The Kidney & the Nephron: Extended
The kidneys are located in the back of the abdomen and have two important functions in the body:
They regulate the water content of the blood (vital for maintaining blood pressure)
They excrete the toxic waste products of metabolism (such as urea) and substances in excess of requirements (such as salts)
The Nephron
Each kidney contains around a million tiny structures called nephrons, also known as kidney tubules or renal tubules
The nephrons start in the cortex of the kidney, loop down into the medulla and back up to the cortex
The contents of the nephrons drain into the innermost part of the kidney and the urine collects there before it flows into the ureter to be carried to the bladder for storage
1) Ultrafiltration
Arterioles branch off the renal artery and lead to each nephron, where they form a knot of capillaries (the glomerulus) sitting inside the cup-shaped Bowman’s capsule
The capillaries get narrower as they get further into the glomerulus which increases the pressure on the blood moving through them (which is already at high pressure because it is coming directly from the renal artery which is connected to the aorta)
This eventually causes the smaller molecules being carried in the blood to be forced out of the capillaries and into the Bowman’s capsule, where they form what is known as the filtrate
This process is known as ultrafiltration
The substances forced out of the capillaries are: glucose, water, urea, salts
Some of these are useful and will be reabsorbed back into the blood further down the nephron
Components of filtrate:
2) Selective Reabsorption
Reabsorption of Glucose
After the glomerular filtrate enters the Bowman’s Capsule, glucose is the first substance to be reabsorbed at the proximal (first) convoluted tubule
This takes place by active transport
The nephron is adapted for this by having many mitochondria to provide energy for the active transport of glucose molecules
Reabsorption of glucose cannot take place anywhere else in the nephron as the gates that facilitate the active transport of glucose are only found in the proximal convoluted tubule
In a person with a normal blood glucose level, there are enough gates present to remove all of the glucose from the filtrate back into the blood
People with diabetes cannot control their blood glucose levels and they are often very high, meaning that not all of the glucose filtered out can be reabsorbed into the blood in the proximal convoluted tubule
As there is nowhere else for the glucose to be reabsorbed, it continues in the filtrate and ends up in the urine
This is why one of the first tests a doctor may do to check if someone is diabetic is to test their urine for the presence of glucose
Reabsorption of Water & Salts
As the filtrate drips through the Loop of Henle necessary salts are reabsorbed back into the blood by diffusion and active transport
As salts are reabsorbed back into the blood, water follows by osmosis
Water is also reabsorbed from the collecting duct in different amounts depending on how much water the body needs at that time
What is the process of filtration in the glomerulus?
How do the kidneys regulate the body's fluid and electrolyte balance?
What is the role of the loop of Henle in urine concentration?
How do the kidneys help in maintaining acid-base balance in the body?
What are the differences between cortical and juxtamedullary nephrons?
How does the process of reabsorption occur in the proximal convoluted tubule?
1. How does the presence of glucose in urine indicate a problem with the functioning of the proximal convoluted tubule in diabetic individuals?
2. Why does water follow salts during reabsorption in the Loop of Henle, and how does this process help maintain blood osmolarity?
3. What role does active transport play in the reabsorption of salts in the Loop of Henle, and what would happen if this mechanism failed
4. If a person's body fails to regulate the amount of water reabsorbed in the collecting duct, how could this affect their overall blood pressure and hydration levels?
5.How might a mutation affecting the transport proteins in the proximal convoluted tubule impact glucose reabsorption and overall kidney function?