URINARY SYSTEM

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URINARY SYSTEM

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Title: URINARY SYSTEM

1
URINARY SYSTEM
Medical ppt
http//hastaneciyiz.blogspot.com
2
FUNCTIONS OF THE SYSTEM URINARY

1. FILTERING OF BLOOD
2. REGULATION OF BLOOD VOLUME
3. REGULATION OF BLOOD SOLUTES
4. RBC SYNTHESIS
5. VITAMIN D SYNTHESIS
6. GLUCONEOGENESIS

3
KIDNEY ANATOMY
4
ORGANS OF THEURINARY SYSTEM

1. KIDNEYS
2. URETERS
3. URINARY BLADDER
4. URETHRA

5
ORGANS OF THEURINARY SYSTEM

5. INTERNAL URETHRAL SPHINCTER.
6. EXTERNAL URETHRAL SPHINCTER.

6
LOCATION AND EXTERNALANATOMYOF KIDNEYS

The kidneys lie
behind peritoneum
on the posterior
abdominal wall on
either side of
vertebral column.
The right kidney is
slightly lower than
the left.

7
EXTERNAL ANATOMY OF THE KIDNEY

The covering of kidney consists
of three layers. The inner
layer, the renal capsule, the
middle layer, the adipose
capsule, and the outer, renal
fascia.

8
INTERNAL ANATOMY OF THE KIDNEY

A FRONTAL SECTIONS OF A
KIDNEY REVEALS 3 REGIONS
1. RENAL CORTEX
2. RENAL MEDULLA
3. RENAL PELVIS

9
INTERNAL ANATOMY OF THE KIDNEY
10
RENAL CORTEX

The outer layer
of the kidney
that contain most
of the nephrons.
It is the main site
for filtration,
reabsorption and
secretion.

11
RENAL MEDULLA

Within the renal
medulla are
located the renal
pyramids, renal
papilla, and renal
columns.

12
RENAL MEDULLA

The function of the renal columns is to provide
the space to pass blood vessels to and from the
nephrons.

13
RENAL MEDULLA

Triangular shaped units in the medulla that
house the Loops of Henle and collecting ducts of
the nephron.
Site for the counter-current system that
concentrates salt and conserves water and urea

14
RENAL MEDULLA

The tip of the renal pyramid.
Releases urine into a calyx.

15
INTERNAL ANATOMY OF THE KIDNEY

The nephrons of the
kidneys produces urine. It
flows from the renal papilla,
to the minor calyce, to the
major calyce, to the renal
pelvis, and finally exits the
kidney within the ureter.

16
RENAL PELVIS

The function of the renal pelvis collects urine
from all of the calyces.
The urine then is conducted from the kidney to
the urinary bladder using the ureter.

17
INTERNAL ANATOMY OF THE KIDNEY

Two major blood vessels are
associated with the kidney.
The renal artery, a branch of
the abdominal aorta, and the
renal vein, which empties into
the inferior vena cava.

18
THE NEPHRON
19
TYPES OF NEPHRONS

Cortical nephron
Originates in outer 2/3 of cortex.
Involved in solute reabsorption.
Juxtamedullary nephron
Originates in inner 1/3 cortex.
Important in the ability to produce a
concentrated urine.
Has longer Loop of Henle.

Insert fig. 17.6
20
THE NEPHRON
21
THE NEPHRON

STRUCTURES OF THE NEPHRON
1. BOWMANS CAPSULE
2. PROXIMAL CONVOLUTED TUBULE
3. LOOP OF HENLE
A. DESCENDING LIMB
B. ASCENDING LIMB
4. DISTAL CONVOLUTED TUBULE
THESE EMPTY INTO THE COLLECTING
DUCT OR TUBULES.

22
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25
PROXIMAL CONVOLUTED TUBULE
26
PROXIMAL CONVOLUTED TUBULES

Simple cuboidal
epithelial cells with
prominent brush
borders of
microvilli.

