Membrane Potential, Equilibrium Potential and Resting Potential, Animation

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(USMLE topics) Understanding basics of ion movement and membrane voltage, equilibrium potential and resting potential.
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Voice by: Ashley Fleming
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Membrane potential, or membrane voltage, refers to the DIFFERENCE of electric charges across a cell membrane. Most cells have a NEGATIVE transmembrane potential. Because membrane potential is defined RELATIVE to the exterior of the cell, the negative sign means the cell has MORE negative charges on the INSIDE.
There are 2 basic rules governing the movement of ions:
- they move from HIGHER to LOWER concentration, just like any other molecules;
- being CHARGE-bearing particles, ions also move AWAY from LIKE charges, and TOWARD OPPOSITE charges.
In the case of the cell membrane, there is a THIRD factor that controls ion movement: the PERMEABILITY of the membrane to different ions. Permeability is achieved by OPENING or CLOSING passageways for specific ions, called ION CHANNELS. Permeability can change when the cell adopts a DIFFERENT physiological state.
Consider this example: 2 solutions of different concentrations of sodium chloride are separated by a membrane. If the membrane is EQUALLY permeable to BOTH sodium and chloride, both ions will diffuse from higher to lower concentration and the 2 solutions will eventually have the same concentration. Note that the electric charges remain the same on both sides and membrane potential is zero.
Now let’s assume that the membrane is permeable ONLY to the positively-charged sodium ions, letting them flow down the concentration gradient, while BLOCKING the negatively-charged chloride ions from crossing to the other side. This would result in one solution becoming INCREASINGLY positive and the other INCREASINGLY negative. Since opposite charges attract and like charges repel, positive sodium ions are now under influence of TWO forces: DIFFUSION force drives them in one direction, while ELECTROSTATIC force drives them in the OPPOSITE direction. The equilibrium is reached when these 2 forces COMPLETELY counteract, at which point the NET movement of sodium is ZERO. Note that there is NOW a DIFFERENCE of electric charge across the membrane; there is ALSO a CONCENTRATION gradient of sodium. The two gradients are driving sodium in OPPOSITE directions with the EXACT SAME force. The voltage established at this point is called the EQUILIBRIUM potential for sodium. It’s the voltage required to MAINTAIN this particular concentration gradient and can be calculated as a function thereof.
A typical RESTING neuron maintains UNequal distributions of different ions across the cell membrane. These gradients are used to calculate their equilibrium potentials. The positive and negative signs represent the DIRECTION of membrane potential. Because sodium gradient is directed INTO the cell, its equilibrium potential must be POSITIVE to drive sodium OUT. Potassium has the REVERSE concentration gradient, hence NEGATIVE equilibrium potential. Chloride has the same INWARD concentration direction as sodium, but because it’s a negative charge, it requires a NEGATIVE environment inside the cell to push it OUT.
The resting membrane potential of a neuron is about -70mV. Notice that ONLY chloride has the equilibrium potential near this value. This means chloride is IN equilibrium in resting neurons, while sodium and potassium are NOT. This is because there is an ACTIVE transport to keep sodium and potassium OUT of equilibrium. This is carried out by the sodium-potassium PUMP which constantly brings potassium IN and pumps sodium OUT of the cell. The resulting resting potential, while costly to maintain, is essential to generation of action potentials when the cell is stimulated.

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29 сен 2024

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Комментарии : 121

@Alilamedicalmedia Год назад

Love this video? Check out our course “Anatomy and Physiology” made entirely with videos like this (without watermark): www.alilaacademy.com/courses/anatomy-and-physiology-for-teachers

@litrallynotmebruh9531 5 лет назад

thank you so much! this is much clearer than a 150 mins lecture!!!

@mooky01 2 года назад

exactly. been trying to find out what in the world my prof is communicating in that mess of a lecture, and here I go, a four minute video got me up to speed.

