L25 1502-2024- GFR FINAL.pdf

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1502
Glomerular Filtration Rate &
Renal Clearance
Fall 2024

Lecture 25
Monday, Oct 21: 9am

Dr. Layla Al-Nakkash
[email protected] 1
© L. Al-Nakkash 2020
 Learning Objectives

1. Describe the filtration barrier in the glomerulus.
2. Identify the Starling forces that drive glomerular filtration rate (GFR).
3. Describe how the Starling forces influence GFR.
4. Assess how GFR is calculated using inulin or creatinine.
5. Examine the relationship between GFR and RPF.
6. Describe renal clearance.
7. Examine the relationship between a given substance and the
clearance of inulin (clearance ratio).
8. Examine the differences between filtered load and excretion rate.

© L. Al-Nakkash 2024 2
 Glomerular Filtration
This is the first step in the formation of urine.
RBF enters the glomerular capillaries- a portion of that blood is filtered into
the Bowman’s space (the first part of the nephron).
This filtered fluid is like interstitial fluid : called the ULTRAFILTRATE.
– Ultrafiltrate contains water & all the small solutes in blood.
– Ultrafiltrate does not contain proteins and blood cells.

The forces responsible for glomerular filtration are like those in the capillaries
These are the Starling Forces
The physical
characteristics of the
glomerular filtration wall
control what is filtered
into the Bowman’s space

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© L. Al-Nakkash 2024 1. Describe the filtration barrier in the glomerulus.
 Glomerular Filtration
30,000 x mag

Endothelium: pores ~70-100 nm diameter.Quite large
– Solutes plasma proteins are all filtered across it.

Basement membrane

Epithelium: contains specialized cells-podocytes.
– Attached to the basement membrane by foot processes. A barrier to filtration.
– Between the foot processes are filtration slits

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© L. Al-Nakkash 2024 1. Describe the filtration barrier in the glomerulus.
 Glomerular Filtration
30,000 x mag

In addition to the pore sizes, the glomerular barrier has negative charge.
– Due to the presence of negative charged glycoproteins.
present throughout the glomerular-capillary barrier
Negative charges add an electrostatic component to the filtration process.
– Positive solutes are attracted to the negative charged barrier → more readily filtered.
– Negative solutes are repelled by the negative charged barrier → less readily filtered.

Small solutes are freely filtered across the barrier. i.e., ions: Na, K, Cl, HCO3

Plasma proteins have net negative charge and are less readily filtered (due to both size and charge)

Proteinuria: can result from glomerular diseases where the negative charge
on the barrier is lost, resulting in increase filtration of proteins.

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© L. Al-Nakkash 2024 1. Describe the filtration barrier in the glomerulus.
© L. Al-Nakkash 2024 1. Describe the filtration barrier in the glomerulus.
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 Starling Forces across Glomerular Capillaries
Starling forces/pressures drive filtration across the glomerular capillary wall.
Assume the oncotic pressure of the Bowman’s space = 0.
This is analogous to the interstitial space but here filtration of proteins is negligible

GFR: Glomerular filtration rate
Kf: Hydraulic conductance or filtration coefficient

GFR = Kf [(PGC - PBS) - πGC]
PGC: Hydrostatic pressure in glomerular capillary
PBS: Hydrostatic pressure in Bowman’s space
πGC: Oncotic pressure in glomerular capillary

Kf filtration coefficient: hydraulic conductance/water permeability of the
glomerular capillary wall. What contributes towards it? Water permeability/total surface area
– A much greater volume of fluid is filtered here versus systemic capillaries
PGC hydrostatic pressure in glomerular capillaries: A force that favors filtration.
PGC remains high (45 mmHg) along the entire length of glomerular capillaries.
How is that different to the systemic side? PGC decreases along the capillary length
PBS hydrostatic pressure in Bowman’s space: A force that opposes filtration. This
pressure (10 mmHg) comes from the fluid in the nephron lumen.
πGC oncotic pressure in the glomerular capillaries: A force that opposes filtration.
Determined by the [protein] in the glomerular capillary blood. It increases as fluid is
filtered out of the capillary.
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© L. Al-Nakkash 2024 2. Identify the Starling forces that drive glomerular filtration rate (GFR).
 Starling Forces & Net filtration Pressure
GFR = Kf [(PGC - PBS) - πGC]
GFR: Glomerular filtration rate
Kf: hydraulic conductance, or, filtration coefficient