27
DECENDING LIMB OF THE LOOP OF HENLE
28
DECENDING LIMB OF THE LOOP OF HENLE

Simple squamous epithelial cells

29
ASCENDING LIMB OF THE LOOP OF HENLE
30
ASCENDING LIMB OF THE LOOP OF HENLE

Simple cuboidal
epthelial to low
columnar cells.

31
DISTAL CONVOLUTED TUBULE
32
DISTAL CONVOLUTED TUBULES

Simple cuboidal epthelial cells.

33
THE NEPHRON

Simple cuboidal epithelial cells with prominent
brush borders of microvilli.
Simple squamous epithelial cells
Simple cuboidal to low columnar epithelial cells.
Simple cuboidal epthelial cells.

Proximal convoluted tubule
Descending limb of Loop of Henle
Ascending Limb of Loop of Henle
Distal convoluted tubules

34
THE NEPHRON

BLOOD VESSELS OF THE NEPHRON
1. AFFERENT ARTERIOLE
2. GLOMERULUS
3. EFFERENT ARTERIOLE
4. PERITUBULAR CAPILLARIES
5. VASA RECTA

35
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36
JUXTAGLOMERULAR APPARATUS

THE JGA IS LOCATED WHERE
THE INITIAL PORTION OF THE
DISTAL CONVOLUTED TUBULE
LIES AGAINST THE AFFERENT,
AND SOMETIMES THE EFFERENT,
ARTERIOLE.

37
JUXTAGLOMERULAR APPARATUS
38
JUXTAGLOMERULAR APPARATUS

SOME THE SMOOTH MUSCLE CELLS
OF THE AFFERENT ARTERIOLES
ENLARGE AND HAVE
PROMINENT SECRETORY GRANULES
CONTAINING RENIN. THESE
CELLS ARE TERMED JG CELLS, AND
THEY ACT AS BARORECEPTORS.

39
JUXTAGLOMERULAR APPARATUS

THE CELLS OF THE DISTAL
CONVOLUTED TUBULE WHICH
CONTACT THE ARTERIOLES ARE
TERMED THE MACULA DENSA.
THESE CELLS DETECT CHANGES IN
THE RATE AT WHICH URINE FLOW
PAST THEM AND THE CONCENTRATION
OF SOLUTES IN THE URINE.

40
JUXTAGLOMERULAR APPARATUS

THE MACULA DENSA CELLS
TRIGGER THE RELEASE OF
LOCALLY ACTING CHEMICALS
WHICH EITHER VASOCONSTRICT
OR VASODILATE THE AFFERENT
ARTERIOLE. THIS RESULTS IN A
CHANGE THE GFR.

41
KIDNEY PHYSIOLOGY
42
KIDNEY PHYSIOLOGY

URINE FORMATION AND THE
SIMULTANEOUS ADJUSTMENT OF
BLOOD COMPOSITION INVOLVES
THREE MAJOR PROCESSES
1. GLOMERULAR FILTRATION
2. TUBULAR REABSORPTION
3. SECRETION

43
KIDNEY PHYSIOLOGY
44
KIDNEY PHYSIOLOGY

FILTRATION is the movement of substances from the
glomerulus into the lumen
of bowmans capsule. This
forms filtrate.

45
KIDNEY PHYSIOLOGY

REABSORPTION is the
movement of substances,
solutes and water,
across the walls of
nephron into the capillaries
associated with the nephron.

46
KIDNEY PHYSIOLOGY

SECRETION is the movement
of substances from the
capillaries, associated
with the nephron, across the walls of nephron
into the filtrate with the nephron.

47
OSMOTIC EFFECTS

Water serves as the
universal solvent in which
a variety of solutes are
dissolved. Solutes can be
classified as electrolytes
and nonelectrolytes.

48
ELECTROLYTES

Electrolytes have ionic bonds
which allow the compounds
to dissociate into ions in
water. Because ions are
charged particles, they can
conduct an electrical current.

