Ciliates regulate their internal osmotic balance through contractile vacuoles, which pump out excess water. These organelles help prevent swelling and bursting due to the influx of water, maintaining the cell's internal environment stable. Additionally, ciliates can adjust the activities of ion channels and transporters to further regulate osmosis.
Ciliates regulate osmosis through contractile vacuoles, specialized organelles that expel excess water from the cell. These vacuoles collect water through a system of canals and release it to the cell exterior to prevent swelling and bursting due to osmotic pressure.
Ciliates regulate osmosis by using contractile vacuoles, specialized organelles that collect excess water and expel it from the cell. This helps them maintain the balance of water and solutes inside the cell. Additionally, ciliates have a semi-permeable membrane that allows for the selective passage of water and solutes to help control osmotic pressure.
Contractile vacuoles are the structures in protozoans that respond to osmosis by regulating water balance within the cell. They fill with excess water to prevent the cell from bursting due to osmotic pressure, and then release the water outside the cell.
The organelle that removes excess water from the organism in relation to osmosis is the contractile vacuole. It is commonly found in freshwater single-celled organisms to regulate their water balance by expelling excess water that enters the cell through osmosis.
water to move into the cell, causing the cell to swell and eventually burst due to the influx of water.
Ciliates regulate osmosis through contractile vacuoles, specialized organelles that expel excess water from the cell. These vacuoles collect water through a system of canals and release it to the cell exterior to prevent swelling and bursting due to osmotic pressure.
Ciliates regulate osmosis by using contractile vacuoles, specialized organelles that collect excess water and expel it from the cell. This helps them maintain the balance of water and solutes inside the cell. Additionally, ciliates have a semi-permeable membrane that allows for the selective passage of water and solutes to help control osmotic pressure.
Contractile vacuoles are the structures in protozoans that respond to osmosis by regulating water balance within the cell. They fill with excess water to prevent the cell from bursting due to osmotic pressure, and then release the water outside the cell.
When you immerse a living human cell in a hypotonic solution, water will tend to move into the cell through osmosis. This influx of water can cause the cell to swell and potentially burst if the cell cannot regulate the influx by expelling excess water.
Osmosis.
The contractile vacuole in Chlamydomonas helps regulate water balance by periodically expelling excess water that enters the cell through osmosis. It prevents the cell from bursting due to the influx of water, maintaining cellular homeostasis.
The organelle that removes excess water from the organism in relation to osmosis is the contractile vacuole. It is commonly found in freshwater single-celled organisms to regulate their water balance by expelling excess water that enters the cell through osmosis.
Ciliates excrete wastes through a contractile vacuole, which collects excess water and waste materials within the cell and expels them outside. The contractile vacuole helps maintain the osmotic balance within the cell by regulating the water content and removing waste products.
water to move into the cell, causing the cell to swell and eventually burst due to the influx of water.
In a hypotonic environment, cells take in water via osmosis, causing them to swell and potentially burst if the cell wall is not strong enough to withstand the influx of water.
Contractile vacuole helps regulate water intake and prevent bursting in unicellular organisms by pumping out excess water that enters the cell by osmosis.
A hypotonic solution, with a lower solute concentration compared to the inside of the cell, causes water to move into the cell via osmosis. This influx of water makes the cell swell and potentially burst if the osmotic pressure becomes too high.