the other hand, adrenergic antagonists block the effects of the SNS receptors. Dopamine also stimulates these receptors, but it is dosage-based. Dopamine causes vasodilation of arteries in the kidney, heart, and brain, depending on the dosage. See Table 4.2 for a comparison of stimulation and inhibition of these SNS receptors.

Table 4.2 Comparison of Medication Effects of Adrenergic Receptor Stimulation and Inhibition

Receptor

Effects of Stimulation

Effects of Inhibition

Alpha-1

  • Contract smooth muscle
  • CNS stimulation
  • Blood vessels: vasoconstriction to nonessential organs
  • GI: relax smooth muscle and decrease motility
  • Liver: glyconeogenesis
  • Bladder: contraction
  • Uterus: contraction
  • Pupils: dilation
  • Medication example: Pseudoephedrine to treat nasal congestion by vasoconstriction
  • Relax smooth muscle
  • Vasodilation
  • Bladder: increase urine flow
  • Medication example: Tamsulosin to improve urine flow

Alpha-2

  • Vasodilation
  • Medication Example: Clonidine to treat hypertension
  • Not used clinically

Beta-1

  • Primarily stimulates heart with increased heart rate and contractility
  • Also causes kidneys to release renin
  • Medication example: Dobutamine to treat acute heart failure, to increase cardiac output
  • “Selective beta-blocker” used to decrease heart rate and blood pressure
  • Medication example: Metoprolol to decrease heart rate and blood pressure

Beta-2

  • Primarily relax smooth muscle
  • Blood vessels: vasodilation
  • Lungs: bronchodilation
  • GI: decreased motility
  • Liver: glyconeogenesis
  • Uterus: relaxation
  • Medication example: Albuterol for bronchodilation
  • “Nonselective beta-blockers” block Beta-1 and Beta-2 receptors so also cause bronchoconstriction
  • Medication example: Propranolol blocks Beta-1 and Beta-2 receptors so lowers blood pressure but inadvertently causes bronchoconstriction

 

 Interactive Activity

Adrenergic Agonists

Adrenergic agonists stimulate Alpha-1, Alpha-2, Beta-1, or Beta-2 receptors. Stimulation of each type of receptor has different effects and are further explained below.

Alpha-1 receptor agonists: Stimulation of Alpha-1 receptors causes vasoconstriction in the periphery, which increases blood pressure. Vasoconstriction also occurs in mucus membranes, which decreases swelling and secretions for patients experiencing upper respiratory infections. Examples of Alpha-1 agonist medications are pseudoephedrine or phenylephrine, used to treat nasal congestion.

Alpha-2 receptor agonists: Stimulation of Alpha-2 receptors reduces CNS stimulation and is primarily used as an antihypertensive or a sedative. An example of an Alpha-2 agonist medication is clonidine, which is used to treat hypertension and is also used to treat attention deficit hyperactivity disorder.

Beta-1 receptor agonists: Stimulation of Beta-1 receptors primarily affects the heart by increasing heart rate and contractility. It also causes the kidneys to release renin. Effects on the heart are described as having a positive chronotropic (increases heart rate), positive inotropic (increases force of contraction), and positive dromotropic (increases speed of conduction between SA and AV node) properties. Medications that stimulate Beta-1 receptors are primarily used during cardiac arrest, acute heart failure, or shock. An example of a Beta-1 receptor agonist medication is dobutamine, which is used to increase cardiac output in someone experiencing acute heart failure or shock. See Figure 4.2g[13]  illustrating dromotropic properties of stimulating Beta-1 receptors.

Illustration of human heart from anterior view of frontal section with labels for major areas. Also has small inset illustration of frontal plane through heart.
Figure 4.2g Dromotropic Properties Affect the Speed of Conduction Between SA and AV Nodes

Beta-2 receptor agonists: Stimulation of Beta-2 receptors causes relaxation in smooth muscle in the lungs, GI, uterus, and liver. Medications that stimulate Beta-2 receptors are primarily used to promote bronchodilation, which opens the airway, and are often used to treat patients with asthma or chronic obstructive pulmonary disease (COPD). An example of a Beta-2 receptor agonist medication used in asthma is albuterol. See Figure 4.2h[14]  for an illustration of the effects of stimulating Beta-2 receptors in the lungs.