49
ELECTROLYTES

Examples of electrolytes
include inorganic salts,
inorganic and organic
acids and bases, and some proteins.

50
NONELECTROLYTES

Nonelectrolytes have bonds,
usually covalent bonds, that
prevent them from
dissociating in solution.
Therefore, they have
no electrical charge.

51
NONELECTROLYTES

Examples of nonelectrolytes
include glucose, lipids,
creatinine, and urea.

52
OSMOTIC EFFECTS

All dissolved solutes
contribute to the osmotic
activity of a fluid. However,
electrolytes have greater
power because each electrolyte
molecule dissociates into at
least 2 ions.

53
OSMOTIC EFFECTS

Water moves according to
osmotic gradientsfrom
areas of lesser osmolality to
areas of greater osmolality.

54
OSMOLALITY

A solutions osmolality
is number of solute particles
dissolved in one liter of
water. Osmotic activity is
determined only by the
number of solute particles.

55
OSMOLALITY

Ten sodium ions have the
same osmotic activity as ten
glucose molecules or
ten amino acids in the same
volume of solution.

56
OSMOLALITY

Water moves according to
osmotic gradients
from areas of lesser to
higher osmolality.

57
GLOMERULAR FILTRATION

Urine formation begins with
glomerular filtration.
It is a passive process
in which fluids and solutes
are forced through the
glomerular membrane.

58
GLOMERULAR FILTRATION

Substances which pass from
the glomerulus into the
nephron include water,
electrolytes, glucose, amino
acids, vitamins, small
proteins, creatinine,
urate ions, and urea.

59
GLOMERULAR FILTRATION
60
GLOMERULAR FILTRATION

The net filtration pressure
(NFP) is responsible for
filtrate formation.
NFPHPg- (OPg HPc)

61
GLOMERULAR FILTRATION

Glomerular filtration
rate, GFR, is the total amount
of filtrate formed per
minute by the kidneys.
A normal GFR in both
kidneys is 120-125 ml/min or
about 180 l/day

62
GLOMERULAR FILTRATION RATE

FACTORS GOVERNING
FILTRATION RATE
Total surface area available for filtration.
Filtration membrane permeability
Net Filtration Pressure

63
GLOMERULAR FILTRATION

GFR IS HELD RELATIVELY
CONSTANT BY TWO IMPORTANT
MECHANISMS THAT
REGULATE RENAL BLOOD FLOW
1. INSTRINICALLY BY RENAL
AUTOREGULATION
2. EXTRINICALLY BY NEURAL AND HORMONAL CONTROLS

64
RENAL AUTOREGULATION OF GFR

To maintain a stable GFR, the
kidney regulates the diameter
of the afferent arteriole.
therefore, when B.P. decreases
the vessel dilates, and when
B.P. increases the vessel
constricts. This results in a
stable G.F.R.

65
RENAL AUTOREGULATION OF GFR

THE KIDNEY USES TWO
MECHANISMS TO PREFORM
AUTOREGULATION
1. MYOGENIC MECHANISM
2. TUBULOGLOMERULAR FEEDBACK

66
MYOGENIC MECHANISM

The myogenic mechanism is based on
the tendency of vascular
smooth muscle to contract
when stretched. If B.P. is elevated, the
smooth muscle in the afferent arterioles
are stretched. In response, the smooth
muscle contracts, which narrows the
arterioles lumen, and renal blood flow
decreases, which reduces GFR to is previous
level. This mechanism normalizes renal blood
flow
and GFR within seconds after blood pressure
changes.

67
TUBULOGLOMERULAR FEEDBACK

The macula densa cells of the
juxtaglomerular apparatus
respond to changes in the
osmolarity and changes in
flow rate of the filtrate at
the junction of the D.C.T. and
the ascending limb of the loop of
Henle.

68
TUBULOGLOMERULAR FEEDBACK

This results in the secretion
of chemicals which produce
local vasoconstriction of
the afferent and efferent
arterioles. Examples include nitric oxide,
adenosine, endothelin, and prostaglandins.
This mechanism operates more slowly than
the myogenic mechanism.

