Glomerular Filtration and Assessment of Renal Function

Question 1

What percentage of cardiac output do the kidneys receive?

Answer 1

20%

Question 2

What is the difference in composition between plasma and interstitial fluid?

Answer 2

Proteins in plasma but not in interstitial fluid

Question 3

What substances are usually excluded from filtrate?

Answer 3

Most plasma proteins

Blood cells

Question 4

What is the role of the fenestrations in the endothelium of the filtration barrier?

What is the role of the negatively charged basement membrane?

Answer 4

Filters out large molecules

Negative charge repels smaller particles (e.g. albumin) which may otherwise fit through the barrier

Question 5

What factors determine glomerular filtration rate? (GFR)

Answer 5

GFR= Kf x NFP

• Kf= glomerular capillary filtration coefficient
• NFP= net filtration pressure

Question 6

What is the GFR?

Answer 6

Glomerular filtration rate: volume of filtrate formed by all the nephrons in both kidneys per unit time

Question 7

What is the glomerular capillary filtration coefficient? (Kf)

Answer 7

Determined by:

• Surface area available for filtration
• Hydraulic conductivity (permeability) of the filtration barrier

Question 8

What is the NFP?

What is it determined by?

Answer 8

The net pressure acting against the filtration barrier. Sum of:

• Glomerular hydrostatic pressure
• Glomerular colloid oncotic pressure
• Bowman’s capsule hydrostatic pressure

NFP = P_G - P_B - π_G + π_B

Question 9

What is the glomerular colloid osmotic pressure?

Why is this same pressure not present in the Bowman’s capsule?

Answer 9

Osmotic pressure exerted by the proteins in the plasma pulling water back into the glomerular capillaries and opposing the glomerular hydrostatic pressure.

Not present in the Bowman’s capsule as proteins are not present in the filtrate.

Question 10

What is the effect of afferent arteriolar constriction and/or efferent arteriolar dilation on glomerular hydrostatic pressure?

Answer 10

Reduced glomerular capillary pressure (P_GC) therefore reduced GFR

Question 11

What is the effect of afferent arteriolar dilation and/or efferent arteriolar constriction on glomerular hydrostatic pressure (P_G)?

Answer 11

Increased glomerular hydrostatic pressure (P_G) therefore raised GFR

Question 12

Which 2 factors can alter glomerular hydrostatic pressure (P_G) independently of arterial blood pressure?

Answer 12

Afferent arteriolar resistance

Efferent arteriolar resistance

Question 13

What are the factors affecting glomerular hydrostatic pressure?

Answer 13

Renal artery pressure

Afferent arteriolar resistance

Efferent arteriolar resistance

Question 14

What substances raise glomerular hydrostatic pressure (and therefore GFR)?

What do they act on?

Answer 14

Vasoconstriction of efferent arterioles:

• Angiotensin II

Vasodilation of afferent arterioles:

• Prostaglandins
• Atrial natriuretic peptide
• Nitric oxide
• Kinins
• Dopamine (low dose)

Question 15

What substances reduce glomerular hydrostatic pressure (therefore GFR)?

Answer 15

Constriction of afferent arterioles:

• Endothelin
• Noradrenaline (sympathetic nervous system)
• Adenosine
• Vasopressin
• Angiotensin II (high dose)
• PG blockade

Dilation of efferent arterioles:

• Angiotensin II blockade

Question 16

Why is reabsorption favoured over filtration in the peritubular capillaries?

Answer 16

• Reduction in capillary hydrostatic pressure
• Increase in colloid osmotic pressure due to concentrating of plasma proteins in blood leaving the glomerulus.

Question 17

What are the mechanisms of autoregulation of GFR?

Answer 17

• Myogenic response
• Tubuloglomerular feedback

Question 18

What is the myogenic response?

