In the video on the sodium potassium pump, we talk about how it helps a helps a cell establish its resting membrane potential. And it does that by pumping actively pumping three sodium ions out for every two potassium ions it pumps in. And that by itself, that ratio of 3:2 by itself doesn't establish the full resting membrane potential. But then the potassium ions are allowed to start to start diffusing down their concentration gradient from the inside back to the outside. And of course there's a balancing force there or a balancing factor there. And that's the charge. Because if the outside is more positive than the inside, a positively charged ion, which the potassium ions are, well, at some they're not going to want to go up here so much because of their charge. It's more positive here than it is over here. where they'd actually want to go back, but their concentration gradient, they're going to be bumping into the bottom of this channel more than the top. And so, you're going to have a balance. They're going to start diffusing through, but you're not going to have equal concentrations because the charge is going to keep them back here. But what about the sodium ions? The sodium ions are getting more and more concentrated up here, and up here is getting more and more positive. If the sodium ions were left to their own devices, if there was no membrane over here, they would naturally, if we just looked at the concentration gradient, they would naturally want to diffuse down. We have a high concentration over here. We have a low concentration over there. So, if there was no membrane, then they would just naturally diffuse from high to low. That's their concentration gradient. And also, if there was no membrane, we've already talked about it being much more positive on this side than it is on this side. Or you could say we have a positive potential difference between here and here. So the positively charged ions like the sodiums up here would want to go down because of their charge. And so there's two reasons why they would want to go from this side of the membrane to that side of the membrane. Their concentration gradient and the and their charge, the electric potential. There's this potential energy of them wanting to get away from all the positive charges. And so that combined motivation for the sodium ions to go in that direction, we call that the electrochemical gradient. Electro electrochemical chemical gradient. And I I already said it once, but I'll say it again. There it's a combination of the electric gradient and the chemical gradient. The chemical gradient, you have higher concentration here, lower here. You would want to diffuse down. more things are going to bump on this side than on this side. So you're going to have a net net flow down if you didn't have this membrane here. And then when you think about the electric potential, more positive on this side than this side. So positive ions would want to go down. And so you can view this gradient as a source of potential energy. And cells in fact use this gradient, in fact the sodium electrochemical gradient as a source of energy. And so this let's say that this this protein right over here this is what we're going to call a sororter. This is a sim porter. And what it does is it uses the electrochemical gradient of one ion in this case in this case sodium. So it uses the fact that sodium really wants to go through the membrane and it uses that energy. Imagine like water falling down a waterfall and it can turn a it can turn a turbine or it can turn a a watermill type of thing. And so it uses that energy of the sodium flowing down its electrochemical gradient. It wants to go in this direction for two reasons, concentration and electric potential. So or I guess you say it's its electrostatic charge. And then it uses that energy to transport other things. And the most famous simporter with sodium is glucose. it's going to use that the sodium and the glucose are going to go together and the glucose is being transported against its concentration gradient. And so if you're going to transport something against its act against its concentration gradient, you're going to have to use active transport. So this concentration gradient, so let me be clear on glucose's concentration gradient. It looks like this. You have high concentration over here and you have low right over here. And the cell might not want to waste all this glucose. It wants to get as much glucose into the cell or across the membrane as possible. And so it's going to have to do some active transport to go against its concentration gradient to go to go in this direction. And over here the source of energy to go against the concentration gradient is the stored is the stored potential energy from the electrochemical gradient of the sodium. And so this type of active transport where you're using where you're using the energy that was stored up through a another form of active transport the sodium potassium pump we call this secondary active transport. So what's going over here this sodium glucose simporter this is secondary active transport. Secondary active active transport. It's using it's using the stored energy from one from the electrochemical gradient of one molecule. It's using that stored energy to drive the active transport of another molecule glucose going against its concentration gradient.