69
EXTRINIC CONTROL OF GFR

THE GFR CAN ALSO BE CONTROLLED EXTRINICALLY BY
1. SYMPATHETIC NERVOUS SYSTEM
2. RENIN, ANGIOTENSION,
ALDOSTERONE MECHANISM

70
TUBULAR REABSORPTION

The proximal convoluted
tubules are the most active
in tubular reabsorption.
All glucose, lactate, and
amino acids are reabsorbed in this area.

71
TUBULAR REABSORPTION

About 65 of sodium, 70 of
water, are also reabsorbed
90 of bicarbonate ions, 50 of
chloride ions, and 55 of
potassium are reabsorbed in
the proximal convoluted
tubules.

72
TUBULAR REABSORPTION

This large amount of
tubular reabsorption
associated with the pct,
results in the GFR
being reduced from 120 ml/min
to about 40 ml/min.

73
REABSORPTION IN PROXIMAL NEPHRON
74
TUBULAR REABSORPTION

Tubular reabsorption
from the loop of Henle
results in 10 of water
being reabsorbed from the
descending limb, 30 of
potassium ions, 20 of sodium,
and 35 of chloride from the
ascending limb.

75
REABSORPTION IN LOOP OF HENLE
76
REABSORPTION IN LOOP OF HENLE
77
TUBULAR REABSORPTION

Fluids enters the distal
convoluted tubules at a
rate of about 25 ml/min.
because about 80 of the
water in the filtrate has been
reabsorbed.

78
TUBULAR REABSORPTION

As fluid flows through
the DCT, sodium and chloride
are reabsorbed. By the time
fluids reaches the end of the
DCT, about 90 of the filtered
solutes and water has been
returned to the blood.

79
THE COUNTER CURRENTMECHANISM

One of the functions of the
kidneys is to regulate urine
concentration and volume.
The kidneys accomplish this by
the countercurrent
mechanism.

80
THE COUNTER CURRENTMECHANISM

In the kidneys the
countercurrent mechanism
involves the interaction
between the flow of filtrate
through the loops of Henle,
and the flow of blood
through the adjacent vasa recta
blood vessels.

81
THE COUNTER CURRENTMECHANISM

The flow in these two
structures is opposite in
direction.

82
THE COUNTER CURRENTMECHANISM
83
THE COUNTER CURRENTMECHANISM

The NaCl concentration
of the medulla acts as an
osmotic force which draws
water from the descending
limb of the loop of Henle.

84
THE COUNTER CURRENTMECHANISM

This is possible because
the descending limb is lined with
simple squamous epithelial cells,
that are permeable
to water, but, impermeable
to NaCl and other solutes.

85
THE COUNTER CURRENTMECHANISM

The movement of water causes
the osmolarity of the filtrate
to increase from 300 to 1,200
mOSM/L.

86
THE COUNTER CURRENTMECHANISM
87
THE COUNTER CURRENTMECHANISM

The ascending limb of the
loop of Henle reabsorbs
chloride by active transport.
In addition, as chloride moves
from the filtrate it pulls
sodium along into the
medulla.

88
THE COUNTER CURRENTMECHANISM

This is possible because
the ascending limb is
impermeable to water.

89
THE COUNTER CURRENTMECHANISM

The movement of NaCl
into the medulla decreases
the osmolarity of the
filtrate from 1,200 to 100
mOsm/L.

90
THE COUNTER CURRENTMECHANISM
91
THE COUNTER CURRENTMECHANISM

The hyperosmotic medulla
also pulls water from the
collecting ducts. This varies
depending on the amount of
ADH. As water moves from
the collecting duct, urea
follows.

92
THE COUNTER CURRENTMECHANISM

Thus, water is conserved, as well as,
a certain amountof urea. The
urea contributes to the
high osmolarity of the
medulla.

