Update_Urinary System Physiology I_with QA PDF

Summary

This document is a presentation about the urinary system. It covers learning objectives, functions of the kidneys, including hormone and enzyme production. It also includes information about renal clearance, blood flow, and filtration.

Full Transcript

FFFJ 1023: Anatomy, Physiology & Biochemistry

THE URINARY SYSTEM
DR. NUR ‘IZZATI MANSOR
DEPARTMENT OF NURSING
FACULTY OF MEDICINE
UNIVERSITI KEBANGSAAN MALAYSIA
Email: [email protected]

# FPERUKM50Years www.ukm.my/fper INSPIRING FUTURES, NURTURING POSSIBILITIES
 Learning Objectives

1 Explain general functions of the kidney

Describe renal blood flow & plasma flow and factors that control and affect renal
2 blood flow
Explain glomerular filtration rate (GFR), its measurement, factors determining and
3 affecting it

4 Define renal clearance and explain its principles and importance

5 Describe the renal reabsorption of various substances

# FPERUKM50Years INSPIRING FUTURES, NURTURING POSSIBILITIES
The urinary system consists of 3 main components:
1) Kidneys
2) Ureters Nephron is the functional unit of kidney.
3) Urinary bladder

# FPERUKM50Years INSPIRING FUTURES, NURTURING POSSIBILITIES
 What are the Functions of Kidneys?

Most people know that a major function of the kidneys is to remove waste
products and excess fluid from the body in the form of urine.

The more important function of kidney is
to regulate the body homeostasis.

# FPERUKM50Years INSPIRING FUTURES, NURTURING POSSIBILITIES
In general, kidney functions are divided into 4 main functions:

1. Regulation of Body Fluid, Electrolytes and Acid-base balance.
2. Production of Hormones and Enzymes.
3. Elimination of Waste and Foreign substances (from metabolic
reaction)
4. Reabsorption and Metabolism of Amino acids and Glucose.

# FPERUKM50Years INSPIRING FUTURES, NURTURING POSSIBILITIES
 Regulation of Body Fluid, Electrolytes and Acid-base
balance.

Regulate osmotic pressure of body fluid
by excreting osmotically diluted or concentrated urine
Regulate the plasma ionic composition
Regulate acid-base balance
by excreting H+ or HCO3-
Regulate the extracellular fluid (ECF) volume
by controlling Na+ and water excretion
Regulate arterial blood pressure
by adjusting Na+ excretion and producing various substances that
can affect blood pressure

# FPERUKM50Years INSPIRING FUTURES, NURTURING POSSIBILITIES
Production of Hormones and Enzymes
Erythropoietin
1,25-dihydroxycholecalciferol
Renin
Kinins

# FPERUKM50Years INSPIRING FUTURES, NURTURING POSSIBILITIES
 Elimination of Waste and Foreign substances
(from metabolic reaction)
Metabolic reaction
Urea
end-product of protein metabolism
Uric acid
end-product of purine (nucleic acid) metabolism
Creatinine
end-product of muscle metabolism

Foreign substances
Penicillin
Urea
Urobillinogen
# FPERUKM50Years INSPIRING FUTURES, NURTURING POSSIBILITIES
 Which is NOT a function of the kidneys?

A. excrete waste products
B. regulate blood pressure
C. balance fluid and electrolytes
D. white blood cell production

Answer: D. Healthy kidneys produce a hormone called erythropoietin or EPO,
which stimulates the bone marrow to make red blood cells.

# FPERUKM50Years INSPIRING FUTURES, NURTURING POSSIBILITIES
 Structure and Function of Nephron
 Nephron is the basic functional unit of the
kidney. Each part of nephron carry out specific
function (Will be discussed in the following
slide).

 Two basic types of nephrons:
1) Cortical nephrons or superficial nephrons
2) Juxtamedullary nephrons.

