Clinical Chemistry-2 Lecture Prelims PDF

Summary

This lecture covers enzymes as biological catalysts and their role in speeding up chemical reactions. It discusses the importance of enzyme tests in diagnosing diseases and how enzymes work within the body. The lecture also gives examples of enzymes and their specific functions in the body.

Full Transcript

CLINICAL CHEMISTRY-2 LECTURE

PRELIMS TOPIC 1. ENZYMES PT. 1
Lecturer/s: Mr. Christian Villahermosa, RMT, MSMT
August 10, 2023

ENZYMES ENZYMOLOGY
Biologic catalysts
○ Hasten chemical reactions Study of enzymes
Are not consumed during the reactions We have to look for:
Do not undergo a chemical change after the ○ Activity of Enzymes
reactions Different reactions they mediate
Significance in diagnosis,
Why do doctors include enzyme tests as part of lab tests possible diseases the doctor can
for their patients? explore if a certain enzyme is
Enzymes operate as biological catalysts that hasten or increased
speed up chemical reactions. ○ Chemical reactions they catalyze
They facilitate/mediate the fruition of certain biochemical ○ Clinical uses
reactions.
Enzymes make us thrive on this planet. Enzymes do not undergo change.
HOW AN ENZYME INTERACTS INSIDE THE BODY
MAIN ACTION OF ENZYMES
Catalyze/interact with substrate to mediate/facilitate
chemical reactions.

Enzymes are found in the cells and tissues.
They are present only in the circulation at a limited level (low
level)
The bulk of enzymatic concentrations are present in
the cells/tissues where they facilitate chemical
reactions
If they are present at increased levels in the blood,
we can point to a problematic organ.
EXAMPLE…
- ALT (alanine transaminase) is found in the cells of
the liver.
- It is found in low
concentration/circulation but once it
increases in circulation, it will be detected
by the Pentra machine.
- The doctor assumes there is something
wrong with the liver of the patient.
- Enzyme + substrate (object of choice) → basic
requirement
TESTING FOR ENZYMES
- Enzyme alone/ substrate alone → no reaction will
is NOT DIAGNOSTIC for a certain disease.
occur
Purpose: For the doctors to be alerted as to which body part,
- Enzyme + substrate = enzyme-substrate complex
cell/tissue has a problem.
which produces a product and the enzyme
- This helps the doctor on which area to focus.
- During this reaction, the enzyme will not be
- “Narrowing down” of the possible disease
consumed and the form will not be changed
- Disease is Non-specific
- The intact enzyme bound to the substrate is still the
There are enzymes found in so many body parts, rendering
same enzyme that was expelled after products were
enzyme tests for them as impractical.
formed. It retains the same appearance before
binding.
EXAMPLE → LDH
Role: For the substrate to turn into product. (Helper)
LDH is found in the RBCs, many tissues, in the
Only the substrate underwent change. The enzyme
heart, etc., deeming it expensive and unnecessary.
remained intact. (Michaelis-Menten Theory) [see below]

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 Linkage Catalyze one type Chymotrypsin
reaction for a catalyzes the
specific type of hydrolysis of peptide
bond bonds (all types of
protein) [not all, but
If you have this they share the peptide
specific type of bond]
bond, it will bind to
you.

ACTIVE SITE

Comparison of energy required for a chemical reaction to
occur with an enzyme vs. without an enzyme

