3.6.4.3 Control of Blood Water Potential Flashcards
What is osmoregulation?
The homeostatic control of the water potential of the blood
What carries out osmoregulation?
The kidney and in particular, the nephron
What is the shape of the nephron?
A narrow tube closed at one end with two twisted regions separated by a long paperclip loop
What is the structure of the nephron?
Renal capsule Proximal convoluted tubule Loop of Henle Distal convoluted tubule Collecting duct
What is the renal capsule?
The closed end at the start of the nephron
It surrounds a mass of blood capillaries known as the glomerulus
The inner layer is made of specialised cells called podocytes
What is the proximal convoluted tubule?
A series of loops surrounded by blood capillaries
It’s walls are made of epithelial cells and microvilli
What is the loop of Henle?
A long hairpin loop which extends from the cortex into the medulla of the kidney (further towards the centre) and back again
It is surrounded by blood capillaries
What is the distal convoluted tubule?
A series of loops surrounded by blood capillaries
Its walls are made of epithelial cells
Surrounded by fewer capillaries than the proximal tubule
What is the collecting duct?
A tube into which a number of distal convoluted tubules from a number of nephrons empty
Lined with epithelial cells and becomes increasingly wide as it empties
What are the four blood vessels in the nephron? (No explanation)
Afferent arteriole
Glomerulus
Efferent arteriole
Blood capillaries
What is the afferent arteriole?
A tiny vessel which arises from the renal artery and supplies the nephron with blood
The afferent arteriole enters the renal capsule of the nephron where it forms the glomerulus
What is the glomerulus?
A many branched knot of capillaries from which the fluid is forced out of the blood
The glomerulus capillaries recombine to form the efferent arteriole
What is the efferent arteriole?
A tiny vessel that leaves the renal capsule
It has a smaller diameter than the afferent arteriole and so causes an increase in blood pressure within the glomerulus
The efferent arteriole carries blood away from the renal capsule and later branches to form the blood capillaries
What are the blood capillaries in the nephron?
A concentrated network of capillaries that surrounds the proximal convoluted tubule and forms where they reabsorb mineral salts, glucose and water
The capillaries merge together into venules, tiny veins that in turn merge into the renal vein
What are the stages of osmoregulation of the nephron?
The formation of glomerular filtrate by ultrafiltration
Reabsorption of glucose and water by the proximal convoluted tubule
Maintenance of a gradient of sodium ions in the medulla by the loop of Henle
Reabsorption of water by the distal convoluted tubule and collecting ducts
What is the process of the formation of glomerular filtrate by ultrafiltration?
The walls of the glomerulus capillaries are made up of epithelial cells with pores between them
As the diameter of the afferent arteriole is greater than that of the efferent arteriole, there is a build up of hydrostatic pressure
Therefore water, glucose and mineral ions are squeezed out of the capillary to form the glomerular filtrate
Blood cells and proteins do not pass through as they are too large
What is the movement of filtrate out of the glomerulus resisted by?
Connective tissue and epithelial cells
Hydrostatic pressure of the fluid in the renal capsule space
The low water potential of the blood
What modifications cause filtrate to move out of the glomerulus?
The inner layer called podocytes have spaces between them which allows filtrate to pass between these cells rather than through them
The endothelium has spaces between its cells to allow the movement of fluid
During ultrafiltration of the glomerulus, where does filtrate move between?
Filtrate passes from the blood into the renal capsule
Useful substances are small so are reabsorbed
How are the epithelial cells in proximal convoluted tubules adapted to reabsorb substances into the blood?
They have microvili to provide a large surface area
They have infoldings at their bases to to give a larger surface area to transfer reabsorbed substances into blood capillaries
They have a high density of mitochondria to provide ATP for active transport
What is the process for the reabsorption of glucose and water by the proximal convoluted tubule?
Sodium ions are actively transported out of the proximal convoluted tubule cells into blood capillaries which lowers the sodium ion concentration
Sodium ions diffuse down a concentration gradient from the lumen of the proximal convoluted tubule into the epithelial lining cells through carrier proteins via facilitated diffusion
These carrier proteins are of specific types, each of which carries another molecule along with the sodium ions
The molecules which have co-transported into the cells of the proximal convoluted tubule diffuse into the blood. This causes most valuable molecules to be absorbed
What is the purpose of the loop of Henle?
It is responsible for water being reabsorbed from the collecting duct, thereby concentrating the urine so that it has a lower water potential than the blood
What are the two regions of the loop of Henle?
Descending limb: narrow, thin walls which are highly permeable to water
Ascending limb: wider, thick walls which are impermeable to water
What is the process of the loops of Henle?
Sodium ions actively transported out of the ascending limb using ATP provided by mitochondria
This causes a low water potential in the medulla region between the two limbs. No water moves into this region as the walls are impermeable
In the descending limb where the walls are permeable, water enters the interstatial space which then enters blood capillaries by osmosis and is carried away
The filtrate progressively loses water as it moves down the descending limb, reaching its lowest water potential at the tip
At the base of the ascending limb, sodium ions diffuse out of the filtrate and as it moves up they are also actively pumped out which raises the water potential
In the interstatial space between the ascending limb and the collecting duct, there is a water potential gradient with the lowest potential reaching into the medulla
The collecting duct is permeable to water and so as the filtrate moves down it, water passes out. This water passes by osmosis into the blood vessels that occupy this space, and is carried away
As water passes out of the filtrate, its water potential is lowered. However water is lowered in the intestinal space so water continues to move out by osmosis down the whole length of the collecting duct. The counter current multiplier ensures there is always a water potential gradient drawing water out of the tubule