 Each nephrons is made up of two major parts
1) Renal corpuscle – consists of glomerulus
and Bowman capsule
2) Renal tubule – consists of proximal
convoluted tubule, loop of Henle, distal
convoluted tubule

# FPERUKM50Years
INSPIRING FUTURES, NURTURING POSSIBILITIES
 Structure and Function of Nephron

 The primary function of the
nephron is to filter the blood
by removing waste, excess
fluid and unwanted ions in
the urine.

 They do this by accomplishing
three key processes —
filtration, reabsorption,
and secretion.

Cocchiaro et al. (2017) Front. Cell Dev. Biol. 5,114.

# FPERUKM50Years INSPIRING FUTURES, NURTURING POSSIBILITIES
 Filtration from blood plasma into
nephron Three Basic Renal Processes:
Afferent Efferent
arteriole arteriole
GF 1. Glomerular filtration refers to the
80% of the plasma movement of fluid and solutes from
that enters the the glomerular capillaries into
Glomerulus glomerulus is not
GF filtered and leaves Bowman’s capsule.
Bowman’s through the efferent
capsule arteriole
TR 2. Tubular reabsorption refers to the
20% of the plasma
that enters the TR movement of materials from the
glomerulus is filtrate in the kidney tubules into the
filtered Peritubular
capillary peritubular capillaries.
TS
To venous
Kidney tubule
system TS 3. Tubular secretion refers to the
(entire length,
uncoiled) (conserved for secretion of solutes from the
the body) peritubular capillaries into the kidney
Urine Excretion (eliminated from the body)
tubules.
Excretion = Filtration - Reabsorption + Secretion
# FPERUKM50Years INSPIRING FUTURES, NURTURING POSSIBILITIES
Which of the following choices correctly traces the route of
glomerular filtrate on its path to the collecting duct of a
nephron?
A. proximal tubule, Bowman’s capsule, descending loop
of Henle, ascending loop of Henle, distal tubule
B. Bowman’s capsule, proximal tubule, descending loop
of Henle, ascending loop of Henle, distal tubule
C. Bowman’s capsule, distal tubule, descending loop of
Henle, ascending loop of Henle, proximal tubule
D. Bowman’s capsule, proximal tubule, ascending loop of
Henle, descending loop of Henle, distal tubule

Answer: B.
# FPERUKM50Years INSPIRING FUTURES, NURTURING POSSIBILITIES
 How are cortical nephrons different from juxtamedullary nephrons?
A. cortical nephrons lie almost entirely outside the renal
medulla.
B. cortical nephrons have an associated vasa recta.
C. cortical nephrons have a longer tubule.
D. there are fewer cortical nephrons.

Answer is A: Cortical nephrons are situated almost entirely within the
cortex, while the far less numerous juxtamedullary nephrons have their
glomeruli adjacent to the medulla and extend their loop of Henle into the
medulla.

# FPERUKM50Years INSPIRING FUTURES, NURTURING POSSIBILITIES
 The Micturition Reflex (Sherwood, pg. 531)

 Micturition, or urination, the process of bladder emptying,
is governed by two mechanisms: the micturition reflex
and voluntary control.
 Micturition reflex is an autonomic spinal cord reflex,
integrated in the sacral segment (S2-4).
 As the bladder is filled with urine, stretch receptor on its
wall is stimulated, and signals are sent to the brain and
spinal cord.
 Signal from the spinal cord reflexively sent back to the
bladder via parasympathetic nerve causing contraction.
 Signals from the brain may facilitate or inhibit
micturition.
 Inhibition of pudendal nerve in the spinal cord causes
relaxation of the external sphincter to facilitate
micturition process.
 Internal sphincter relaxation is caused by contraction of
the bladder

INSPIRING FUTURES, NURTURING POSSIBILITIES
Renal Clearance, Blood Flow & Filtration

# FPERUKM50Years INSPIRING FUTURES, NURTURING POSSIBILITIES
 Renal Blood Flow (RBF)
RBF is volume of blood that reaches kidneys in unit time: determined by pressure
gradient (pressure in renal artery – pressure in renal vein) divided by arteriolar
On Average, the resistance.
heart pumps out the
blood almost 5 L/min
Purpose of high flow:
 to supply enough plasma
for high glomerular
filtration necessary to
regulate fluid and Aorta
electrolytes Interior vena cava
Renal artery
20-25% (~1.25 Renal veins
L/min) of the
Segmental arteries
resting cardiac
output (CO) to Interlobar veins
the kidneys Interlobar arteries

