Osmosis in Cells (DP IB Biology)
Revision Note
Water Movement & Cells
The direction of the net movement of water will depend on whether a cell is placed in a hypertonic or hypotonic solution
In a hypertonic solution there will be a net movement of water out of the cell, as the cytoplasm is more dilute than the outside solution
In a hypotonic solution there will be a net movement of water into the cell because now the outside solution is more dilute than the cytoplasm
In an isotonic solution, the movement of water into the cell will be balanced out by the movement of water out of the cell
There will therefore be no net movement of water into or out of the cell
The cell is now in dynamic equilibrium with the isotonic solution
It is especially important for animal cells to maintain their osmotic concentration as any deviation from this equilibrium may either cause the cell to shrink or burst
Effects of Osmosis on Cells Without Cell Walls
Animal cells lose and gain water as a result of osmosis
As animal cells do not have a supporting cellulose cell wall, the results on the cell are more severe than on plant cells
If an animal cell is placed into a hypertonic solution (more concentrated than the cytoplasm of the cell), it will lose water by osmosis and become crenated (shrivelled up)
This may lead to the formation of blood clots as crenated red blood cells may become stuck while moving through capillaries
If an animal cell is placed into a hypotonic solution (more dilute than the cytoplasm of the cell), it will gain water by osmosis and, as it has no cell wall to create turgor pressure, will continue to do so until the cell membrane is stretched too far and it bursts
Multicellular organisms must therefore maintain isotonic tissue fluid around their cells to prevent these harmful changes from happening
Osmosis in animal cells diagram
The effects of water movement on animal cells
Some unicellular organisms, such as the protozoan Amoeba, live in freshwater aquatic habitats that is hypotonic to their cytoplasm.
There will be a constant net influx of water into the organism by osmosis, which increases the internal pressure
To prevent these organisms from bursting, they contain structures called contractile vacuoles in their cytoplasm
Excess water will be continuously collected in the contractile vacuole and pumped out of the organism to maintain the osmotic concentration of the cytoplasm
Osmosis in an amoeba diagram
The contractile vacuole is responsible for removing excess water from Amoeba to prevent them from bursting
Effects of Osmosis on Cells With Cell Walls
If a plant cell is placed in a hypotonic solution, water will enter the plant cell through its partially permeable cell surface membrane by osmosis, as the solution has a lower solute concentration than the plant cell
As water enters the vacuole of the plant cell, the volume of the plant cell increases
The expanding protoplast (living part of the cell inside the cell wall) pushes against the cell wall and pressure builds up inside the cell
This pressure is known as turgor pressure
The inelastic cell wall prevents the cell from bursting
The pressure created by the cell wall also stops too much water entering and this also helps to prevent the cell from bursting
When a plant cell is fully inflated with water and has become rigid and firm, it is described as fully turgid
This turgidity is important for plants as the effect of all the cells in a plant being firm is to provide support and strength for the plant – making the plant stand upright with its leaves held out to catch sunlight
If plants do not receive enough water the cells cannot remain rigid and firm (turgid) and the plant wilts
The net movement of water into a plant cell will increase the turgor pressure and result in a turgid cell
If a plant cell is placed in a more concentrated solution, water will leave the plant cell through its partially permeable cell surface membrane by osmosis
As water leaves the vacuole of the plant cell, the volume of the plant cell decreases
The protoplast gradually shrinks and no longer exerts pressure on the cell wall
As the protoplast continues to shrink, it begins to pull away from the cell wall
This process is known as plasmolysis – the plant cell becomes flaccid and is said to be plasmolysed
Plasmolysis of a plant cell that has been placed in a solution with a lower water potential than the cell itself
Examiner Tips and Tricks
Remember – plant cell membranes are composed of a phospholipid bilayer and are partially permeable (only certain molecules can cross), whereas plant cell walls are made of cellulose and are freely permeable. Thus, in a plasmolysed cell, the external solution will be exerting pressure on the protoplast, that is, there is not an empty space between the cell wall and protoplast.
Application of Isotonic Solutions in Medicine
In some cases, patients may require an intravenous (IV) drip to treat dehydration or to deliver medicine directly into the bloodstream
It is important that the solution in the IV drip is isotonic in relation to blood plasma
The solution is usually a 0.9% sterile saline solution (saltwater)
If the solution was hypotonic then there would be a net movement of water into red blood cells causing them to burst
This would result in a decrease in the oxygen carrying capacity of blood
A hypertonic IV solution would result in a net movement of water out of the red blood cells causing them to shrivel and become crenated
This would increase the risk of blood clots forming as these red blood cells cannot move freely through capillaries
Another important medical application of isotonic solutions is in the preparation of donated human organs for transplant surgery
These organs must be kept in an isotonic saline solution to prevent damage to the cells due to the net movement of water by osmosis
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