@ومضةلطفي 5 месяцев назад

I’m still confused

@LaibaLaiba-k2m 3 месяца назад

This is very confusing topic ...but now my concept has cleared...after watching 3 or 4 times

@majdfayad4019 2 месяца назад

Work harder

@haiderMJ 24 дня назад

I’m more confused

@cindyjemutai9812 3 года назад

That was super informative and soo easy to understand.. Thank you 😁

@rajeevkaparthi190 7 месяцев назад

Thanks a lot

@วิ่งกับหมวย 4 года назад

ขอแปลไทยหน่อยคับ

@maigiangha4016 2 года назад

i understood the whole lesson just by watching 2 minutes of this video. Thank you so so much!

@GurmeetKaur-jw4ld 4 года назад

I'm confused

@sal941 4 года назад

@theGuilherme36 4 года назад

Me too. I don't understand why the potential of the membrane is equal to that of the chloride since the chloride has more negative outside while the membrane has more negative inside.

@sal941 4 года назад

@@theGuilherme36 hom gout vancom

@theGuilherme36 4 года назад

@@sal941 ???

@sal941 4 года назад

Guilherme Resende so if romases do nadonades meet anatomical poratesas if you?

@sudipsaha305 5 лет назад

Great and detailed explanation, good graphics.. Very helpful to understand

@aymane9752 Год назад

can someone please explain to me why the equilibrium potential of K+ is negative? negative and positive attract each other, and you want K+ to enter the cell again, so why isnt it positive?

@funnybunny1408 Год назад

Bcz when potassium get into the neuron simultaneously sodium will move outside and for every two k+ ions are actively transported inward and three Na+ ions are pumped out so as more positive charges pumped out than going inside the inner environment get more negative than outside!

@halicusdiaarcan102 Год назад

This is because calculating membrane potential is a comparison of the outside of the cell (ground) compared to the inside. If your voltage is positive, this means that the inside of the cell is more positive compared to the outside. This would force K+ out, which is the opposite of our desired effect. Thus, K+ requires a negative voltage-a more negative inside- to draw that K+ back in.

@joaofelipeagostini7040 4 года назад

exellent, simplified and still accurate explanation!

@CrankyRayy 3 года назад

Lol potassium can't make up it's damn mind!

@princesspearl3994 3 года назад

thank you love the video. Why does the equilibrium potential need to be positive for Na+ inorder to put sodium out of the cell?

@htetmyatmin223 3 года назад

The equilibrium potential needs to be positive because like charges repel. Only then the sodium ions will go back to the outside of the cells.

@henricostel7273 2 года назад

@@htetmyatmin223 Could you explain why does it have to be negative to potassium?

@htetmyatmin223 2 года назад

@@henricostel7273 Since potassium ion is positive charge and the direction of it's gradient is to flow out of the cell, the equilibrium potential has to be negative to attract these potassium ions back inside the cell because unlike charges attract.

@halicusdiaarcan102 Год назад

@@htetmyatmin223 wonderful explanation. Thank you!

@prathvisingh8288 5 лет назад

At 1:52, how to know that at which point the flux of Na+ ions across the membrane will stop?

@sucharithapandeti8942 5 лет назад

As soon as Na diffusion potential is able to counteract Na conc.gradient

@CrankyRayy 3 года назад

What cherry said

@anaselassal3322 4 года назад

This video is an artwork.. Thank you

@bookworm6920 5 лет назад

That is very useful thanks so much 👏🏻👏🏻

@rahulraman9962 5 лет назад

Great and simplified explanation!!

@kafge7798 7 месяцев назад

how did she calculate that E was 6??

@IylaMohamed Час назад

I am an Arab and I cannot understand English fluently. Is there anyone who can teach me English?🥺❤️

@mustafacenkkarasulu8094 5 лет назад

Why is cell interior negative charged even though there’s more cations and less anions than outside ?

@Alilamedicalmedia 5 лет назад

There are large molecules inside the cells that carry negative charge: proteins, nucleic acids

@dilipsinhjhala1713 4 года назад

Useful video to understand body Biology, better than reading a book !