Mechanism that regulate RBF: Arcuate veins
Arcuate arteries
 closely linked to the Only in
regulation of glomerular Interlobular arteries Interlobular veins Juxtaglomerular
nephron
filtration rate (GFR) and
excretory functions of the Peritubular capillaries
Vena recta
Afferent arteriole
kidneys

Glomerular arteries
# FPERUKM50Years
Efferent arteriole
INSPIRING FUTURES, NURTURING POSSIBILITIES
 Substances in the blood plasma pass
through glomerulus

Some will be filtered into the
Bowman capsule

Some filtrates* will be reabsorbed
into the interstitium and capillaries

Some will remain in the renal
tubules and excreted

Renal tubular cells can secrete
substances to be excreted in urine
*What goes into the tubule is called the “filtrate” because it has been filtered out of the blood.
# FPERUKM50Years INSPIRING FUTURES, NURTURING POSSIBILITIES
 Glomerular membrane
Glomerular capillary membrane is
composed of 3 structural layers:
Wall of glomerular capillaries
(endothelial cell layer) with
large fenestration (pores: 70-
100 nm in diameter)

Basement membrane
(collagen & glycoprotein)

Inner layer of Bowman capsule
(epithelial cells with podocytes)

To be filtered, a substance must pass through:
1) The pores between and the fenestrations within the endothelial cells of the glomerular capillary.
2) The basal lamina, an acellular basement membrane
3) The filtration slits between the foot processes of the podocytes in the inner layer of Bowman’s
capsule.
# FPERUKM50Years INSPIRING FUTURES, NURTURING POSSIBILITIES
 Glomerular Filtration Rate (GFR)

GFR is the volume of plasma filtered through the glomerulus per unit time. Normal
GFR = 125 ml/min (7.5 L/hr; 180 L/day). GFR is a crucial determinant of renal function.

 Forces Involved in Glomerular Filtration:
a) Glomerular blood hydrostatic pressure (GBHP) is
the blood pressure in glomerular capillaries. It
promotes filtration by forcing water and solutes in
blood plasma through the filtration membrane.
b) Capsular hydrostatic pressure (CHP) is the
hydrostatic pressure exerted against the filtration
membrane by fluid already in the capsular space
and renal tubule.
c) Blood colloid osmotic pressure (BCOP), which is
due to the presence of proteins such as albumin,
globulins, and fibrinogen in blood plasma, also
opposes filtration.
# FPERUKM50Years
INSPIRING FUTURES, NURTURING POSSIBILITIES
 Glomerular Filtration Rate (GFR) – Cont’d.
 Glomerular filtration is driven by the Starling forces across the
wall and, with the assumption that the oncotic pressure of
Bowman’s space is zero, is described by the Starling equation:

GFR = Kf  [(PGC – PBC) – (πGC – πBC)]
Where,
Kf = Coefficient filtration = surface area  permeability of
capillaries
PGC = Glomerular capillaary hydrostatic pressure
PBS = Bowman space Hydrostatic pressure
πGC = Glomerular capillary oncotic pressure Starling forces
πBS = Bowman space oncotic pressure

 In words, glomerular filtration rate is the product of Kf and the
net ultrafiltration pressure. The net ultrafiltration pressure
(NFP) is the algebraic sum of the three Starling pressures
(omitting the oncotic pressure in Bowman’s space).
 The greater the net ultrafiltration pressure, the higher the rate
of glomerular filtration.
NFP=(PGC – PBC) – (πGC – πBC)
# FPERUKM50Years
INSPIRING FUTURES, NURTURING POSSIBILITIES
 Factors affecting GFR

1. Renal blood flow

 During Baseline: constant blood flow (RBF)
through afferent arteriole, glomerulus and
efferent arteriole constant the hydrostatic
capillary pressure (PGC) constant GFR
 Increase renal blood flow ( RBF) through the
nephron elevates the hydrostatic capillary
pressure ( PGC)  GFR

 And vise versa.

