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BISC 101 Lecture Notes - Lecture 21: Resting Potential, Cell Membrane, Membrane Potential

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amberalpaca785
11 Feb 2018
School
Simon Fraser University
Department
Biological Sciences
Course
BISC 101
Professor
Tony Williams

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Document Summary

A voltage difference and concentration gradients exist across the plasma membrane. Nerve cells have a resting membrane potential of -60 to. 80mv selectively permeable membrane k+ >>> na+ at rest concentration gradients are maintained by na+-k+ pumps. Outward diffusion of k+ via lots of open resting (cid:894)(cid:862)leak(cid:863)(cid:895) k (cid:272)ha(cid:374)(cid:374)els little inward diffusion of na+ due to few open resting na channels inside becomes negative due to loss of k+ (until equilibrium reached) Na/k pump maintains concentration gradients for na and k transporting 3 na+ out for every. Graded potentials = small change in membrane potential where magnitude varies with size of stimulus. Action potential = (cid:862)all or (cid:374)o(cid:374)e(cid:863); (cid:272)o(cid:374)sta(cid:374)t (cid:373)ag(cid:374)itude a(cid:374)d (cid:272)a(cid:374) rege(cid:374)erate alo(cid:374)g a(cid:454)o(cid:374) Depolarization causes action potential = electrical signal. Voltage gated ion channels open and close by changing shape (conformation) in relation to changes in m. p. or voltage difference. If voltage-gated na channels open increase na permeability na flows in = depolarization.

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Related Questions

6. Consider the presence of hemoglobin in the catheter bag. Whatsymptom would this loss of

hemoglobin most strongly and immediately be linked to in thepatient?

A. Loss of blood volume

B. Loss of heartbeat

C. Drop in blood oxygen saturation

D. Liver failure


When a neuron is stimulated, the area of the membrane at thepoint of stimulation becomes
more permeable to Na+. If a cell starts at resting potential(-70mv), and is then stimulated:
A. The membrane voltage will become < -70mV, because Na+will move OUT of the cell.
B. The membrane voltage will become > -70mV, because Na+will move OUT of the cell.
C. The membrane voltage will become < -70mV because Na+will move INTO the cell.
D. The membrane voltage will become > -70mV because Na+will move INTO the cell.

. At the peak of the action potential, the Na+ voltage-gatedchannels close, and K+ voltage-gated
channels open in response to the positive membrane potential.In order to return the cell to its
negative resting potential quickly:
A. K+ will diffuse along its concentration gradient INTO thecell.
B. K+ will diffuse along its concentration gradient OUT of thecell.
C. Na+ will reverse its direction of diffusion OUT of thecell.
D. The sodium-potassium pump will move Na+ OUT of the cell andK+ INTO the cell.
E. None of the above would return the cell to its negativeresting potential quickly.

You experiment with higher concentrations of toxin and findcases when the cell could not
repolarize at all or, if it began to repolarize, itimmediately depolarized again. This tells you that
the toxin:
A. Prevents voltage-gated K+ channels from opening.
B. Increases the speed that the Na+ ion channels open.
C. Prevents the Na+ ion channels from closing.
D. Makes the Na+ ion channels close too soon.
E. Doesn

Santiago Ramon y Cajal’s theory of dynamic polarization refers to the:

(a)membrane potential of a neuron at rest.

(b)membrane potential of a neuron firing action potentials.

(c)opening and closing of gated channels in the membrane.

(d)one way flow of information in neurons from dendrites to axon terminals.

(e)one way flow of information in neurons from axon terminals to dendrites.

Over the course of scientific history, there are many examples of scientists reaching the right conclusion for the wrong reasons. When Schwann first proposed that the nervous system was made of individual cells, he based it on observations of:

(a)synapses.

(b)dendrites

(c)axon terminals.

(d)astrocytes.

(e)Nodes of Ranvier.

The synaptic cleft was finally seen in the 1950s. What prevented scientists from seeing it earlier?

(a)The resolution of the light microscope.

(b)They were looking in the wrong place.

(c)Their tissue was not appropriately stained.

(d)Myelination of the axons.

(e)all of the above

The resting membrane potential of a neuron is approximately:

(a) +65 V

(b) +65 mV

(c) -65 V

(d) -65 mV

What is largely responsible for the resting membrane potential in a neuron?

(a)Axonal insulation by myelin

(b)Voltage-Gated Sodium Channels

(c)The Action Potential

(d)Potassium Leak Channels

Which of the following would DECREASE the propagation velocity of an action potential down an axon?

(a)Increase in axon diameter

(b)Increase myelination between nodes of Ranvier

(c)Remove myelination between nodes of Ranvier

(d)Decrease density of voltage-gated Na+ channels except at the Nodes of Ranvier

The resting membrane potential of a neuron can be estimated using the:

(a)Nernst equation

(b)Goldman equation

(c)Hodgkin and Huxley equation

(d)Ohm’s law

18. What would happen to the resting membrane potential of a neuron if you added K+ to the extracellular fluid?

(a)Resting membrane potential would increase (become more positive)

(b)Resting membrane potential would decrease (become more negative)

(c)Resting membrane potential would not change

(d)Resting membrane potential would be abolished

. Which of the following statements is FALSE for Graded Potentials

(a)Magnitude changes with magnitude of triggering stimulus

(b)Magnitude decreases with distance from initial site

(c)Cannot be summed

(d)No refractory period

In the nervous system, the strength of the stimulus is coded into:

(a)The frequency of action potentials generated

(b)The amplitude of action potentials generated

(c)Both the frequency and amplitude of action potentials generated

(d)The duration of individual action potentials generated

Ion movement during both the depolarization and repolarization phases of an action potential are the result of:

(a)active transport pumps along the neuron membrane.

(b)diffusion of ions down their electrochemical concentration gradients.

(c)negative feedback loops.

(d)All of the above

At the peak of the action potential, the membrane potential is:

(a)Exactly at the Na+ equilibrium potential

(b)Greater (more positive) than the Na+ equilibrium potential

(c)Above 0 mV but less positive than the Na+ equilibrium potential

(d)0 mV