0
macula for static equilibrium and cristae for dynamic equilibrium. All are found in the inner ear.
Wiki User
β 12y ago
Add your answer:
Earn +20 pts
What is the receptor for equilibrium?
The Macula is the receptor for static equilibrium.
Which of the following correctly matches the equilibrium receptor to the type of equilibrium it monitors?
maculae/static equilibrium
What is the sensory receptor for static equilibrium?
macula
What are the receptor cells involved in dynamic equilibrium?
cristae
What Cellular acetylcholine receptor is found in effector organs of the parasympathetic system?
muscarinic receptor
Which two organs respond to changes in blood buffer equilibrium?
There are two organs that show a noticeable response to the changes that occur in blood buffer equilibrium. These two organs are the lungs and kidneys.
Where would you not find a cholinergeric nicotine receptor?
all parasympathetic target organs
Where would you find a cholinergeric nicotinic receptor?
all parasympathetic target organs
Where would you not find cholinergeric nicotinic receptor?
all parasympathetic target organs
Cells of different tissues and organs respond to the same hormone if they have the same kind of molecules?
receptor
What are all the accessory organs?
the process of quantum's being physically distributed through the equilibrium.
explain why hormones in the bloodstream are able only to affect target cells/organs and not other cells/organs?
Hormones in the bloodstream are able to affect target cells/organs and not other cells/organs because of selective permeability. This means that hormones are only able to pass through the cell membrane of certain cells and organs, and not through the cell membrane of other cells and organs. The cell membrane of the target cells and organs are specialized to allow the hormones to pass through, while the cell membrane of other cells and organs are not specialized and are therefore impermeable to the hormones. This is due to the presence of receptor proteins on the cell membrane of the target cells and organs. These receptor proteins can bind to the hormones and facilitate their entry into the cell. Since these receptor proteins are not present on the cell membrane of other cells and organs, the hormones are unable to bind to them and therefore unable to cross the cell membrane. In addition, hormones can be broken down by enzymes in the bloodstream, which means they canβt reach their target cells and organs if they are exposed to the enzymes. This further ensures that hormones only affect the target cells and organs, and not other cells and organs. In summary, hormones in the bloodstream are able to affect target cells and organs and not other cells and organs because of selective permeability and the presence of receptor proteins on the cell membrane of the target cells and organs. Other cells and organs do not have these specialized receptor proteins and therefore cannot be affected by the hormones.