Even if there is no enzyme, we can expect products to form
because this is the basic rule (substrate will become
product.)
If there is NO ENZYME, products will still be
formed, but at a longer time, and with the utilization
of very high levels of energy. (Lock and Key Model, Emil Fisher in 1894)
Binding of enzyme to a substrate to form a complex
Y axis = Energy usage which will yield a product
X axis = Time required to produce a product Enzyme = as is, no change, no consumption
Red line refers to the process if there is no ACTIVE SITE ⇒ where the substrate binds to an
enzyme presence enzyme
○ A lot of energy is needed, and the ○ Since there is a need to bind for the
production time is slower compared to blue formation of complex and yielding of
line product
○ Our body will choose the ‘with enzyme’
process – every energy we produce is ALLOSTERIC SITE
precious.
○ Enzymes facilitate faster reactions The Allosteric site is where the activators and the
because the alternative may take too long, inhibitors bind (not the substrate)
even months. Activators promote the binding of the enzyme to
Enzymes help break down triglycerides into simpler forms. the substrate.
Inhibitors prevent the binding of the enzyme to the
ENZYME SPECIFICITY substrate
Enzymes may recognize and catalyze: Since BOTH of them are needed, they will bind to
- a single substrate the enzyme in the allosteric site (different from the
- a group of substrates that have specific active site)
functional groups
- A group of substrates that have a ALLOSTERIC INHIBITOR
particular type of bond
TYPES OF ENZYME SPECIFICITY

TYPE REACTION TYPE EXAMPLE

Absolute Catalyze one type of Urease catalyzes only
reaction for a single the hydrolysis of urea
substrate

Group Catalyze one type of Hexokinase adds a
reaction for all phosphate group to
similar substrates hexoses

Looks for a specific
functional group An allosteric inhibitor (red) binds to the allosteric site to
(amino group, prevent the enzyme from binding the substrate
carboxyl group, ester,
etc. made into Inhibitors prevent, so they make sure the substrate
substrate) doesn’t bind to the active site.

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 ○ The shape of the enzyme is changed so
they could not bind. NOTE!
The names of some enzymes do not end in -ase.
○ Examples: pepsin, trypsin
○ Angiotensin-converting enzyme

CLASSIFICATION OF ENZYMES
IN ORDER
1. Oxidoreductases
2. Transferases
3. Hydrolases
4. Lyases
5. Isomerases
6. Ligases

An allosteric activator (green) makes the enzyme better at ENZYMATIC REACTIONS
binding the substrate
Can occur in both ways. There is a forward and reverse
reaction, thats why the arrow points both ways.
TAKE NOTE!
The substrate and the active site are not the same,
1. OXIDOREDUCTASES
so they could not bind
All enzymes in this class can perform oxidation and reduction
What’s needed for them to bind is for the activator
forward and reverse.
to bind to the allosteric site
Oxidation and reduction
○ Oxidation - removal of H ion
Or it could be any electron, but in
Do we have inhibitors in the body? If enzymes are needed this case this is appropriate for
for chemical reactions, why is it that inhibitors exist? Clinical Chemistry
Yes. There are chemical reactions that their ○ Reduction - acceptance of H ion
products can worsen certain conditions.
Gout / increased uric acid – xanthine oxidase will - E.C. 1.1.1.27 : L-lactate NAD+ Oxidoreductase
produce uric acid, and normally the body will get - Lactate Dehydrogenase (removal of
rid of it, uric acid is continuously produced and hydrogen from lactate)
excreted. - This enzyme has a lactate
○ For patients with gout, we have to do substrate.
something to prevent the production of
uric acid. Allopurinol is an inhibitor of
xanthine oxidase.

Same with inflammation, as anti-inflammatory drugs act
as inhibitors.
Inflammation is created by the enzyme
cyclooxygenase which produces prostaglandin.

1. In the forward reaction, the substrate is lactate
NOMENCLATURE OF ENZYMES 2. As Lactate dehydrogenase reacts, it becomes
pyruvate as hydrogen is converted (left lactate)
1. Substrate + -ase (not true to all) 3. This is an oxidation reaction (removal of H ion)
a. Lipid = lipase a. We base it on the substrate
b. Ester = esterase
c. Protein = protease LOOKING AT IT IN REVERSE…
Pyruvate is the substrate, and H binds back to
2. Reaction it catalyzes pyruvate to become lactate
a. Oxidation = oxidase This is now a reduction reaction.
b. Reduction = reductase
c. Hydrolysis = hydrolase 2. TRANSFERASES
d. Dehydrogenase = remove hydrogen atoms Transfer of functional groups other than hydrogen
e. Decarboxylase = remove carboxyl groups from one substrate to another