Bowman’s
Glomerular capsule
Capillary
PBS Note:
πGC – πBS
PGC
πGC
But πBS =0
No proteins in the
Bowman’s space

PGC: hydrostatic pressure in glomerular capillary (driving force for GFR)
PBS: Hydrostatic pressure in Bowman’s space (slows GFR)
π GC: Oncotic pressure in glomerular capillary (due to unfiltered proteins in the capillary –
can not cross the barrier, slows GFR)
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© L. Al-Nakkash 2024 2. Identify the Starling forces that drive glomerular filtration rate (GFR).
 Starling Forces & Net Filtration Pressure
GFR = Kf [(PGC - PBS) - πGC]
=NFP
GFR: Glomerular filtration rate
Kf: hydraulic conductance, or, filtration coefficient
Sample problem:
What is the net filtration pressure,
NFP, given the following pressures?
PGC = 45 mmHg
PBS = 10 mmHg
PBS π GC = 26 mmHg
Kf = 14 ml/min/mmHg
PGC
[(PGC - PBS) - πGC]
πGC NFP = (45 - 10) - 26 = 9 mmHg

What is the GFR?
GFR = Kf [(PGC - PBS) - πGC] i.e. Kf x NFP
PGC: hydrostatic pressure in glom. cap. (driving force for GFR)
PBS: Hydrostatic pressure in Bowman’s space (slows GFR)
GFR = 14 x 9 = 126 ml/min
π GC: Oncotic pressure in glom. Cap. (slows GFR)

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© L. Al-Nakkash 2024 2. Identify the Starling forces that drive glomerular filtration rate (GFR).
 Starling Forces across Glomerular Capillaries
GFR = Kf [(PGC - PBS) - πGC]
A: The pressures at the beginning of the
glomerular capillary. Here blood has just come
from the afferent arteriole and no filtration has
yet occurred. The sum of the three Starling
pressures (the ultrafiltration pressure) is +16
mmHg, favoring filtration (45 -10) -19 A + value
favors filtration

B: The pressures at the end of the
glomerular capillary. Here blood has been
filtered and is about to leave the glomerular
capillary to enter the efferent arteriole. The sum
of the three Starling pressures (the ultrafiltration
pressure) is 0, no filtration occurs, at this point
which is the filtration equilibrium.
Arrow direction indicates filtration out of, or, Which occurs at the end of the glomerular capillary
absorption into the capillary.
Arrow size indicates magnitude of the pressure.
+ indicates the pressure favors filtration.
- Indicates the pressure favors absorption.
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© L. Al-Nakkash 2024 2. Identify the Starling forces that drive glomerular filtration rate (GFR).
 Starling Forces across Glomerular Capillaries
How does filtration equilibrium occur?

Comparing A (the start of the glomerular
capillary) and B (towards the end of the
glomerular capillary) the only pressure that
changed was πGC.
The oncotic pressure of the glomerular capillary blood.

As fluid filters out of the glomerular
capillary blood, what is left behind? Proteins

Thus, the [protein] and πGC INCREASE.

At the end of the glomerular capillary, πGC
increases such that net ultrafiltration
Arrow direction indicates filtration out of, or, pressure will become 0.
absorption into the capillary.
Arrow size indicates magnitude of the pressure.
+ indicates the pressure favors filtration.
- Indicates the pressure favors absorption.
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© L. Al-Nakkash 2024 2. Identify the Starling forces that drive glomerular filtration rate (GFR).
 Changes in Starling Pressure and GFR
Changes in PGC (hydrostatic pressure in
the glomerular capillary) are a result of
changes in the ___________
resistance of the
afferent and efferent arterioles
Constriction of the afferent arteriole will

_____ afferent arteriole resistance.
– This will result in decreased RPF, and
decreased GFR.
– As less blood flows into the glomerular
capillary → PGC will also decrease →
reducing the net ultrafiltration pressure.

