Tricky Topics: Action Potentials

FirstYearPsych Dalhousie
10 May 202018:17

Summary

TLDRThis script explores how neurons communicate via electrochemical signals, focusing on action potentials. It explains the roles of excitatory and inhibitory postsynaptic potentials in reaching the threshold for an action potential. The video details the process of action potential generation, propagation along the axon, and termination at the axon terminals. It also touches on how substances like novocaine and tetrodotoxin can block sodium channels, affecting action potentials, and how drugs can manipulate neurotransmitter levels to treat conditions like depression and Alzheimer's.

Takeaways

  • 🧠 Neurons communicate using electrochemical signals, with neurotransmitters playing a key role in transmitting messages across synapses.
  • πŸ”‹ Neurons have two main functions: transmitting messages to a target neuron via a synapse and carrying messages along the axon to the next neuron.
  • πŸ“ˆ Graded potentials, both excitatory (EPSPs) and inhibitory (IPSPs), determine when a neuron reaches the threshold to initiate an action potential.
  • ⚑ Action potentials are electrical signals generated when the membrane potential reaches a threshold of -55 millivolts, leading to the opening of voltage-gated sodium channels.
  • πŸš€ Action potentials propagate along the axon to the terminals, with the nervous system operating within a sensitive computational timeframe, some traveling at speeds up to 100 meters per second.
  • πŸ›‘ Myelin sheaths, formed by glial cells, insulate axons and allow electrical charge to jump between nodes of Ranvier, increasing the speed of action potential propagation.
  • πŸ”„ The action potential involves a cycle of depolarization, caused by sodium influx, and repolarization, caused by potassium efflux, to restore the resting membrane potential.
  • πŸ’Š Local anesthetics like novocaine block sodium channels, preventing the depolarization phase of action potentials, which is essential for nerve signaling.
  • 🐑 Tetrodotoxin, found in pufferfish, is a potent sodium channel blocker that can be lethal by paralyzing the respiratory system.
  • πŸ”— When an action potential reaches the axon terminal, it triggers the opening of voltage-dependent calcium channels, which are necessary for neurotransmitter release through exocytosis.
  • πŸ”„ Neurotransmitter release is terminated by either reuptake into the presynaptic neuron or enzymatic degradation in the synaptic cleft.

Q & A

  • How do neurons communicate with each other?

    -Neurons communicate with each other using the language of electrochemistry, primarily through the release of neurotransmitters and the generation of action potentials.

  • What are the two important jobs of a neuron?

    -A neuron's two important jobs are to transmit a message to a target across a synapse and to carry a message along the length of the axon to the next neuron.

  • What are the two types of postsynaptic potentials?

    -The two types of postsynaptic potentials are excitatory postsynaptic potentials (EPSPs) and inhibitory postsynaptic potentials (IPSPs).

  • What is the threshold membrane potential that triggers an action potential?

    -The threshold membrane potential that triggers an action potential is minus 55 millivolts.

  • How does the action potential propagate along the axon?

    -The action potential propagates along the axon through the sequential opening of voltage-gated sodium channels, which allows sodium ions to rush into the neuron, further depolarizing the membrane.

  • What is the role of myelin sheaths in the nervous system?

    -Myelin sheaths, formed by glial cells, insulate the axons and allow electrical charge to quickly jump between myelin segments, increasing the speed of action potential propagation.

  • What are nodes of Ranvier and why are they significant?

    -Nodes of Ranvier are the spaces between myelin sheaths that are densely clustered with ion channels, allowing the passage of electrical charge across the membrane and facilitating the rapid propagation of action potentials.

  • What happens when the membrane potential reaches positive 40 millivolts during an action potential?

    -When the membrane potential reaches positive 40 millivolts, voltage-gated sodium channels inactivate, and voltage-gated potassium channels open, leading to potassium efflux and the repolarization phase of the action potential.

  • What is the refractory period and why is it important?

    -The refractory period is a brief period of time when the neuron is hyperpolarized and unlikely to fire off another action potential, ensuring that the action potential only travels in one direction.

  • How do neurons terminate their response after an action potential?

    -Neurons terminate their response through two main methods: presynaptic reuptake, which uses transporter proteins to repackage neurotransmitters, and enzymatic degradation, which breaks down neurotransmitters in the synapse.

  • How do drugs like novocaine work to block action potentials?

    -Drugs like novocaine are sodium channel blockers, which prevent the depolarizing phase of action potentials, thus blocking the initiation of action potentials and causing a numbing effect.

  • What is tetrodotoxin and how does it affect the nervous system?

    -Tetrodotoxin is a powerful sodium channel blocker found in pufferfish. It can lead to paralysis and death by blocking action potentials in the respiratory system.

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Related Tags
Neuronal CommunicationAction PotentialsElectrochemistryNeurotransmittersSynaptic PotentialIon ChannelsMyelin SheathNeuroscienceLocal AnestheticsNeurotransmitter Release