93
THE COUNTER CURRENTMECHANISM

The vasta recta is composed
of capillaries which
surround the loop of henle.
The vessels flow
counter (opposite) to the
loop of Henle and act as a
counter current exchanger.

94
THE COUNTER CURRENTMECHANISM

As blood flows through the
vasa recta it picks up water
and leaves behind NaCl.

95
THE COUNTER CURRENTMECHANISM

Therefore, the vasa recta
returns water back to the
body and the NaCl
maintains the hyperosmotic
medulla.

96
THE COUNTER CURRENTMECHANISM
97
TUBULAR SECRETION

Tubular secretion is the
movement of chemicals
from the blood into the
nephron. This process can
occur in the proximal or
distal convoluted tubules.

98
TUBULAR SECRETION

THIS PROCESS IS IMPORTANT FOR
1. Disposing of substances which were not
filtered.
2. Removal of excess K .
3. Controlling blood ph.
4. Eliminating substances which have been
reabsorbed.

99
TUBULAR SECRETION

Most secretion occurs within
the PCT. Substances such as
neurotransmitters, bile
pigment, uric acid, penicillin,
atropine, morphine, H ,
and ammonia are secreted.

100
TUBULAR SECRETION

The DCT receives mainly
K and H ions from
the blood.

101
SECRETION OF HYDROGEN AND POTASSIUM
102
KIDNEY PHYSIOLOGY

AMOUNT AMOUNT AMOUNT
FILTERED REABSORBED EXCRETED

103
KIDNEY PHYSIOLOGY

If the kidneys filters 16 grams
of NaCl per day, and
reabsorb 14 grams of NaCl
per day, then 2 grams of NaCl
would be excreted by the
kidneys per day.

104
KIDNEY PHYSIOLOGY

Renal clearance refers
to the volume of plasma
that is cleared of a
particular substance in a
given time, usually 1 minute.

105
KIDNEY PHYSIOLOGY

RENAL CLEARANCE CAN
BE CALCULATED USING
RC UV/P
UCONCENTRATION OF SUBSTANCE IN URINE (mg/ml)
V FLOW RATE OF URINE FORMATION (ml/min)
PCONCENTRATION OF SUBSTANCE IN PLASMA (mg/ml)

106
RENAL CLEARANCE

QUESTIONS
1. If the renal clearance rate is to GFR?
2. If the renal clearance rate is greater than
GFR?
3. If the renal clearance rate is less than GFR?

107
RENAL CLEARANCE

1. All of the substance is filteredinulin.
2. All of the substance is filtered and addition
is secretedPAH.
3. Some of the substance is reabsorbedurea.

108
RENAL CLEARANCE
109
HORMONAL CONTROL OF THE KIDNEYS
110
ANTIDIURETIC HORMONE
111
HORMONAL CONTROL OF URINE CONCENTRATION

One of the most
important hormones in
the control of urine
concentration and
volume is antidiuretic
hormone, ADH.

112
ANTIDURETIC HORMONE

Antiduretic hormone
prevents wide variation in
water balance, helping to
avoid dehydration or edema.

113

ADH is synthesized by neurosecretory cells whose
cells bodies are located in the supraoptic nuclei
of the hypothalamus.

114

The ADH is packaged within vacuoles. The
vacuoles move by axonal transport to the axonal
terminals of the neurosecretory cells which make
up the hypothalamic hypophyseal tract. The
vacuoles are stored in the posterior lobe of the
pituitary.

115
ANTIDURETIC HORMONE

The chemical class of ADH
is a protein

116
ANTIDURETIC HORMONE

Solute concentrations in the blood are monitored
by osmoreceptors
in the hypothalamus.
This is an example of humerol control.

117
ANTIDURETIC HORMONE

When solute concentrations
increase, thereby, increasing
osmotic pressure,
the receptors are stimulated.

118
ANTIDURETIC HORMONE

The osmoreceptors,
in turn, stimulate
hypothalamic neurons in the
supraoptic nucleus, which
synthesize ADH.