When might this occur? Activation of the SNS
or high levels of
PGC: Hydrostatic pressure in glomerular capillary Angiotensin II
(seen during hemorrhage)

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© L. Al-Nakkash 2024 3. Describe how the Starling forces influence GFR.
 Changes in Starling Pressure and GFR
Changes in PGC (hydrostatic pressure in
the glomerular capillary) are a result of
changes in the ___________
resistance of the
afferent and efferent arterioles

Constriction of the efferent arteriole will
_____
 efferent arteriole resistance.
– This will result in decreased RPF, and
increased GFR.
– As less blood flows out of the glomerular
capillary → PGC will increase →
increasing the net ultrafiltration pressure.
When might this occur? Low levels of
angiotensin II

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© L. Al-Nakkash 2024 3. Describe how the Starling forces influence GFR.
 Measurement of GFR
A marker for nephron function
Measured using the clearance of a glomerular marker. Something that:
– is freely filtered across the glomerular capillaries.
– is not reabsorbed or secreted by the renal tubule.
– does not alter the GFR
Inulin fits these criteria. It is very large, not charged, doesn’t bind to plasma proteins,
It is freely filtered across the glomerular capillary wall,
It is neither reabsorbed nor secreted by renal tubular cells.

The amount of inulin filtered across the glomerular capillaries = the
amount excreted in urine. Inulin must be infused (IV). It is not found endogenously
Clearance of inulin = GFR. = excretion rate of inulin or creatinine

RPF: Renal plasma flow

GFR = _[U]inulin /Cr x V_ = Cinulin/Cr
[U]inulin/Cr: [inulin or creatinine] in urine
V = Urine flow rate
[P]inulin/Cr: [inulin or creatinine] in plasma
[P]inulin/Cr Cinulin/Cr: clearance of inulin or creatinine

CREATININE is used clinically- even though it is a product of
muscle metabolism, it is filtered, not reabsorbed/secreted.
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© L. Al-Nakkash 2024 4. Assess how GRF is calculated using inulin or creatinine.
 Measurement of GFR using inulin
Sample problem:
A patient is infused with inulin to measure GFR. The patient’s urine flow is
varied by drinking large volumes of water. [P]inulin is maintained constant
at 1 mg/ml via the infusion.
Before drinking water After drinking water
[U] inulin = 100 mg/ml [U] inulin = 20 mg/ml
V = 1 ml/min V = 5 ml/min
What is the effect of the increase in urine flow on the patient’s GFR?
_[U]inulin x V_ = Cinulin
GFR =
[P]inulin

GFR before _100 mg/ml x 1 ml/min_ GFR after _20 mg/ml x 5 ml/min_
drinking = 1 mg/ml drinking = 1 mg/ml
= 100 ml/min = 100 ml/min
ANSWER: GFR remained constant, even though urine flow changed.
While V increased 5-fold, [U]inulin decreased the same amount.
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© L. Al-Nakkash 2024 4. Assess how GRF is calculated using inulin or creatinine.
 Measurement of Filtration Fraction
This is the relationship between GFR and RPF.
Filtration fraction is the fraction of RPF filtered across the glomerular
capillaries.

Filtration fraction = _GFR_ RBF: Renal plasma flow
GRF: glomerular filtration rate

RPF

The normal filtration fraction is ~ 20% (0.2).
20% of the RPF is filtered and 80% is not filtered.
80% that is not filtered leaves the glomerular capillaries via the efferent
arterioles and becomes the peritubular capillary blood.

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© L. Al-Nakkash 2024 5. Examine the relationship between GFR and RPF.
 Renal Clearance
The rate at which a substance is removed/cleared from plasma.
Renal clearance is the volume of plasma completely cleared of a
substance by the kidneys per unit time.
= urinary excretion or
excretion rate

_[U]x_x V C = clearance
C= [U]x: urine concentration of substance x

[P]x V= urine flow
[P]x: plasma concentration of substance x

Renal clearance is the ratio of urinary excretion/ plasma concentration.

The higher the renal clearance, the more plasma that is completely cleared
of that substance.
A substance with a high renal clearance could be removed with a single
pass through the kidneys (organic acids and bases: PAH, morphine),
whereas a substance with a lower renal clearance may not even be
removed at all (albumin).
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© L. Al-Nakkash 2024 6. Describe renal clearance.
 Measurement of Clearance Ratio for Na+
Sample problem:
A patient is infused with inulin. In a 24-hour period 1.44 L of urine is collected.
The patient’s urine [inulin] is 150 mg/ml and urine [Na+] is 200 mEq/L.
The patient's plasma [inulin] is 1 mg/ml and plasma [Na+] is 140 mEq/L.
What is the clearance ratio for Na+ and how much was reabsorbed?