3. Enzyme Commission Nomenclature (E.C.) - E.C. 2.6.1.1 : L-Aspartate 2-Oxaloglutarate
- E.C. 1.1.1.21 Aminotransferase
1st digit = class - Aspartate Aminotransferase (transfers
2nd digit = subclass amino group)
3rd and 4th = serial number

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 - Aspartate that has NH2 is transferred by 5. ISOMERASES
AST to a-ketoglutarate that has no NH2. Rearrange the functional groups within a molecule
- NH2 is being transferred. and catalyze the conversion of one isomer into
- NH2 of aspartate is being transferred to another
a-ketoglutarate.
- As soon as a-ketoglutarate has NH2, it - Phosphoglycerate mutase
becomes glutamate.
- Aspartate, when removed with NH2,
becomes oxaloacetate.

O-P=O-O is attached to the 3rd carbon
3. HYDROLASES Now it is attached to the 2nd carbon. Therefore it is
Hydrolysis of various bonds named 2-Phosphoglycerate
Addition of water to a bond resulting in bond
breakage 6. LIGASES
○ Loss of substrate
Catalyze the joining of two large molecules by
- E.C. 3.1.1.3 : Triacylglycerol lipase forming a new chemical bond
Accompanied by an ATP-ADP interconversion

1. Lipase with water will break down TAG
(triacylglycerol.)
2. It will become Diacylglyercol with 1 Free Fatty Acid
3= 2+1

4. LYASES
Catalyze the removal of groups from Substrates
without hydrolysis or oxidation; the product contains
double bonds or a ring TERMS
It breaks down a big molecule, WITH NO WATER
INVOLVED. Substrate
○ Enzyme is strained ○ Acted upon by the enzyme
○ Product should always contain either a ○ Specific
double-bond or a ring. Isoenzyme
○ Different form, but with the same action
Cofactor
○ Non-protein molecule
○ Helper of enzyme / promote enzymatic
attachment to the substrate
Some enzymes require cofactor, some do
not
Apoenzyme
○ Polypeptide portion
○ Inactive enzyme
○ Enzyme that requires a cofactor BUT has
not met a cofactor
Holoenzyme
○ Apoenzyme + Coenzyme
○ Enzyme that has met a cofactor

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 ○ Only if it becomes a holoenzyme can it
bind with the substrate.

- Some enzymes require cofactors
- Without cofactors: inactive apoenzyme
- With cofactors: active holoenzyme

COFACTORS
TWO TYPES
Activators or Coenzymes (Bishop)
○ Activators → inorganic substances
Does NOT contain carbon
○ Coenzymes → organic substances
Contains carbon

Other literature divides cofactors based on their binding
tightness. Since there is NO COFACTOR YET, the cofactor in
Prosthetic groups: Tightly bound place will have to be COPPER first.
○ Metal ions (activators) or organic This is an inorganic substance. → Activator
molecules
○ Change to the configuration of the COFACTOR
enzyme/link substrate to the enzyme/
Prosthetic groups
coenzyme
- Heme
○ Copper is a member
- Flavin adenine dinucleotide (FAD)
○ Activators are members
Coenzymes
Coenyzmes: loosely bound
- Flavin mononucleotide (FMN)
○ Organic molecules
- Thiamine pyrophosphate (TPP)
○ “Second substrate” for enzyme reactions
- Nicotinamide adenine dinucleotide (NAD)
- Lipoic acid