119
ENDOCRINE SYSTEM
120
ANTIDURETIC HORMONE

Nerve action potentials
trigger the release of ADH
from the axonal terminals
in the posterior lobe of the
pituitary.

121
ENDOCRINE SYSTEM
122
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123
ANTIDURETIC HORMONE

ADH travels through the systemic circulation to
the
distal convoluted
tubules of the nephron
and the collecting ducts.

124
ANTIDURETIC HORMONE

ADH causes water to be
reabsorbed from the
D.C.T. and the collecting
ducts into the capillaries
which surround the nephron.

125
ANTIDURETIC HORMONE

THE RESULTS OF ADH
1. A decrease in osmolality
2. An increase in blood volume
3. A decrease in urine output
4. An increase in the concentration of the urine.

126
ANTIDURETIC HORMONE

This chart is a good summary of the events of ADH.

127
ANTIDURETIC HORMONE

ADH is regulated by
negative feedback when
solute concentrations are
reduced to normal levels the
amount of ADH is reduced.

128
ANTIDURETIC HORMONE

PATHOLOGY
1. Hypersecretion can produce SIADH.
2. Hyposecretion can produce diabetes insipidus.

129
ALDOSTERONE
130
ALDOSTERONE

Aldosterones function is to
help maintain Na ion
balance, and indirectly water
balance and K,
within the fluid compartments
of the body.

131
ALDOSTERONE

The chemical class of
aldosterone is steroid

132
ALDOSTERONE

A decrease in blood pressure

133
ALDOSTERONE

Aldosterone is synthesized by the cells of the
zona
glomerulosa in the
adrenal cortex.

134
ALDOSTERONE

Aldosternone targets the
D.C.T.
of the nephron.

135
ALDOSTERONE

EFFECTS OF ALDOSTERONE
1. REABSORPTION OF Na IONS.
2. WATER IS REABSORB USING THE
SAME TRANSPORT MECHANISM.
3. K IONS ARE SECRETION INTO THE DCT FROM THE
CAPILLARIES.

136
ALDOSTERONE

Aldosterone secretion is
controlled by negative
Feedback.

137
ALDOSTERONE

PATHOLOGY
1. Hypersecretion can produce
aldosteronism.
2. Hyposecretion can produce addison disease.

138
ESTROGEN
139
ESTROGEN

Estrogen is a female sex
hormone produced by
the ovaries.

140
ESTROGEN

EFFECTS OF ESTROGEN
1. Reabsorption of Na ions.
2. Water is reabsorb using the same transport
mechanism.
3. Ca2 deposition into bone.

141
CORTISOL
142
CORTISOL

Cortisol is a hormone
produced by the cortex of
the adrenal gland.
It helps in the conversion of lipids and proteins
to form glucose (gluconeogensis).

143
CORTISOL

EFFECTS OF CORTISOL
1. Reabsorption of Na ions.
2. Water is reabsorb using the same transport
mechanism.
3. Can cause edema.

144
BONE CALCIUM REGULATION
145
CALCITONIN

Calcitonin is a hormone
produced by the thyroid
gland in response to high
levels of Ca2 ions in the
blood.

146
CALCITONIN

EFFECTS OF CALCITONIN
1. Ca2 ion deposition into bone.
2. Inhibit osteoclasts.

147
CALCITONIN
Calcium
148
PARATHYROID HORMONE

Parathyroid hormone
is produced by the
parathyroid gland in response
to low levels of Ca2 ions
in the blood.

149
PARATHYROID HORMONE

EFFECTS OF PTH
1. Causes the break down of the inorganic matrix
of bone, releasing Ca2 ions.
2. Increase absorption of Ca2 ions.
3. Reabsorption of Ca2 ions from the DCT.

150
PARATHYROID HORMONE
Calcium
151
ACID BASE BALANCE

BLOOD pH REGULATED BY
1. KIDNEYS
2. LUNGS
3. BUFFERS IN BLOOD

152
KIDNEY REGULATION

The kidney can regulate
pH by retaining or excreting
hydrogen or bicarbonate
ions.

