Nothing. There would be no gradient between the cell and the solution.
Isotonic solution
isotonic.
the cell lets out water to make it an isotonic solution
In an isotonic solution the cell would be unchanged. In a hypertonic solution water would flow out of the cell and it would shrink. In a hypotonic solution water would flow into the cell and it would expand like a balloon and possibly rupture.
In isotonic solution nothing ail happen. In hypertonic solution fluid will leave the cell to dilute the external fluid, causing the cell to crenate. In Hypotonic solution fluid will move into the cell to dilute the contents of the cell, causing it to bust or haemolyse.
isotonic and hypotonic
If a cell is placed in an isotonic solution, there will be no net movement of water across the cell membrane. The concentration of solutes inside and outside the cell will be equal, so the cell will maintain its normal shape and size as there is no osmotic pressure acting on it.
"hypertonic"
When a red blood cell is exposed to an isotonic solution, there is no net movement of water into or out of the cell. This means that the cell maintains its normal shape and volume, as the concentration of solutes inside and outside the cell is balanced.
When a cell is placed in an isotonic solution, there will be no net movement of water into or out of the cell, as the concentration of solutes is the same inside and outside the cell. This equilibrium maintains the cell's shape and functionality, preventing it from swelling or shrinking. The cell will remain stable, with its internal environment balanced relative to the external solution.
A cell placed in an isotonic solution will not shrink or swell. Isotonic means that the concentration of solutes in the solution is equal to the concentration of solutes within the cell. Since both concentrations are the same, no water flows in or out of the cell due to osmotic pressure.
A cell placed in an isotonic solution will remain the same size. This is because the concentration of solutes inside the cell is equal to the concentration of solutes outside the cell, creating a balanced environment where there is no net movement of water into or out of the cell.