3 - Glomerular Filtration Rate and Renal Blood Flow

Question 1

How is renal function quantified for the body? How would you calculate dietary intake?

Answer 1

By utilizing mass balance: amount in = amount out.

Dietary intake = excretion in urine and feces + insensible loss (sweat, respiration).

Question 2

How would you calculate renal function for the whole kidney?

Answer 2

in = out

Renal arterial input = urine output + renal venous and lymphatic output.

Question 3

How would you calculate renal function for the nephron? What is one way this is done clinically?

Answer 3

Filtered + secreted = reabsorbed + excreted

Inulin is a polysaccharide that is filtered but not secreted or reabsorbed so filtration of inulin = excretion of inulin.

Question 4

What does the properties of inulin allow us to infer?

Answer 4

That the amount of inulin filtered is equal to the glomerular filtration rate (GFR) multiplied by the plasma concentration of inulin (Pin)

Question 5

What is the amount of inulin secreted equal to?

Answer 5

The urine flow rate (UF) multiplied by the urine concentration of inulin (Uin).

Question 6

Using what we know about inulin, what is one way to calculate GFR?

Answer 6

Urine flow rate X Urine concentration of inulin / Plasma inulin concentration

GFR = (UF X Uin)/ Pin

Question 7

What is renal clearance? How is the clearance of substance X (Cx) calculated?

Answer 7

The volume of plasma from which a substance has been removed and excreted into the urine per unit of time.

Cx = (UF X Ux) /Px

Where UF = urine flow rate
Ux = urine concentration of substance x
Px= plasma concentration of x

Question 8

What is a second way to assess renal clearance? Which way is preferred?

Answer 8

Creatine clearance.

Inulin is the best way though.

Question 9

How do you calculate creatine clearance?

Answer 9

Ccreat = GFR = (Ucreat X UF)/Pcreat

Question 10

How is GFR-1 estimated clinically?

Answer 10

By using the reciprocal of serum creatinine.

In a steady state, urinary excretion of creatine can be considered a constant K = Ucreat x UF

Then GFR = K/Pcreat

Therefore GFR ~ 1/Pcreat

Question 11

What occurs with creatinine when the GFR is reduced by 50%?

Answer 11

The filtered load, and therefore excretion, of creatinine is instantly reduced by 50%.

Since production of creatinine stays constant, the steady state is not maintained b/c production of creatinine exceeds the excretion.

There will therefore be a retention of creatinine in the body until a steady state is reached.

Question 12

What is the relationship between plasma creatinine and GFR?

Answer 12

As GFR increases, plasma creatinine decreases.

Graph has a characteristic slope downward due to the fact that creatinine is entirely excreted from the body through the kidneys by glomerular filtration.

Question 13

What is another solute whose plasma concentration is dependent on GFR for secretion similarly to creatinine.

Answer 13

Urea, which is very poorly regulated when GFR is decreased.

Question 14

How is GFR related to plasma concentrations of bicarb, calcium, and phosphate?

Answer 14

Bicarb, calcium, and phosphate plasma levels are less dependent on GFR for excretion, and are also poorly regulated (but not as poor as creatinine and urea).

This is because tubular handling of these substances can also be altered to maintain plasma levels.

Question 15

What is the relationship between plasma sodium, potassium, and water to GFR?

Answer 15

Sodium, potassium, and water concentrations in the plasma are well regulated until GFR becomes very low.

Question 16

What do clinical estimates of GFR-2, 3, and 4 take into account that measurements of GFR-1 does not?

Answer 16

More comprehensive - take into account age, weight, body surface area, sex, and ethnicity.

Question 17

How is renal clearance used to assess renal blood flow?

Answer 17

Renal clearance of para-amino-hippuric acid (PAH) is used to obtain an index of renal plasma flow.

PAH is an exogenous compound that is filtered and secreted but not reabsorbed by the tubules.

Question 18

How is PAH in arterial plasma calculated? What do we assume?

Answer 18

PAH in art plasma = PAH in venous plasma + lymph + urine

We assume PAH is completely removed from the plasma by filtration and secretion (filtration + secretion = excretion)

Therefore PAH in art plasma = PAH in urine

Question 19

What is the equation that relates renal plasma flow rate (RPF) to urine concentration of PAH (Upah)? How is Renal plasma flow rate ultimately calculated?

Answer 19

Renal plasma flow rate X Plasma concentration of PAH = urine flow rate X urine concentration of PAH

RPF X Ppah = UF x Upah

Therefore RPF = (UF X Upah)/Ppah

Question 20

What can effective renal plasma flow rate (ERPF) be estimated from? How is this done to be more accurate?

Answer 20

PAH clearance.

Important note is that not all of PAH in the renal artery is removed from the blood.

This means that PAH must be corrected for PAH extraction.

Question 21

How would you correct for PAH extraction to calculate renal plasma blood flow?

Answer 21

RPF = Cpah / Extraction PAH

Question 22

What is the difference between renal blood flow and renal plasma flow?

Answer 22

RBF = RPF / (1-Hct)

Question 23

What is the acute (seconds to minutes) regulation of GFR and RBF? What are two examples.

Answer 23

Responses to changes in art BPvia auto-regulation.

Maintains constancy of filtered load in face of normal second to second changes in renal perfusion pressure.

Myogenic mechanisms and tubuloglomerular feedback.

Question 24

Describe myogenic mechanisms of acute regulation?

Answer 24

Intrinsic properties of blood vessels.

Stretch of smooth muscle, such as that during increased art BP, elicits contraction which elevates resistance and maintains blood flow and GFR constant.

Question 25

Describe tubuloglomerular feedback?

Answer 25

Unique to the kidney.

In response to elevation in perfusion pressure, increased fluid is filtered leading to increased delivery of NaCl to the macula densa.

This delivery causes an increase in vascular resistance.

Question 26

Describe the chronic (minutes to days) regulation of the kidneys?

Answer 26

Changes in neuronal or hormonal input to kidneys in order to set the level of filtered load in an attempt to maintain daily fluid and electrolyte balance.

Nerve activity, hormones, and autacoids alter GFR and RBF to do this.

Question 27

What hormones and autacoids decrease GFR?

Answer 27

Norepinephrine, epinephrine, endothelin, and angiotensin II (can also have no change).

Question 28

What hormones and autacoids increase GFR?

Answer 28

Endothelial derived nitric oxide and prostaglandins.