Theories Biological Psychology How Do Neurons Fire? Understanding How Actions Potential Work By Kendra Cherry, MSEd Kendra Cherry, MSEd Kendra Cherry, MS, is a psychosocial rehabilitation specialist, psychology educator, and author of the "Everything Psychology Book." Learn about our editorial process Updated on December 01, 2023 Medically reviewed Verywell Mind articles are reviewed by board-certified physicians and mental healthcare professionals. Medical Reviewers confirm the content is thorough and accurate, reflecting the latest evidence-based research. Content is reviewed before publication and upon substantial updates. Learn more. by Shaheen Lakhan, MD, PhD, FAAN Medically reviewed by Shaheen Lakhan, MD, PhD, FAAN Shaheen Lakhan, MD, PhD, is an award-winning physician-scientist and clinical development specialist. Learn about our Medical Review Board Fact checked Verywell Mind content is rigorously reviewed by a team of qualified and experienced fact checkers. Fact checkers review articles for factual accuracy, relevance, and timeliness. We rely on the most current and reputable sources, which are cited in the text and listed at the bottom of each article. Content is fact checked after it has been edited and before publication. Learn more. by Karen Cilli Fact checked by Karen Cilli Karen Cilli is a fact-checker for Verywell Mind. She has an extensive background in research, with 33 years of experience as a reference librarian and educator. Learn about our editorial process Print Science Photo Library - PASIEKA / Getty Images Table of Contents View All Table of Contents Before a Neuron Fires During Neuronal Firing After a Neuron Fires Problems With Neurons Firing Trending Videos Close this video player A neuron (a nerve cell) is the basic building block of the nervous system. When neurons transmit signals through the body, part of the transmission process involves an electrical impulse called an action potential. This process, which occurs during the firing of the neurons, allows a nerve cell to transmit an electrical signal down the axon (a portion of the neuron that carries nerve impulses away from the cell body) toward other cells. This sends a message to the muscles to provoke a response. For example, say you want to pick up a glass so you can take a drink of water. The action potential plays a key role in carrying that message from the brain to the hand. At a Glance Neurons firing transmits electrical signals through the body to carry information to other parts of the body and the brain. Neurons fire in a series of three steps:DepolarizationOvershootRepolarizationFor a neuron to fire, the electrical charge inside the cell has to change. Once this happens, an action potential fires, sending an electrical signal down the length of the axon, which can then be transmitted to the next cell. After neuronal firing, there is a brief refractory period where the cell cannot fire again. Before a Neuron Fires When a neuron is not sending signals, the inside of the neuron has a negative charge relative to the positive charge outside the cell. Electrically charged atoms known as ions maintain the positive and negative charge balance. Calcium contains two positive charges, sodium and potassium contain one positive charge, and chloride contains a negative charge. When at rest, the cell membrane of the neuron allows certain ions to pass through while preventing or restricting other ions from moving. In this state, sodium and potassium ions cannot easily pass through the membrane. Chloride ions, however, are able to freely cross the membrane. The negative ions inside the cell are unable to cross the barrier. The resting potential of the neuron refers to the difference between the voltage inside and outside the neuron. The resting potential of the average neuron is around -70 millivolts, indicating that the inside of the cell is 70 millivolts less than the outside of the cell. At this point, the brain has not yet sent the message to the hand to pick up the glass, but the neuron is ready to receive the signal. How Neurons Transmit Information During Neuronal Firing You’ve decided that you are thirsty and would like a drink of water. Your brain starts the chain of events to send a message to the muscles in your hand that you need to pick up the glass. When a nerve impulse (which is how neurons communicate with one another) is sent out from a cell body, the sodium channels in the cell membrane open and the positive sodium cells surge into the cell. Once the cell reaches a certain threshold, an action potential will fire, sending the electrical signal down the axon. The sodium channels play a role in generating the action potential in excitable cells and activating a transmission along the axon. Action potentials either happen or they don't; there is no such thing as a "partial" firing of a neuron. This principle is known as the all-or-none law. This means that neurons always fire at their full strength. This ensures that the full intensity of the signal is carried down the nerve fiber and transferred to the next cell and that the signal does not weaken or become lost the further it travels from the source. The message from the brain is now traveling down the nerves to the muscles in the hand. After a Neuron Fires After the neuron has fired, there is a refractory period in which another action potential is not possible. The refractory period generally lasts one millisecond. During this time, the potassium channels reopen and the sodium channels close, gradually returning the neuron to its resting potential. Once the neuron has "recharged," it is possible for another action potential to occur and transmit the signal down the length of the axon. Through this continual process of firing then recharging, the neurons are able to carry the message from the brain to tell the muscles what to do—hold the glass, take a sip, or put it down. An Overview of the Different Parts of a Neuron Problems With Neurons Firing Sometimes, problems with neuronal firing can emerge. This is often connected to problems with the myelin sheath surrounding the cell's axon. Myelin is a fatty substance that sheaths the axon, which helps aid in electrical transmission. Disorders that affect the myelin sheath include: Multiple sclerosisOptic neuritisTransverse myelitisAdrenoleukodystrophy Diffuse axonal injury is another problem that can disrupt neuron firing. This is due to traumatic brain injury and can lead to damage to different parts of the brain. 4 Sources Verywell Mind uses only high-quality sources, including peer-reviewed studies, to support the facts within our articles. Read our editorial process to learn more about how we fact-check and keep our content accurate, reliable, and trustworthy. Raghavan M, Fee D, Barkhaus PE. Generation and propagation of the action potential. Handb Clin Neurol. 2019;160:3-22. doi:10.1016/B978-0-444-64032-1.00001-1 Prieto N, Wrobleski J. Action potentials. In: Vonk J, Shackelford T, eds. Encyclopedia of Animal Cognition and Behavior. Springer International Publishing; 2017:1-5. doi:10.1007/978-3-319-47829-6_1268-1 Duncan ID, Radcliff AB. Inherited and acquired disorders of myelin: The underlying myelin pathology. Exp Neurol. 2016;283(Pt B):452-475. doi:10.1016/j.expneurol.2016.04.002 Benson C. Diffuse axonal injury. In: Encyclopedia of the Neurological Sciences. Elsevier; 2014:998-999. doi:10.1016/B978-0-12-385157-4.00326-2 By Kendra Cherry, MSEd Kendra Cherry, MS, is a psychosocial rehabilitation specialist, psychology educator, and author of the "Everything Psychology Book." 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