# FPERUKM50Years
INSPIRING FUTURES, NURTURING POSSIBILITIES
 Factors affecting GFR

2. Diameter of glomerular blood vessels
b) Changes to efferent arteriole
a) Changes to afferent arteriole  Mild Constriction: Decrease renal blood flow
( RBF) increase hydrostatic capillary
 Constriction: Decrease renal blood flow
( RBF) reduce the hydrostatic pressure ( PGC)  GFR
capillary pressure ( PGC)  GFR  Extreme Constriction: Decrease renal blood
flow ( RBF) increase the capillary
 Dilation: Increase renal blood flow (
RBF) increase the hydrostatic capillary oncotic force ( πGC)  GFR
pressure ( PGC)  GFR  Dilation: Increase renal blood flow ( RBF)
e.g.: Adrenaline decrease the hydrostatic capillary
Noradrenaline pressure ( PGC)  GFR
e.g.: Angiotensin II e.g.: Angiotensin II
High-protein diet blockade

# FPERUKM50Years INSPIRING FUTURES, NURTURING POSSIBILITIES
 Baseline

The relationship between
afferent and efferent
arteriole resistance and
how this affects blood flow,
pressure and filtration

# FPERUKM50Years
INSPIRING FUTURES, NURTURING POSSIBILITIES
 Factors affecting GFR

3. Coefficient filtration (Kf)
- Pathophysiology caused: Renal disease, diabetes mellitus, hypertension
 Surface area of the membrane
 Contraction of mesangial cells reduces surface area
 Agents that affects mesangial cells:
i. Contraction: PGF2, angiotensin II, norepinephrine, vasopressin
ii. Relaxation: cAMP, PGE2, ANP, Dopamine

 Glomerular capillary permeability
 Size of molecules. Neutral & small molecules ( 8 nm are not filtered
 Charge of molecules. Negatively charged molecules are less easily
filtered (e.g. albumin)
# FPERUKM50Years
INSPIRING FUTURES, NURTURING POSSIBILITIES
 Physiologic Control of GFR

Two major control mechanisms regulate the GFR:
1. Autoregulation, which is; aimed at preventing spontaneous changes
in GFR
2. Extrinsic sympathetic control, which is aimed at long-term
regulation of arterial blood pressure.
i. Nervous regulation (Sympathetic nervous system)
ii. Hormonal regulation

# FPERUKM50Years
INSPIRING FUTURES, NURTURING POSSIBILITIES
 Autoregulation of GFR
Occurs when stretching of blood vessels
(in response to BP) triggers contraction
of arteriolar smooth muscle in the wall
Myogenic mechanism of afferent arterioles, vise versa
(myo- muscle; -genic
producing) This mechanism normalizes RBF and
GFR within seconds after a change in
BP.

An adaptive mechanism that links the
GFR to the concentration of salt in the
Tubuloglomerular tubule fluid at the macula densa in
feedback juxtaglomerular apparatus
Autoregulation prevents inappropriate (from the tubule to
fluctuations in the GFR in response to the glomerulus)
changes in the mean arterial driving pressure Mediators released by macula densa to
within the range of 80 to 180 mm Hg. regulate GFR:
(1) ATP (adenosine)
(2) Nitric oxide (NO), prostaglandins
(PGE2)
# FPERUKM50Years INSPIRING FUTURES, NURTURING POSSIBILITIES
 Myogenic Autoregulation

This response helps limit blood flow into the glomerulus
to normal despite the elevated arterial pressure

# FPERUKM50Years
INSPIRING FUTURES, NURTURING POSSIBILITIES
 *At ascending loop of henley

# FPERUKM50Years
INSPIRING FUTURES, NURTURING POSSIBILITIES
 Mechanism of Tubuloglomerular Feedback
 GFR

 [NaCl] at macula densa

 NaCl uptake via Na+-K+-2Cl-

Macula densa Extraglomerular Granular & Afferent
 ATP & Adenosine release
Tubular fluid mesangial cells *VSM cells arteriole