Urine volume, V = 1.44 L / 24 hr. = 1440 ml/1440 min = 1.0 ml/min Needs to be in ml/min

CNa = [U]Na x V = 200 mEq/L x 1 ml/min =1.43 ml/min
[P]Na 140 mEq/L
Cinulin = [U]inulin x V = 150 mEq/L x 1 ml/min
= 150 ml/min
[P]inulin 1 mEq/L
C Na = _1.43 ml/min_ = 0.01 or 1%
C inulin 150 ml/min
ANSWER:
Sodium is freely filtered across glomerular capillaries.
A clearance ratio of 0.01 means that 1% of sodium filtered, is excreted.
99%
Therefore, how much was reabsorbed ? _____.
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© L. Al-Nakkash 2024 7. Examine the relationship between a given substance and the clearance of inulin (clearance ratio).
 Filtered Load & Excretion Rate
Filtered Load = GFR x [P]x

Excretion Rate = [U]x x V

Filtered load: is the amount of substance
filtered into the Bowman’s space per unit
time. This fluid in the Bowman’s space and
in the nephron lumen is ‘tubular fluid'
Luminal fluid
Excretion rate: is the amount of substance
excreted per unit time. This is the sum of
filtration, reabsorption and secretion.
Reabsorption: many substances are reabsorbed ( ions, glucose) into the peritubular capillary
– required, otherwise they are lost in urine

Secretion: less substances are secreted from the peritubular capillary (K, organic
acids/bases). Allows excretion of these substances
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© L. Al-Nakkash 2024 8. Examine the differences between filtered load and excretion rate.
 Filtered Load & Excretion Rate
= Transport Rate for a substance

Reabsorption
or secretion rate = Filtered Load – Excretion rate
Comparing FL with ER provides information as to whether
a substance has been reabsorbed or secreted

If Filtered load > Excretion rate :
– what do you expect has happened to the substance?
Net reabsorption

If Filtered load < Excretion rate :
– what do you expect has happened to the substance?
Net secretion

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© L. Al-Nakkash 2024 8. Examine the differences between filtered load and excretion rate.
 Filtered Load & Excretion Rate
Reabsorption or secretion rate = Filtered Load – Excretion rate

Sample problem:
A patient has a GFR of 180 L/day and the plasma [Na+] is 140 mEq/L.
The patients voids 1L of urine in 24 hours and the urine [Na+] is 100 mEq/L.

What is the filtered load and excretion rate for sodium? Is this patient
undergoing net sodium secretion or reabsorption?

Filtered Load = GFR x [P]x
= 180 L/day x 140 mEq/L
=25,200 mEq/day
Filtered Load – Excretion rate
Excretion Rate = V x [U]x
= 25,200 - 100 mEq/day
= 1 L/day x 100 mEq/L =25,100 mEq/day
=100 mEq/day
FL > ER = Reabsorption

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© L. Al-Nakkash 2024 8. Examine the differences between filtered load and excretion rate.
 Glomerular filtration is the last step in urine formation
True / False

Starling Forces modify GFR
True / False

GFR is indirectly proportional to NFP
True / False

Unfiltered proteins will ↑ the oncotic P of glomerular capillary blood
True / False

Filtration fraction = RPF / GFR
True / False

Inulin is a glomerular marker
True / False

If Filtered load < excretion rate, we expect a substance is reabsorbed
True / False
© L. Al-Nakkash 2024 22
 Glomerular filtration is the last step in urine formation
True / False First step

Starling Forces modify GFR
True / False GFR = Kf [(PGC - PBS) - πGC]

GFR is indirectly proportional to NFP
PBS) - πGC]
True / False GFR = f GC
K [(P -
NFP= [(PGC - PBS) - πGC]

Unfiltered proteins will ↑ the oncotic P of glomerular capillary blood
True / False ↑ πGC

Filtration fraction = RPF / GFR
True / False =GFR/RPF

Inulin is a glomerular marker
True / False As is creatinine

If Filtered load < excretion rate, we expect a substance is reabsorbed
True / False If FL