Side effects of Beta-2 receptor agonists are related to stimulation of Beta-2 receptors in other locations in the body. For example, albuterol can cause tachycardia by stimulating Beta-2 receptors in the heart. Stimulation of Beta-2 receptors can also inadvertently cause hyperglycemia in patients with diabetes because of activation of Beta-2 receptors in the liver, causing glyconeogenesis.

Images showing affect of asthma medication on bronchiole, as a woman inhales the medication.
Figure 4.2h Effects of Medications Stimulating Beta 2 Receptors in the Lungs
Adrenergic Antagonists

Adrenergic antagonist medications inhibit the Alpha-1, Alpha-2, Beta-1, and Beta-2 receptors. The effects of inhibition of each receptor are explained further below.

Alpha-1 antagonists: Alpha-1 antagonists are primarily used to relax smooth muscle in the bladder and cause vasodilation.

Examples include:

  • Tamsulosin is used to decrease resistance of an enlarged prostate gland and improve urine flow.
  • Prazosin is used to cause vasodilation and decrease blood pressure in patients with hypertension.

Alpha-2 antagonists: This classification is used in research, but has limited clinical application.

Beta Antagonists: There are two types of beta antagonists: selective beta blockers, which inhibit Beta-1 receptors and affect the heart only, and nonselective beta blockers, that block both Beta-1 and Beta-2 receptors, thus affecting both the heart and lungs. Beta-blockers are also referred to as having negative chronotropic (decreased heart rate), negative inotropic (decreased force of contraction), and negative dromotropic (decreased speed of conduction between SA and AV nodes) properties. It is also important for a nurse to remember that beta-blockers can mask the usual hypoglycemic symptoms of tremor, tachycardia, and nervousness in patients with diabetes.

Beta-1 antagonists: Beta-1 antagonists primarily block receptors in the heart, causing decreased heart rate and decreased blood pressure. An example is metoprolol, a selective beta-blocker used to treat high blood pressure, chest pain due to poor blood flow to the heart, and several conditions involving an abnormally fast heart rate.

Beta-2 antagonists: Nonselective beta-blockers block Beta-1 receptors and Beta-2 receptors in the lungs. An example is propranolol, which is used to lower blood pressure by decreasing the heart rate and cardiac output. However, it can also cause bronchoconstriction by inadvertently blocking Beta-2 receptors, so it must be used cautiously in patients with asthma or COPD.

 Interactive Activity

Parasympathetic Nervous System

Acetylcholine (ACh) stimulates nicotinic and muscarinic receptors. Drugs that stimulate nicotinic and muscarinic receptors are called cholinergics. Medications are primarily designed to stimulate muscarinic receptors. Nicotine stimulates pre- and post-ganglionic nicotinic receptors, causing muscle relaxation and other CNS effects. An example of a medication designed to stimulate nicotinic receptors is the nicotine patch, used to assist with smoking cessation.

Muscarinic agonists are also called parasympathomimetics and primarily cause smooth muscle contraction, resulting in decreased heart rate, bronchoconstriction, increased gastrointestinal/genitourinary tone, and pupillary constriction. There are two types of muscarinic agonists: direct-acting and indirect-acting. Direct-acting agonists bind to the muscarinic receptor. Indirect-acting muscarinic agonists work by preventing the breakdown of ACh, thus increasing the amount of acetylcholine available to bind receptors.

Examples of direct-acting muscarinic agonist medications include:

  • Pilocarpine: Used to treat glaucoma by causing the ciliary muscle to contract and allow for the drainage of aqueous humor
  • Bethanechol: Used for urinary retention by stimulating the bladder causing urine output

Examples of indirect-acting muscarinic agonist medications include:

  • Pyridostigmine: Used to reverse muscle weakness in patients with myasthenia gravis
  • Physostigmine: Used to treat organophosphate insecticide poisoning
  • Donepezil: Enhances memory in some patients with early Alzheimer’s disease

Muscarinic antagonists are referred to as anticholinergics or “parasympatholytics.” Anticholinergics inhibit ACh and allow the SNS to dominate, creating similar effects as adrenergics. Their overall use is to relax smooth muscle. “SLUDGE” is a mnemonic commonly used to recall the effects of anticholinergics: Salivation decreased, Lacrimation decreased, Urinary retention, Drowsiness/dizziness, GI upset, Eyes (blurred vision/dry eyes).  Anticholinergics may also cause confusion and constipation and must be used cautiously in the elderly. See Figure 4.2i[15] for an illustration of the  "SLUDGE" effects of anticholinergics.