 Intracellular [Ca2+] in

Vasoconstriction
afferent arteriole smooth
muscle
[NaCl]

Vasoconstriction of
afferent arteriole

 GFR to normal level
*VSM cells: Vascular smooth muscle cells # FPERUKM50Years
INSPIRING FUTURES, NURTURING POSSIBILITIES
Mechanism of Tubuloglomerular Feedback

 Renin released from these cells
then functions as an enzyme to
increase the formation of
angiotensin I, which is converted
to angiotensin II.
 Finally, the angiotensin II
constricts the efferent arterioles,
thereby increasing glomerular
hydrostatic pressure and helping to
return GFR toward normal.

# FPERUKM50Years
INSPIRING FUTURES, NURTURING POSSIBILITIES
 Extrinsic controls of GFR: Neural and endocrine
mechanisms

 The extrinsic control mechanisms have an effect on GFR, but their primary function is to
maintain systemic blood pressure.
 The neural and endocrine mechanisms used in extrinsic controls of GFR include
the sympathetic nervous system and the renin–angiotensin–aldosterone mechanism.

 At rest (normal condition):
 Renal blood vessels are dilated
 Renal autoregulation mechanism prevail

 Under extreme stress,:
 Norepinephrine (NE) is released by sympathetic nervous system; epinephrine (Epi) is
released by the adrenal medulla.
 NE and Epi cause constriction of afferent arterioles, inhibiting filtration and triggering
the release of renin from juxtaglomerular apparatus cells leading to renin-angiotensin
cascade.
 Renal Clearance

Definition Clearance concept

Renal clearance is the volume of blood or  High renal plasma clearance = EFFICIENT

plasma that is “cleaned” or cleared of a EXCRETION of a substance in the urine.

substance by the kidney per minute.  Low renal plasma clearance = INEFFICIENT
EXCRETION of a substance in the urine.
The IMPORTANCE of

Measurement of glomerular filtration rate
renal clearance

(GFR) and Renal Plasma Flow (RPF)

Assess severity of renal damage

Measurement of tubular reabsorption and
secretion

# FPERUKM50Years
INSPIRING FUTURES, NURTURING POSSIBILITIES
 Renal Handling of Substances during urine formation

 Substance W: Filtered & secreted, but not reabsorbed (e.g. H+ ions, Para AminoHippurate (PAH))
 Substance X: Filtered & partially reabsorbed (e.g. Urea, Na+, phosphate.)
 Substance Y: Filtered & completely reabsorbed (e.g. glucose & amino acid)
 Substance Z: Filtered but neither reabsorbed nor secreted (e.g. Creatinine & inulin)
 Renal Clearance (contd.)
Clearance calculation

Clearance rate of a substance X,

UX  V Excretion rate
C (ml/min) = =
Plasma concentration
PX  Inulin clearance can be used to
estimate GFR
 Creatinine clearance is used
Where, clinically to estimate GFR
U = concentration of substance X in urine (mg/ml)
V = urine flow rate (ml/min)
P = concentration of substance X in plasma (mg/ml)

# FPERUKM50Years
INSPIRING FUTURES, NURTURING POSSIBILITIES
 Renal Handling of Inulin INULIN (exogenous), a biologically inert
polysaccharide, can be used to estimate
GFR since it is filtered, but not reabsorbed
or secreted.
UX  V
CInulin =
PX
Amount filtered = Amount excreted Properties of a substance
used for GFR measurement
GFRInulin = CInulin
 Freely filtered
UInulin  V  NOT secreted by the tubular cells
GFR =
PInulin
 NOT reabsorbed by the tubular cells
 1 ml/min
GFR = 125 mg/ml
1.0 mg/ml
 NOT toxic
 NOT be metabolized
GFR = 125ml/min  Easily measurable
 Creatinine clearance