Metal ions
- Zn2+
- Cu2+
- Mg2+
PROENZYME
a.k.a Zymogen
Role: enzyme precursor / immature enzyme
Not all enzymes have proenzymes – there are
enzymes where once they are created, they are
good to go.
There are certain enzymes, most especially
digestive enzymes, they express as a proenzyme
EXAMPLE: trypsinogen and trypsin
Trypsinogen is the proenzyme, whereas trypsin is the active
enzyme.
Some enzymes require a coenzyme to facilitate the reaction.
The apoenzyme binds the coenzyme and then the Why is it that some enzymes need to undergo proenzyme
substrate. before it has to become active form?
The coenzyme is a part of the catalytic domain and will either In Trypsinogen, it is produced by the pancreas.
donate or accept functional groups, allowing the reaction to They are proteases (digest proteins)
occur. If the pancreas will produce trypsin right ahead, that
Once the product is formed, both the product and the is grounds for death – trypsin is a protease. If
coenzyme are released. pancreas will produce trypsin right away, it will
digest the pancreas, leading to pancreatitis and
killing the patient.
For safety, if the substrate protein is not present yet,
they will exist in their proenzyme form, which will
not do anything because IT HAS NO ACTIVE SITE.
Trypsinogen will exit the pancreas and go to the
intestine, where proteins are present.
Trypsinogen will become trypsin will become
proteins.
Only in this case, ONLY TRYPSIN IS THE
PROTEASE.

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 ENZYME KINETICS
MICHAELIS-MENTEN THEORY

E + S → E-S → P + E

Vmax
Y axis - velocity of the enzymatic reaction
X axis - substrate concentration
Low substrate, more substrate

- Our enzymes are limited.
- Enzymes are fixed in number, substrates are not. In
other words, if the substrate count is low, there is an
enzyme available to bind to them, that’s why
velocity is going upwards because enzyme and
substrate is available.
- There will come a time where it will just stop (Vmax)
(maximum velocity) because all enzymes are
saturated. All enzymes have been bound to a
substrate at this moment.
- They could not accommodate more substrate.
- This explains the slow digestion.

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 CLINICAL CHEMISTRY-2 - LECTURE

PRELIMS TOPIC 2. ENZYMES PT. 2 / CLINICAL SIGNIFICANCE
Lecturer/s: Mr. Christian John Villahermosa, RMT, MSMT
August 17, 2023

LINEWEAVER-BURK PLOT 1. SUBSTRATE CONCENTRATION
First-Order Reactions
○ Are those which proceed at a rate exactly
proportional to the concentration of ONE
REACTANT
○ In enzymes, when the reaction rate is
directly proportional to the substrate
concentration

Second-Order Reactions
○ Are those in which the rate is proportional
to the product of the concentration of TWO
REACTANTS or THE SQUARE OF THE
CONCENTRATION OF ONE REACTANT

Similarities between 1ST and 2ND order is that the
𝐾𝑚 relationship between SUBSTRATE conc. and VELOCITY. is
1 1 1
𝑉
= 𝑉𝑚𝑎𝑥 [𝑆]
+ 𝑉𝑚𝑎𝑥
DIRECTLY PROPORTIONAL. (S = V | ↑S ↑V)

- Meaning, the MORE substrates you add, the
A double-reciprocal plot of the Michaelis-Menten FASTER is the velocity.
constant which yields a straight line - Which is true because if there are substrates, there
are products nga form.
Difference between Michaelis-Menten Plot &
Zero-Order Reactions
Lineweaver-Burk Plot
○ When the substrate concentration is high
Presents the same thing as with the enough to saturate all available enzymes
Michaelis-Menten Plot (MM Plot), the difference Na saturate na lahat ng enzymes
between the 2 is that the lineweaver-burk plot (LB thus it attained → Maximum
Plot) presents a STRAIGHT LINE compared to the reaction velocity (Vmax)
HYPERBOLA of Michaelis-Menten’s plot. ○ A higher concentration of substrate will no
Another difference is the unit of X and Y axis of the longer result in increased reaction rate
lineweaver-burk plot is the RECIPROCAL of ↑S = No change in V
Michaelis-Menten which are the Velocity and
Substrate concentration
2. ENZYME CONCENTRATION
○ Velocity makita na sa Y axis; Substrate
makita na sa X axis. The HIGHER the enzyme level, the FASTER the
reaction will proceed.
The point of Lineweaver-Burk Plot is to illustrate in another
graph form how the enzyme to substrate reaction occurs. Once the reaction has reached its Vmax it cannot anymore
produce any reaction but when enzyme is added the reaction
But the main graph that we are going to use is the MM Plot, will proceed once again eliminating Vmax.
because in LB Plot, we CANNOT appreciate the reaction ↑E = ↑V
happening because the line is just continuous, unlike in MM
Plot where we can appreciate the reaction or the relationship 3. pH
between velocity and the substrate concentration due to the pH + 7.0 - 8.0 (most enzymes)
curve that it forms. ○ ALP → Has a pH: 9
Changes in pH may DENATURE the enzyme.
FACTORS THAT INFLUENCE ENZYMATIC REACTIONS ○ Denature = Destroyed
Each enzyme operates within a specific pH range
These factors either INCREASE or DECREASE the rate of
reaction