153
ACID-BASE BALANCE
Blood
H
Kidney Nephron
Urine
HCO3-
154
RESPIRATORY REGULATION

The respiratory system
regulates pH by
regulating the amount
of carbon dioxide in
the blood.

155
CARBON DIOXIDE and pH
CO2 H2O H2CO3 H HCO3-
156
RESPIRATORY REGULATION

If the pH is low, the
respiratory rate will
be decreased, and if the
pH is high, the respiratory
rate will be increased.

157
DISEASES and ABNORMALITIES ASSOCIATED WITH THE
URINARY SYSTEM
158
ACIDOSIS

1. pH below 7.35
2. Depresses the nervous system.

159
ALKALOSIS

1. pH above 7.45.
2. Overexcites the nervous system.

160
RESPIRATORY ACIDOSIS

Any condition that
impairs breathing can
cause respiratory acidosis.
This can result in an increase
in the amount of carbon
dioxide in the blood and a
reduction in the pH.

161
RESPIRATORY ALKALOSIS

Any condition that leads
to hyperventilation can
cause respiratory alkalosis.
This can result in an decrease
in the amount of carbon
dioxide in the blood and a
increase in the pH.

162
METABOLIC ACIDOSIS

Metabolic acidosis is
caused by excess acids in
the blood. This can be the
result of renal disease,
diabetes mellitus, or a
decrease in the number of
bicarbonate ions in the blood.

163
METABOLIC ALKALOSIS

Metabolic alkalosis is
caused by a reduction in the
amount of acid in the blood.
This can be the result of
vomiting, diuretics, or
excessive bicarbonate ions
in the blood.

164
SODIUM

FUNCTIONS
1. Attracts water into the ECF.
2. Nerve impulses.
3. Muscle contraction.

165
HYPERNATREMIA

EXCESS SODIUM
1. Hypertension
2. Muscle twitching
3. Mental confusion
4. Coma

166
HYPONATREMIA

DEFICIENCY OF SODIUM
1. Hypotension
2. Tachycardia
3. Muscle weakness

167
POTASSIUM

FUNCTIONS
1. Attracts water into the ICF.
2. Nerve impulse
3. Muscle contractions

168
HYPERKALEMIA

EXCESS POTASSIUM
1. Can lead to a cardiac arrhythmia
2. Elevated t waves
3. Muscle weakness

169
HYPOKALEMIA

DEFICIENCY OF POTASSIUM
1. Can lead to cardiac arrhythmia.
2. Depressed (flatened) t waves
3. Muscle weakness

170
CALCIUM

FUNCTIONS
1. Matrix of bones and teeth
2. Nerve impulse
3. Muscle contraction

171
HYPERCALCEMIA

EXCESS CALCIUM
1. Excess in calcium in blood
2. Kidney stones
3. Cardiac arrhythmia

172
HYPOCALCEMIA

DEFICIENCY OF CALCIUM
1. Tetany
2. Weak heart muscle contractions.
3. Increased clotting time.

173
URINARY DISEASES

RENAL CALCULI (KIDNEY STONES)
1. Caused by the crystallization of Ca2 and
Mg2 salts in the renal pelvis.
2. If the stone travel down the ureter, the
patient will be in pain.

174
URINARY DISEASES

CYSTITIS
1. Caused by bacteria, usually E. coli,
Klebsiella, or Proteus.
2. Leads to inflammation, fever, increased
urgency and frequency of urination and pain.

175
URINARY DISEASES

GLOMERULONEPHRITIS
1. Caused by inflammation of the
glomerulus due to streptococcal
antibody complexes.
2. Inflammation of the glomerulus
leads to faulty filtration.

176
URINARY DISEASES

INCONTINENCE
1. Caused by loss of the ability to control
voluntary micturition due to age, emotional
disorders, pregnancy, or damage to the nervous
system.
2. Leads to wet clothing.

177
URINARY DISEASES