 Creatinine (endogenous) is a by-product of skeletal muscle metabolism and almost
entirely removed from the body through kidneys.
 Measurement of creatinine clearance does not require intravenous infusion into the
patient, this method is much more widely used than inulin clearance for estimating GFR
clinically.
 Creatinine is freely filtered across the glomerular capillaries but also is secreted to a
small extent. Thus, the clearance of creatinine slightly overestimates the GFR.
 Creatinine production is proportional to total muscle mass.
 creatinine clearance can be estimated from serum creatinine concentration
 Creatinine clearance is inversely proportional with extent of renal functional
impairment.
 serum creatinine concentration rises as the creatinine clearance decreases.

# FPERUKM50Years
INSPIRING FUTURES, NURTURING POSSIBILITIES
 Renal Plasma Flow (RPF)

 If a substance is completely cleared from the plasma, the
clearance rate of that substance is equal to renal plasma
flow (RPF). Renal Handling of PAH
 E.g. para-aminohippuric acid (PAH). PAH have the
highest clearances of all substances because they are
both filtered and secreted.

Amount entered kidney = Amount excreted

Properties of a substance used UPAH  V
RPFPAH = CPAH =
for RBF measurement PPAH

 Freely filtered
 NOT reabsorbed
 Secreted 10%

# FPERUKM50Years
90%
INSPIRING FUTURES, NURTURING POSSIBILITIES
 Measurement of RPF using clearance of PAH
 The clearance of PAH can be used as an
estimation of RPF (ERPF). The percentage of PAH
removed from the blood is known as the
extraction ratio of PAH and averages about 90% in
normal kidneys. E.g.:

UPAH  V 5.85  1
ERPFPAH = CPAH = = = 585 ml/min
PPAH 0.01

ERPF 585
Actual RPF = = = 650 ml/min
∗Extraction ratio 0.9
RPF
Renal blood flow =
1 −#𝐻𝑎𝑒𝑚𝑎𝑡𝑜𝑐𝑟𝑖𝑡

650
= = 1182 ml/min
1 −0.45
#Hematocrit = 0.45
PPAH − Renal venousPAH
*Extraction ratio =
PPAH # FPERUKM50Years
INSPIRING FUTURES, NURTURING POSSIBILITIES
 Glucose Clearance
 In normal adult, all glucose filtered are reabsorbed at the proximal
tubule so clearance of glucose = zero. Renal Handling of Glucose
 Amount of glucose reabsorbed is proportionate to the amount
filtered.
 The transport maximum (TmG) for glucose reabsorption is 375
mg/min (man) & 300 mg/min (woman).
 When TmG is exceeded, amount of glucose in the urine rises.
 Filtered load = GFR  Plasma glucose up to transport maximum
(TmG).

E.g.:
Normal plasma glucose = 80 - 100 mg/dL
GFR = 1.25 dL/min.
Filtered load = 1.25 dL/min  100mg/dL = 125 mg/min.

 Since 125 mg/min < 375 mg /min, all the glucose is reabsorbed.
# FPERUKM50Years
INSPIRING FUTURES, NURTURING POSSIBILITIES
 Glucose Clearance (Contd.)

 Glucose is reabsorbed with Na+
in the kidneys by secondary
active transport

 Glucose requires transport for
reabsorption from tubular
lumen into cell

# FPERUKM50Years
INSPIRING FUTURES, NURTURING POSSIBILITIES
 Renal threshold for glucose

 Plasma concentration at which glucose first
appears in the urine

 GFR  Renal Threshold = TmG

 1.25 dL/min  Renal Threshold = 375 mg/min

 Thus, renal threshold = 300 mg/dL

 Actual renal threshold = 200 mg/dL (because
some nephrons have lower absorptive capacity)

# FPERUKM50Years
INSPIRING FUTURES, NURTURING POSSIBILITIES
# FPERUKM50Years
INSPIRING FUTURES, NURTURING POSSIBILITIES
 THANK YOU
GANGWAR ER-DR INSTITUTE

# FPERUKM50Years
INSPIRING FUTURES, NURTURING POSSIBILITIES