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How to ensure desired pH in reagents? 5. COFACTORS (Activators or Coenzymes)
- The Reagent box contains BUFFERS. It ensures
Non-protein entities that must bind to particular
desired pH is followed; NO MORE MANUAL
enzymes before a reaction occurs
measurement.
○ Activators: Metallic or Nonmetallic
○ Coenzymes: Nucleotide phosphate and
4. TEMPERATURE Vitamins
37° C is the OPTIMAL temp for enzymes (Body
Temp) 6. ACTIVATORS
Denaturation @ 40-50°C (HOT)
Proper substrate binding
Inactivation @ 4-10°C (COLD)
Link substrate to the enzyme or coenzyme
○ Will become INERT
Undergo oxidation or reduction
○ The enzyme you refrigerated for it to
inactivate is the same enzyme you will be
getting if you restore it back to its optimal 7. INHIBITORS
temp Interfere with enzyme reactions
○ Preservation of blood samples in Clinical 3 types of Inhibition
Laboratories is REFRIGERATION. ○ Competitive
Assay temperatures: 25, 30, or 37°C ○ Noncompetitive
○ Uncompetitive

1. Competitive Inhibition: The inhibitor will bind to the ACTIVE SITE.
- So since the active site is occupied by this inhibitor, the substrate cannot bind to the active site where it usually
binds.

2. Noncompetitive Inhibition: The inhibitor will bind to the ALLOSTERIC SITE.
- The allosteric site of the enzyme is occupied by the inhibitor changing now the FORM or the SHAPE of the active
site making it unable for the substrate to bind to the active site.

3. Uncompetitive Inhibition: The inhibitor will bind to the ENZYME-SUBSTRATE COMPLEX.
- This inhibitor is considered smart because it waits for the Enzyme and Substrate to bind first before it binds to the
complex which inhibits the reaction process.
reductase ing agent
IF WE WANT ENZYMES TO PRODUCE A PRODUCT, WHY
DO WE ALLOW INHIBITORS TO EXIST? Pargyline Monoamine Antihypertensive
oxidase agent
Examples of Enzyme Inhibitors with Therapeutic
Applications Penicillin Transpeptidase Antibacterial
agent
Inhibitor Target Enzyme Effect or
Application HMG-CoA = 3-hydroxy-3-methylglutaryl coenzyme A.

Allopurinol Xanthine oxidase Treatment of Gout is the accumulation of URIC ACID.
gout Uric acid came from the breakdown of PURINE.
In order for the purine to become a uric acid it
Aspirin Cyclooxygenase Antiinflammatory needs the help of XANTHINE OXIDASE.
agent

Thymidylate Antineoplastic So if we eat food that is rich in purine our xanthine oxidase
5-Fluorouracil will now convert it into uric acid for it to be urinated.
synthetase agent

Lovastatin HMG-CoA Cholesterol-lower Too much accumulation of uric acid will now be
deposited into our joints and will lead to gout.