@samsadbegum1898 Год назад

Wow

@nuwanda3333 11 месяцев назад

Can anyone help me with my EDx course? I couldn't find an answer there: Cells in the electric eel's electric organ have a larger-than-normal membrane potential, sitting at roughly -150 mV. How might a cell achieve a more negative resting potential? Indicate all that apply. Higher extracellular K+ concentration Lower extracellular K+ concentration (correct) Higher intracellular K+ concentration (correct) Lower intracellular K+ concentration Why do lower extracellular K and higher intracellular K make the membrane potential greater? Wouldn't more positive charge inside the neuron make the membrane potential smaller?

@noahhubscher2926 5 лет назад

great video and nice illustration. thank you.

@bio366geethasankar7 7 месяцев назад

🥹🙏

@ChimaobiHillary 4 месяца назад

Ma pls make a video on types nerve fibers and neurotrophin

@gaborpetheo9391 2 года назад

Good, simple, easy-to-understand videos from Alila in general, with some errors in the details (e.g. starting time point of relative refracter period, or threshold potential for the late Kv channels in the action potential video). While these videos are good (overly simplified) starting points for the referred topics, I would warmly suggest medical students etc, to put effort in understanding/learning their text books and university lectures as well, if they want to remain on the safe side for passing their exams.

@charlesagyenang2584 Год назад

UHAS202212743 So in what way does this pump differ from the voltage gated channel with regards to the action potential?

@Piston4 2 года назад

Great, thank you. So simple.

@waqasarmanii4724 Год назад

Thanks sir very informative and short video .but plz upload videos in urdu.

@farahali5754 Год назад

True thanks about grateful Active and passive diffusion of electrical and chemical ions through cellular membrane . Perfect information

@salmaelmoghrabi7136 5 лет назад

thank you ! that was very helpful .

@nuwanda3333 11 месяцев назад

At 2.47, how do we calculate the equilibrum potentials?

@Myname-ie3ij Год назад

We have to admit she has Scarlett johansson's voice 😅 lol .. thank you 🙏

@heliarahnamaei6953 Год назад

What does it mean that positive and negative signs represent the direction of membrane potential?

@محمدزكي-ق7ج 5 лет назад

Great video thank yuo

@Danheim641 4 года назад

3:18 was what I came for.... thanks

@felixslytherin6567 5 месяцев назад

This is the cream of our hours long reading and lectures Thankuuu

@Ayanok0jikiyotoka 2 года назад

Why the potential of Na is positive if it is driving inside the cell? ..

@mrwalkercooks 2 года назад

I just started grad school, I really appreciate this video. I can understand my notes now

@sadiqibrahim7654 Месяц назад

Let go

@toushty 3 года назад

I don't understand why the inner membrane is negative, because potassium has a positive charge.

@beyzanurpekmezci9816 3 года назад

Because of the proteins, rna and dna. They have negative charge

@limitd.1921 8 месяцев назад

Thank you so much this was so helpfull :)

@shaistakhursheed18 3 года назад

Thank you so much.....this vedio os better than our lecture of two hours👍👍👍

@baikalkim5324 4 месяца назад

아하!

@katherinecabildo1527 4 года назад

thank you so much!!

@bishnubhusandasgupta50 2 года назад

Great video...need more of these medical topics pls ma'am

@ninjadog5800 9 месяцев назад

This was so helpful thank you so much btw at 0:19 I thought the inside of the membrane being considered more negative was because there were less positive charges instead of it being because of more negative charges

@Alilamedicalmedia 9 месяцев назад

The inside negative charge is due mostly to large negative charges from proteins and nucleic acids.

@ninjadog5800 9 месяцев назад

@@Alilamedicalmedia I had no idea thank you so much!

@qaq8178 2 года назад

I wonder if the equilibrium potential for an ion species is always constant?Lets say,we manually double the amount of Na+ concentration outside the membrane and wait for the Na+ ions to equlibrate,will the ENa still be 6(from your example)?

@gaborpetheo9391 2 года назад

Short answer: no, it will change. Long answer: www.d.umn.edu/~jfitzake/Lectures/DMED/IonChannelPhysiology/MembranePotentials/EquilibriumPotentials.html

@ritadukunde5176 4 года назад

If a neuron has an internal potential of -60mV and an external potential of -20mV, would the potential difference across the membrane be inside minus outside or outside minus inside?