Answer 18

Negative feedback loop

Smooth muscle in afferent arterioles respond to changes in vessel circumference by contracting or relaxing:

1. Increase arterial BP
2. Increased renal blood flow and GFR
3. Increased stretch of afferent arteriole smooth muscle cells
4. Ca²⁺ channels open
5. Vasoconstriction of afferent arterioles
6. Increases resistance to flow
7. Prevents changes in renal blood flow to glomerulus therefore GFR.

Question 19

How does tubuloglomerular feedback maintain renal blood flow and GFR if arterial pressure is raised?

Answer 19

1. Increase in arterial BP
2. Increased renal blood flow and GFR
3. Increased [NaCl] delivered to macula densa
4. Release of paracrine factors (e.g. adenosine)
5. Constriction of AA smooth muscle
6. Vasoconstriction of AA
7. Increased resistance to flow
8. Restores normal blood flow and GFR

Question 20

How does tubuloglomerular feedback maintain renal blood flow and GFR if arterial blood pressure falls?

Answer 20

1. Arterial BP falls
2. Decreased glomerular hydrostatic pressure
3. Decreased GFR
4. Less [NaCl] delivered to macula densa (more proximal absorption)
   
   1. Increased renin from granular cells→Increases angiotensin II→Increased efferent arteriole resistance (RAAS system)
   2. Decreased adenosine→ decreased afferent arteriole resistance

Question 21

What does proteinuria/haematuria/albuminuria indicate?

Answer 21

Damage to filtration barrier

Strong association between proteinuria and rate of disease progression in chronic kidney disease

Question 22

What do eGFR/creatinine/urea indicate?

Answer 22

Functional status of the kidney

Question 23

What other tests aside from eGFR can be used to indicate kidney function?

Answer 23

• Calcium/phosphate homeostasis
• U&Es / pH
• Urine volume/ fluid balance
• Haemoglobin

Question 24

How is GFR measured?

Answer 24

Using renal clearance: the volume of plasma from which a substance is completely cleared by the kidneys per unit time.

Question 25

How is renal clearance calculated?

Answer 25

Clearance (ml/min) = V (ml/min) x U (ml/min)

P (mg/ml)

V= volume of urine produced per minute

U= substance concentration in urine

P= Substance concentration in plasma

Question 26

What is the ideal test of GFR?

Answer 26

Renal clearance of inulin = GFR

Question 27

What non-routine test can be used to approximate GFR?

Answer 27

Creatinine

• Breakdown product of creatine, a skeletal muscle component.
• Completely filtered by the kidney and no absorption
• However small amount of secretion means it over-estimates GFR slightly.

Requires 24 hour urine collection: issues with time, compliance, reliability.

Question 28

How can serum urea be used to approximate GFR?

What else should be considered when interpreting a serum urea result?

What should it be compared with when considering renal disease?

Answer 28

• Completely filtered by the kidney but partially reabsorbed.
• Levels rise in kidney disease as GFR falls

However, rise in serum urea can be caused by other factors:

• Dehydration/hypotension
• High protein diet
• GI bleed (digestion and absorption of blood products)
• Increased catabolism
• Drugs: corticosteroids, tetracyclines

Should be compared with serum creatinine: if both raised a fall in GFR is likely. If disproportionately higher than creatinine, consider the above.

Question 29

How is GFR measured routinely?

Answer 29

• Serum creatinine
• Serum urea
• eGFR

Question 30

How can serum creatinine be used to estimate GFR?

What are its limitations?

Answer 30

Completely filtered by kidneys but some secretion also; always slightly higher than true GFR.

Limitations:

• Levels of production varied between individuals
• Relates to muscle mass which varies with:
  
  • Age
  • Sex
  • Malnutrition
  • Amputations/ muscle wasting (less creatinine, can appear normal even if diseased kidneys
  • Ethnicity
• Varies according to diet
• Not useful for early kidney disease (can lose 50% of kidney function and still have normal serum creatinine)

Question 31

How is eGFR calculated?

Answer 31

CKD-EPI equation using serum creatinine, age, sex and ethnicity.

(recommended by NICE)