Reabsorption and Secretion

Question 1

Does filtration or reabsorption occur at glomerular capillaries?

Answer 1

Only filtration

Question 2

Does filtration or reabsorption occur at the peritubular capillaries?

Answer 2

Reabsorption

Question 3

Why is oncotic pressure greater in pertibular capillaries than in glomerular cappilaries?

Answer 3

• Since about 20% of plasma has filtered into Bowman’s capsule in the glomerulus (filtration fraction), the blood remaining in efferent arteriole and then peritubular capillaries has higher concentration of plasma proteins and lower hydrostatic pressure

(First the oncotic pressure of the peritubular capillaries is relatively high because a significant percentage of the vascular fluid is filtered out in the glomerulus and into the tubule, leaving a higher-than-normal concentration of plasma proteins in the blood entering the peritubular capillaries.

Secondly, the hydrostatic pressure of the peritubular capillaries is relatively low because much of the intravascular pressure is lost after blood passes through the afferent and efferent arterioles. Given the high oncotic pressure and low hydrostatic pressure of the peritubular capillaries, there is a large net starling gradient for fluid resorption.)

Question 4

Where does most reabsorption occur?

Answer 4

Proximal convoluted tubule

Question 5

What are the 2 different mechanisms of reabsorption?

Answer 5

• Reabsorbed by carrier mediated transport systems
• Reabsorption of sodium ions

Question 6

What are examples of substances reabsorbed by carrier mediated transport systems?

Answer 6

• Glucose
• Amino acids
• Organic acids
• Sulphate ions
• Phosphate ions

Question 7

What is the maximum capacity of carriers expressed as?

Answer 7

T_M

Question 8

What is T_M due to?

Answer 8

Saturation of the carriers

Question 9

What happens if T_M is exceeded?

Answer 9

Excess substrates enters the urine

Question 10

What do carrier proteins enable?

Answer 10

Large substances like glucose to cross the membrane

Question 11

What is the capacity of reabsorption of large molecules like glucose limited by?

Answer 11

Number of carriers

Question 12

What is renal threshold?

Answer 12

Plasma threshold at which saturation occurs

Question 13

Plasma glucose levels up to what will be reabsorbed?

Answer 13

10mmole/L

Question 14

What happens to glucose beyond the plasma level of 10mmoles/L?

Answer 14

Glucose appears in the urine, so if plasma [glucose] is 15mmoles/L, then 10 is reabsorbed and 5 is excreted

Question 15

Why is T_M set way above normal glucose levels?

Answer 15

Ensures that all valuable nutrients are normally reabsorbed

Question 16

What is the medical term for the appearance of glucose in the urine?

Answer 16

Glycosuria

Question 17

What causes glucosuria?

Answer 17

Failure of insulin, not failure of the kidney

Question 18

What are examples of substances that are regulated by T_M?

Answer 18

Sulphate

Phosphate

Question 19

Is glucose regulated by T_M?

Answer 19

No, insulin and counter-regulatory hormones do

Question 20

How are things, such as sulphate and phosphate, regulated by T_M?

Answer 20

Because T_M is set at a level whereby the normal [plasma] causes saturation, anything above will be excreted therefore achieving plasma regulation:

• Is also subject to PTH regulation for phosphate, PTH causes decreased reabsorption

Question 21

As well as T_M, what else is phosphate regulated by?

Answer 21

• Is also subject to PTH regulation for phosphate, PTH causes decreased reabsorption

Question 22

How does PTH impact phosphate?

Answer 22

PTH causes decreased reabsorption

Question 23

Are sodium ions most abundant in ICF or ECF?

Answer 23

ECF

Question 24

What percentage of sodium is reabsorbed?

Answer 24

99.5%

Question 25

What percentage of sodium reabsorption occurs in proximal tubule?

Answer 25

65-75%

Question 26

How much sodium is filtered each day?

Answer 26

• 180L/day x 142mmol/L = 25560 mmoles/day

Question 27

By what mechanism is sodium reabsorbed?

Answer 27

• Not reabsorbed by a T_M mechanism but by active transport which establishes a gradient for sodium across the tubule wall

Question 28

Explain the process of sodium reabsorption?

Answer 28

1. Active sodium pumps are located on the basolateral surfaces where the is a high density of mitochondria
2. This decreases [Na] in epithelial cells, increasing the gradient for Na ions to move into the cells passively across the luminal membrane

Question 29

Does brush border of proximal tubule cells have a greater or lesser permeability to Na than other membranes?

Answer 29

Greater:

• Due to enormous surface area offered by microvilli and the large number of sodium ion channels which facilitate this passive diffusion of Na

Question 30

Why is reabsorption of Na so important?

Answer 30

It is key to reabsorption of other components of the filtrate

Question 31

How does reabsorption of Na impact the reabsorption of other components of filtrate?

