Action Potentials and Neurons, Exams of Nursing

The concept of action potentials and how neurons conduct electrical impulses. It covers topics such as resting potential, depolarization, repolarization, and afterpolarization. It also discusses the propagation of action potentials and the role of neurotransmitters in the synapse. a graphic representation of the steps of an action potential and explains how the nervous system interacts with the muscular system at neuromuscular junctions.

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2023/2024

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Action Potentials BIOD-151 Portage Learning
Resting potential - how neurons are able to conduct neural/ electrical
impulses
Neurons: specialized to conduct electrical impulses
Polarized: at rest, the plasma membrane has a different charge on the
inside than the outside
Resting potential: at rest, this charge is about -70mv (NEGATIVE) bc inside is more negative than
outside
Maintained by the sodium-potassium pump
(exchanges
Na and K within
the same pump) gates allow to flow freely
-
active transport via THE SAME integral protein
-Carries ions across the plasma membrane
-Three sodium (Na+) ions pumped OUT
-Two potassiums (K+) ions pumped IN
-The 3:2 ratio makes the inside more negative compared
to the
outside of the cell. MUST BE MAINTAINED TO
KEEP THAT
DIFFERENCE IN CHARGE
Sodium and potassium gates (different than pump) (normally closed and allow only sodium or only
potassium)
-
enable action potentials (opposite of resting potential)
-Special protein-lined channels with gates in the
membrane
-
Allow sodium or potassium to pass through
-Gates are voltage-activated and respond to
changes in
shape
Action Potentials: rapid change in polarity across membrane
Depolarization: the membrane potential becomes more + (inside more positive than
outside) sodium rushes in
Repolarization: everything goes back to normal (more positive inside again) potassium rushes
out
Phase 1: Resting
Potential: During the resting phase, both sodium and potassium
gates are closed. -70mv
Phase
2: Depolarization: The sodium gates open, and sodium rushes into the axon during
the depolarization phase of the action potential. Voltage travels to zero and then on up
to +40 mV.
Phase 3: Repolarization: The sodium gates close, and potassium gates open allowing
potassium to rush out of the axon. This returns a negative voltage to the inside of the
axon
Phase 4: Afterpolarization, also called hyperpolarization. Potassium gates are slow to
close, and there is an undershoot of the potential. The voltage drops below -70mV
(more negative!!!!) and then returns to -70mV as the resting state begins.
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Action Potentials BIOD-151 Portage Learning

Resting potential - how neurons are able to conduct neural/ electrical impulses Neurons: specialized to conduct electrical impulses Polarized: at rest, the plasma membrane has a different charge on the inside than the outside Resting potential: at rest, this charge is about -70mv (NEGATIVE) bc inside is more negative than outside Maintained by the sodium-potassium pump (exchanges Na and K within the same pump) gates allow to flow freely

  • active transport via THE SAME integral protein
  • Carries ions across the plasma membrane - Three sodium (Na+) ions pumped OUT - Two potassiums (K+) ions pumped IN
  • The 3:2 ratio makes the inside more negative compared to the outside of the cell. MUST BE MAINTAINED TO KEEP THAT DIFFERENCE IN CHARGE Sodium and potassium gates (different than pump) ( normally closed and allow only sodium or only potassium)
  • enable action potentials (opposite of resting potential)
  • Special protein-lined channels with gates in the membrane
  • Allow sodium or potassium to pass through
  • Gates are voltage-activated and respond to changes in shape Action Potentials: rapid change in polarity across membrane Depolarization: the membrane potential becomes more + (inside more positive than outside) sodium rushes in Repolarization: everything goes back to normal (more positive inside again) potassium rushes out
    • Phase 1: Resting Potential : During the resting phase, both sodium and potassium gates are closed. -70mv
    • Phase 2 : Depolarization : The sodium gates open, and sodium rushes into the axon during the depolarization phase of the action potential. Voltage travels to zero and then on up to +40 mV.
    • Phase 3: Repolarization : The sodium gates close, and potassium gates open allowing potassium to rush out of the axon. This returns a negative voltage to the inside of the axon
    • Phase^4 :^ Afterpolarization,^ also^ called^ hyperpolarization.^ Potassium^ gates^ are^ slow to close, and there is an undershoot of the potential. The voltage drops below -70mV (more negative!!!!) and then returns to -70mV as the resting state begins.

P Graphic representation of the steps of an action potential. How do action potentials move?

Figure 1.13 Resting State of a neuron is -70mv, meaning there is a net negative charge inside the cell. The resting potential is maintained by a sodium-potassium pump ( Figure 1.14 ), which uses active transport to carry ions across the plasma membrane. The pump works by using an integral carrier protein that, for every three sodium (Na+) ions pumped out, two potassium (K+) ions are pumped in. The pump must keep in constant operation because the Na+ and K+ ions will naturally diffuse back to where they originated. Because the plasma membrane is more permeable to K+ diffusing outward and because more Na+ ions are being pumped outward than K+ pumped inward, a relative positive charge develops and is maintained on the outside of the membrane.

