In this video, we're going to introduce some terms that will be very helpful for you as we move forward and talk about neuronal signaling or the signaling between neurons. The first term we're going to introduce here is electric current. Electric current can be defined as the flow of electric charge. When you think of an electric current, you may think of an image with a battery, and electrons will flow through a wire and be used to power a device such as a light bulb. However, electric currents do not necessarily require the flow of electrons; in fact, the electric current utilized by neuronal signaling will be ions, and the flow of ions will generate this electric current. The term electric potential refers to the electric potential energy per unit of charge and is measured in units of volts, abbreviated as V. The term voltage refers to the difference in electric potential between two points and results from differences in charge. If we look at our image, towards the top, we have positive charges, and towards the bottom, we have negative charges. Because there is a difference in electric potential between these two points, there exists a voltage here in this image. If we were to place a positively charged particle here, it would repel all the positive charges towards the top and be attracted towards the negative charges towards the bottom. This particle would make its way and move towards the negative charges.
When it comes to neuronal signaling, the electric potential can be created using an electrochemical gradient. This gradient is the combination of a chemical concentration gradient and an electric potential gradient across a membrane. Looking at the image below, it represents a biological membrane in the middle, with a bunch of ions on the left hand side representing our extracellular space, and a bunch of ions on the right hand side representing the intracellular space inside the cell. In the extracellular space, there tends to be a high concentration of sodium ions, labeled as high, and as you cross the membrane towards the inside of the cell, there's a low concentration of sodium ions. The potassium ion concentration is opposite of the sodium ion concentration, with a high concentration of potassium inside the intracellular space and a low concentration on the outside of the cell. The chloride ion concentration resembles that of the sodium ion, with high concentration of chloride ions on the outside of the cell and a low concentration on the inside.
The cell creates these concentration gradients through utilizing ion channels or membrane proteins that can transport ions. Sodium ions are actively pumped towards the outside of the cell, creating a high concentration on the exterior and potassium ions are pumped towards the inside. More sodium is pumped out than potassium is pumped in, resulting in a build up of positive charge on the outside of the cell. This is critical to remember as on the outside of the cell, there is a net positive charge and on the inside, there's a net negative charge across the membrane. This results in a voltage across the membrane, referred to as the membrane potential. The membrane potential is the difference in electric potential between the interior and exterior of a cell, separated by the membrane. When the cell is in a resting state, it will have a resting membrane potential which is negative, indicating that the inside of the cell is more negative with respect to the outside which is more positive. However, the membrane potential can change, which will be critical when we start to look at neuronal signaling. Hyperpolarization refers to the membrane potential becoming more negative, and depolarization refers to it becoming more positive.
We will utilize these terms more as we move forward in our course and discuss neuronal signaling. That concludes this video; I'll see you all in our next one.
