Osmoregulation
'Osmoregulation' is the active regulation of the osmotic pressure of body fluids to maintain the homeostasis of the body's water content, that is it keeps the body from becoming too dilute or too concentrated. Osmotic pressure is a measure of the tendency of water to move into one solution from another by osmosis. The higher the osmotic pressure of a solution the more water wants to go into the solution. The pressure that must be exerted on the hypertonic side of a selectively permeable membrane to prevent diffusion of water by osmosis from the side containing pure water. Animals in all environments (aquatic and terrestrial) must maintain the right concentration of solutes and amount of water in their body fluids; this involves excretion: getting rid of metabolic wastes and other substances such as hormones which would be toxic if allowed to accumulate in the blood via organs such as the skin and the kidneys; keeping the water and dissolved solutes in balanced is referred to as osmoregulation.Examples of osmotic pressure
- Hypertonic is a solution with higher solute concentration (higher osmotic pressure) than another thus water wants to move in.
- Hypotonic is a solution with lower solute concentration (lower osmotic pressure) than another thus water wants to move out of it.
- Isotonic is solution with the same solute concentration (same osmotic pressure) as another; no net movement of water.
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2 Vertebrate excretory systems 3 References |
Two major types of osmoregulation are osmoconformers and osmoregulators.
Osmoconformers match their body osmolarity to their environment . It can either be active or passive. An example are marine fish. By drinking in sea water, and actively excreting salt out from the gills, the fish will gain salt as it produces an isotonic urine. Osmoregulators tightly regulate their body osmolarity which always stays constant and are more common in the animal kingdom. Osmoregulators actively control salt concentrations despite the salt concentrations in the environment. An example are freshwater fish. The gills actively uptake salt from the environment. Water will diffuse into the fish where the fish will excrete a very hypotonic urine to expel all the excess water.
Kidneys play a very large role in human osmoregulation. Kidneys regulate the amount of water in urine waste. With the help of naturally producing hormones such as antidiuretic hormone, aldosterone, and angiotensin II, the human body can increase permeability of the collecting ducts in the kidney to reabsorb water and prevent it from being excreted.
A major way animals have evolved to osmoregulate is by controlling the amount of water excreted through the excretory system.
Ammonia is a toxic by-product of protein metabolism and is generally converted to less toxic substances after it is produced then excreted; mammals convert ammonia to urea while birds and reptiles form uric acid to be excreted with other wastes via their cloacas.
Four processes occur:
Forms of osmoregulation
Vertebrate excretory systems
Waste products of nitrogen metabolism
How osmoregulation is achieved in vertebrates
References