Figure 1.14 The resting potential is maintained by a sodium-potassium pump, which continually pumps sodium outside the cell and potassium inside. Action Potentials: Electrical Propagation If the axon is stimulated to conduct a nerve impulse, there is a rapid change in the polarity. This change in polarity is called the action potential. The resting potential becomes an action potential if the membrane becomes depolarized. Once an action potential occurs, it continues through the entire length of the axon. First, the membrane potential becomes more positive (called depolarization ), indicating that the inside of the membrane is now more positive than the outside. Then the potential returns to normal (called re-polarization ), indicating that the inside of the axon is negative again ( Figure 1.15 ).

Figure 1.16 Graphic representation of the steps of an action potential. Figure 1.17 Cell membrane during steps of the action potential The action potential travels along the length of an axon like a wave. It is self-propagating because the ion channels are prompted to open whenever the membrane potential decreases (depolarizes) in an adjacent area. An action potential is an all-or- nothing response, either occurring or not. Since no variation exists in the strength of a single impulse, intensity of a sensation (minor or major pain) is distinguished

by the number of neurons stimulated and the frequency with which the neurons are stimulated. Part 2 lecture Synapse: minute fluid-filled space between the axon terminal of presynaptic neuron and dendrite of postsynaptic neuron Electrical impulse travels down the length of the axon of the neuron. So now that is going to be called electrochemical in nature because it is both electrical and chemical Electrochemical : transmission of nerve impulses is both electrical and chemical. Chemicals called neurotransmitters transmit the signal across the synapse. The chemical transmission of action potential — how does 1 neuron communicate with another if they do not physically touch?

Electrical transmission

  • Electrical impulse travels from the cell body, to the end of the axon. (Axon terminals) reaches the end of the axon
  • The channels then allow Calcium ions to rush inside the cell
  • Causes the vesicles filled with neurotransmitters to fuse with plasma membrane
  • Neurotransmitters are released then bind to the dendrites of the receiving neuron
  • Depolarization occurs in the next neuron
  • The electrical impulse is carried forward
  • to another neuron, target organ, or gland Synaptic inhibition
  • short existence or neurotransmitters in the synapse
  • Prevention of continuous stimulation of postsynaptic neuron Types of neurotransmitters
    1. norepinephrine and epinephrine
  • function as hormones and neurotransmitters
  • Produces in adrenal glands then sent into general circulation
  1. Dopamine
  • specialized brain neurotransmitter
  • Regulates emotional responses
  • Regulates muscle tone
  1. Acetylcholine
  • Found in neuromuscular junctions (NMJ) - motor neuron synapse of a muscle

Figure 1.18 Neurons propagate electrochemical responses. Electrical responses are send along the length of the neurons, while chemical responses are sent in the synapse. Transmission of an action potential travels in one direction: from the presynaptic neuron to the postsynaptic neuron, with the synapse separating the neurons. Neurotransmitters are released by the presynaptic neuron into the synapse. Once a neurotransmitter has been released into a synapse, it has only a short time to act. Some synapses contain enzymes that rapidly inactivate the neurotransmitter. For example, the enzyme acetylcholinesterase , or simply cholinesterase, breaks down the neurotransmitter acetylcholine. In other synapses, the synaptic ending rapidly reabsorbs the neurotransmitter. Some neurons repackage the neurotransmitters in synaptic vesicles while others chemically breakdown the neurotransmitters. The short existence of neurotransmitters in the synapse prevents continuous stimulation of postsynaptic membranes. Prevention of continuous stimulation is called inhibition. Types of Neurotransmitters Norepinephrine and epinephrine are neurotransmitters produced by the adrenal glands. Dopamine is a specialized brain neurotransmitter to help regulate emotional responses and muscle tone. Acetylcholine is a neurotransmitter found at neuromuscular junctions (NMJ) in the peripheral nervous system. The NMJ is located where a motor neuron ends on a muscle instead of another neuron. For a muscle to contract, the nervous system must work together with the muscular system (see Figure 1.19 ).

Figure 1.19 Representation of a motor neuron (orang) synapsing on a muscle fiber (red) at the neuromuscular junction. The Neuromuscular Junction The nervous system interacts with the muscular system at neuromuscular junctions to enable muscular contraction. First, a nerve impulse must be sent to the muscle by the presynaptic motor neuron. A neuromuscular junction is a special type of synapse formed between a motor neuron and muscle tissue. Once the nerve impulse reaches the muscle fiber (at the neuromuscular junction), acetylcholine is released into the synapse (see Figure 1.20 ). Acetylcholine binds to receptors on the muscle fiber that cause sodium channels to open. Sodium

Figure 1.21 The NMJ Step 2: Calcium ions are released inside the muscle cell, causing the muscle to contract.