Answer 31

• Negative ions such as Cl^- diffuse passively across the proximal tubular membrane down the electrical gradient established and maintained by the active transport of Na⁺
• Active transport of Na out of tubule followed by Cl creates an osmotic force, drawing water out of the tubule
• H₂O removed by osmosis from tubule fluid concentrates all other substances left in tubule creating outgoing concentration gradients

Question 32

What does the rate of reabsorption of non-actively absorbed solutes (ones that are absorbed due to action of Na reabsorption) dependent on?

Answer 32

• Amount of water removed, which will determine extent of the concentration gradient
• The permeability of the membrane to any particular solute

Question 33

How much urea is reabsorbed?

Answer 33

• Tubule membrane is only moderately permeable to urea, so only about 50% is reabsorbed

Question 34

What is an example of a substance that the tubular membrane is impermeable to?

Answer 34

• Some substances such as insulin and mannitol the tubular membrane is impermeable
  
  • So despite concentration gradient favouring their reabsorption, they cannot gain access through membrane so that all that is filtered stays in the tubule and passes out in urine

Question 35

What establishes the concentration gradients that allows various components of filtrate to be reabsorbed?

Answer 35

Active transport of Na

Question 36

As well as creating concentration gradients for other substances, what else is Na important for?

Answer 36

Sodium is also important for carrier mediated transport systems:

• Substances such as glucose, amino acids share the same carrier molecule as sodium (symport)
• High [sodium] in tubule facilitates and low [Na] inhibits glucose transport
• Na reabsorption is also linked to HCO₃^- ion reabsorption

Question 37

What are some examples of molecules that share the same carrier molecule as Na?

Answer 37

Glucose

Amino acids

Question 38

How does concentration of Na in tubule impact glucose transport?

Answer 38

• High [sodium] in tubule facilitates and low [Na] inhibits glucose transport

Question 39

What transporters does glucose use to be reabsorbed?

Answer 39

1) SGLT from tubule lumen to proximal tubule cell
2) GLUT from proximal tubule cell to interstitial fluid

Question 40

What transporters does Na reabsorption use?

Answer 40

1) SGLT from tubule lumen to proximal tubule cell
2) Na-K-ATPase from proximal tubule cell to interstitial fluid

Question 41

What does tubular secretion do?

Answer 41

Transports substances from peritubular capillaries into tubule lumen and provide a second route into tubule

Question 42

What is tubular secretion for?

Answer 42

Structures which are protein bound since filtration at glomerulus is very restriced, also for potentially harmful substances meaning they can be eliminated rapidly

Question 43

Are carrier mechanisms used for tubular secretion specific or non-specific?

Answer 43

Carrier mechanisms are not very specific:

• So eg organic acid mechanism which secretes lactic and uric acid can also be used for substances such as penicillin, aspirin and PAH
• Similarly, organic base mechanism for choline, creatinine etc can be used for morphine and atropine

Question 44

What carrier mechanism can substances such as penicillin, aspirin and PAH use for tubular secretion?

Answer 44

Organic acid mechanism which secretes lactic and uric acid

Question 45

What carrier mechanism can substances such as morphine and atropine use for tubular secretion?

Answer 45

Organ base mechanism for choline, creatinine etc

Question 46

Where does tubular secretion occur?

Answer 46

Proximal tubule

Question 47

Is K more concentrated in ICF or ECF?

Answer 47

ICF

Question 48

What is normal ECF [K⁺]?

Answer 48

About 4mmol/L

Question 49

When does hyperkalaemia occur?

Answer 49

When ECF [K] increases to 5.5mmol/L

Question 50

What are consequences of hyperkalaemia?

Answer 50

• Decreases resting membrane potential of excitable cells and eventually ventricular fibrillation and death

Question 51

When does hypokalaemia occur?

Answer 51

When ECF [K] falls below 3.5mmol/L

Question 52

What are consequences of hypokalaemia?

Answer 52

• Increases resting membrane potential ie hyperpolarises muscle, cardiac cells leading to arrhythmias and eventually death

Question 53

Explain the renal handling of K?

Answer 53

• K filtered at the glomerulus is reabsorbed, mainly at the proximal tubule
• Changes in K excretion are due to changes in its secretion in distal parts of the tubule
• Any increase in renal tubule cells [K⁺] due to increased ingestion will cause K secretion, while a decrease in intracellular [K] causes reduced secretion

Question 54

What are changes in K excretion due to?

Answer 54

Changes in its secretion in distal parts of the tubule

Question 55

How does intracellular K levels impact K secretion?

Answer 55

• Any increase in renal tubule cells [K⁺] due to increased ingestion will cause K secretion, while a decrease in intracellular [K] causes reduced secretion

Question 56

What is K secretion regulated by?

Answer 56

ICF K levels

Adrenal cortical hormone aldosterone

Question 57

Explain how aldosterone regulates K secretion?

Answer 57

• Increase in [K] in ECF bathing the aldosterone secreting cells stimulates aldosterone release which circulates to kidneys to stimulate increase in renal tubule K secretion
• Aldosterone also stimulates Na reabsorption at the distal tubule but by a different reflex pathway

Question 58

Where is H⁺ actively secreted from?

Answer 58

Are actively secreted from tubule cells (not the peritubular capillaries) into the lumen for acid/base balance