@gaborpetheo9391 2 года назад

Inside negative, -40 mV as compared to the outside. These are conventions: you compare IC to EC (or subtract EC form IC: -60- -20= -40). As EC is often grounded, it is considered to be not different from Earth potential, that is considered 0 mV (convention again, -70mV - 0 mV=-70 mV= Em, in a typical nerve cell).

@srikanthankanthan3889 4 года назад

CLEANLY EXPLAINED

@sehrishirfan6264 3 года назад

Can anyone tell me why potassium ratio is more than sodium ratio across resting membrane potential?

@AmyKaylasVegas 11 месяцев назад

The drawing is confusing bc sodium potassium pumps pump 3 Na out and 2 K in. The graphic shows the opposite happening.

@vitoria96634 Год назад

Perfect, thank you!

@shahrokhabbasirad2223 3 года назад

Thanks for the video. But I was wondering if the channels are different for potassium and sodium. Here You showed only one channel, which I suppose, was for simplicity. Am I right?

@TM-lf6os 3 года назад

I believe they are, dont quote me though

@liamdonnelly1816 2 года назад

Yeah I'm 99% sure each ion has it's own channel.

@abcdefg-hv2ks 11 месяцев назад

The sodium-potassium pump is a special case. Each ion does have its own channel, but the Na-K pump spends ATP to bring K inside and simultaneously push Na outside.

@resapahlevi9073 4 года назад

very best explanation i have ever seen guru, thank you

@arshiyasheik2317 4 года назад

How can sodium move out of the cell when when its extracellular concentration is high?

@edwardcedeno8345 4 года назад

With a process called Primary Active Transport in which a cell membrane moves Ions against a concentration gradient (or against an electrical gradient). Guyton & Hall: Medical Physiology Chpt. 5

@omnigeddon 3 года назад

Amazing stuff thanks lot

@hugkisseslover101 3 года назад

So which channel is open?

@mdcataspirant486 3 года назад

Very well Explained

@ivyhung2329 2 года назад

clear and concise

@tealiciousthoughts2390 4 года назад

I finally understand this!!!! Thank you

@hayatetiktik9949 3 года назад

the

@ahtishamrana95 3 года назад

Thanks

@najebkhan8385 Год назад

soo easy to understand.. Thank you

@Alilamedicalmedia Год назад

You are welcome!

@lelabb4110 4 года назад

Thanks for emphasizing OOUT!

@keplercosmos675 4 года назад

It's more than best😍

@k.mertselvi7746 4 года назад

THANKS ALOT

@k.mertselvi7746 4 года назад

YOU SAVED MY LİFE

@L0n30pium 4 года назад

We have this in 11th grade :((

@allydimmy6885 3 года назад

hey am in 11 th grade too...and my teacher is like sso scary so its hard to understand in class....am depressed

@ronymajumder4587 5 лет назад

Great great great👍👌

@akakarkhan9381 4 года назад

Amazing lec

@umerbinshabir4561 6 лет назад

Mam how do we define the direction of electrostatic force here

@sakuraiwaru3299 6 лет назад

Umer Binshabir From positive isotope to negative isotope. The positive will want to move to where the negatives are.

@theGuilherme36 4 года назад

@@sakuraiwaru3299 So it doesn't make sense that chloride move from the negative to the positive.

@CRICKET..345 5 месяцев назад

Because direction of electrostatic force of attraction is from positive to negative

@khuepham5089 4 года назад

at 2:34 said E of Na is 6, how to calculate this?

@Alilamedicalmedia 4 года назад

6 is the voltage difference. The difference between -3 (on the left) and +3 (on the right) is 6

@khuepham5089 4 года назад

Thank you @@Alilamedicalmedia if mebrane poteintial Vm=0, what is the concentration of each ion on each side of the membrane? Is Vm=0 meant equilibruum potential too?

@CodeRed60005 2 года назад

@@Alilamedicalmedia -3 - (+3) = -6

@CodeRed60005 2 года назад

@@Alilamedicalmedia And if I have 10 positive and 2 negative ions on the left side and zero ions of any kind on the right side, then how do I calculate when the chemical gradient and electrical forces are going to be at equilibrium?