Examples of anticholinergic medications include:

  • Atropine: Specific anticholinergic responses are dose-related. Small doses of atropine inhibit salivary and bronchial secretions and sweating; moderate doses dilate the pupil, inhibit accommodation, and increase the heart rate (vagolytic effect); larger doses will decrease motility of the gastrointestinal (GI) and urinary tracts; very large doses will inhibit gastric acid secretion
  • Oxybutynin: Relaxes overactive bladder
  • Benztropine: Reduces tremor and muscle rigidity in Parkinson’s disease or in treatment of extrapyramidal reactions from antipsychotic medications
  • Scopolamine: Decreases GI motility and GI secretions; used for motion sickness and post-operative nausea and vomiting [16],[17],[18],[19]
Images showing effects of Anticholinergics on organs.
Fig 4.2i “SLUDGE” Effects of Anticholinergics: Salivation decreased, Lacrimation decreased, Urinary retention, Drowsiness/Dizziness, GI upset, Eyes (blurred vision/dry eyes). Also may cause confusion and constipation

Media Attributions

  • Graphic
  • Sympathetic and Parasympathetic Animation (ver 2)
  • SLUDGE

  1. Content can be found at https://openstax.org/books/anatomy-and-physiology/pages/12-1-basic-structure-and-function-of-the-nervous-system
  2. "1201 Overview of Nervous System.jpg" by CNX OpenStax. is licensed under CC BY 4.0 Access for free at https://openstax.org/books/anatomy-and-physiology/pages/12-1-basic-structure-and-function-of-the-nervous-system
  3. "Component of the Nervous System" by Blaire Babbit at Chippewa Valley Technical College is licensed under CC BY 4.0
  4. "Component of the Nervous System" by Blaire Babbit at Chippewa Valley Technical College is licensed under CC BY 4.0
  5. Untitled image by Meredith Pomietlo for Chippewa Valley Technical College is licensed under CC BY 4.0
  6. This work is a derivative of Anatomy and Physiology by OpenStax licensed under CC BY 4.0. Access for free at Access for free at https://openstax.org/books/anatomy-and-physiology/pages/1-introduction
  7. This work is a derivative of Anatomy and Physiology by OpenStax licensed under CC BY 4.0. Access for free at https://openstax.org/books/anatomy-and-physiology/pages/1-introduction
  8. This work is a derivative of Anatomy and Physiology by OpenStax licensed under CC BY 4.0. Access for free at Access for free at https://openstax.org/books/anatomy-and-physiology/pages/1-introduction
  9. "Autonomic Nervous System" by CNX OpenStax is licensed under CC BY 4.0
  10. "The Synapse" by CNX OpenStax is licensed under CC BY 4.0 Access for free at https://openstax.org/books/anatomy-and-physiology/pages/12-5-communication-between-neurons
  11. "Sympathetic and Parasympathetic Pre-and Postganglionic fibers and neuroreceptors" by Dominic Slausen at Chippewa Valley Technical College is licensed under CC BY 4.0
  12. This work is a derivative of Anatomy and Physiology by OpenStax licensed under CC BY 4.0. Access for free at Access for free at https://openstax.org/books/anatomy-and-physiology/pages/1-introduction
  13. "2018 Conduction System of Heart.jpg" by OpenStax College is licensed under CC BY 3.0
  14. "Bronchodilators" by BruceBlaus is licensed under CC BY 4.0
  15. ""SLUDGE" effects of Anticholinergics" by Dominic Slausen at Chippewa Valley Technical College is licensed under CC BY 4.0
  16. McCuistion, L., Vuljoin-DiMaggio, K., Winton, M, & Yeager, J. (2018). Pharmacology: A patient-centered nursing process approach. Elsevier.
  17. Gersch, C., Heimgartner, N., Rebar, C., & Willis, L. (Eds.).  (2017). Pharmacology made incredibly easy. Wolters Kluwer.
  18. Lilley, L., Collins, S., & Snyder, J. (2014). Pharmacology and the Nursing Process. Elsevier.
  19. This work is a derivative of Principles of Pharmacology by LibreTexts licensed under CC BY-NC-SA 4.0
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