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 In patients with gout, uric acid is avoided and the Increase in PRODUCT concentration.
drug ALLOPURINOL inhibits Xanthine oxidase thus ○ How could this be related to enzyme
uric acid production is LOWERED. (Decrease only; activity?
not eliminated totally) Because if there is no enzyme,
there is no product produced.
This is now why inhibitors are allowed to exist. The more product is formed the
more enzymes are present.
LOCK AND KEY THEORY Decrease in SUBSTRATE concentration
○ How could this be related to enzyme
activity?
Because if the substrate is low,
meaning to say that there is an
enzyme that converts the
substrates to products.
The more na ning baba nag level
sa substrates the higher is the
concentration of the enzyme.
Decrease or increase in COENZYME concentration
○ There are coenzymes that can be
ALTERED, DISAPPEAR, UNAFFECTED
or MULTIPLIED when they interfere in an
enzymatic reaction.
The STRUCTURE of the substrate is ○ What is measured here is how many
COMPLEMENTARY to the size and appearance of coenzymes are altered, disappeared,
the active site. unaffected or multiplied.
So when they interact they will just merge as one ○ There is NO FIXED measurement.
perfectly. An increase in the concentration of the altered
coenzyme
According to one journal, this theory is too perfect, too good
to be true. They believe that our body is not THIS PERFECT.

INDUCED FIT THEORY Measuring enzymes directly is difficult.

ENZYMATIC ASSAYS
1. Coupled- Enzyme Assay
Coupling the activity of the enzyme being
tested to another, more easily detectable,
enzyme
○ Measured here is the activity of
ANOTHER ENZYME.
○ This is because enzymes are
There is a CLASH between the structure of the difficult to catch or measure
substrate and the active site of the enzyme. directly, so we need to examine
If a substrate comes close to its target enzyme, the another thing, in order to
active site will CHANGE ITS STRUCTURE to represent our TARGET ENZYME.
accommodate the substrate Coupled-Enzyme meaning you are using
The fact the substrate is CLOSE TO THE ACTIVE MANY ENZYMES.
SITE, is enough to change the structure of the Indirect measurement
active site to accommodate the substrate.
Example of coupled assay reaction:
The enzyme Lysozyme helps kill bacteria by binding to the
polysaccharide coating of the bacteria. The fit is not perfect,
so the shape of the active site changes to fit the
polysaccharide substrate.

This change of shape of the active site is called INDUCED
FIT. By initiating this “induced fit”. the enzyme breaks the Hexokinase (HK) = Auxiliary Enzyme
polysaccharide, ultimately helping kill the bacteria Glucose-6-phosphate dehydrogenase (G-6-PD) = Indicator
Enzyme
MEASUREMENT OF ENZYME ACTIVITY In this type of reaction (CK Enzyme), what is measured here
In the laboratory we do not measure the enzymes directly, is how many Oxidized NADP+ is formed into reduced
but we measure their ACTIVITY; By measuring their activity NADPH.
we will now come up with their concentration.

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 This information is true because, if you can produce But in the laboratory, we do not test for elastase, trypsin,
1 NADPH that is equivalent to 1 CK. pepsin and others. We ONLY test for AMYLASE and LIPASE
○ 1:1 Ratio to diagnose ACUTE PANCREATITIS.
1 NADPH will not be formed without CK
ENDOCRINE AND EXOCRINE FUNCTION OF THE
2. Fixed - Time Method (End point) PANCREAS
Reactants are combined
Endocrine = HORMONES from Pancreatic Islets.
Reaction proceeds for a designated time
○ Exits to the Bloodstream.
Reaction is stopped
Exocrine = Mainly ENZYMES from Acinar cells.
Measurement is made of the amount of
○ Exits through the Pancreatic duct.
reaction that has occurred.
AMYLASE (AMS)
We are given with only 1 RESULT; meaning the
E.C 3.2.1.1 – 1,4-D-Glucan Glucanohydrolase
measurement will only come at the END
Breakdown of starch and glycogen to
monosaccharides
3. Continuous - Monitoring Method (Kinetic Assay)
○ Polysaccharide → Monosaccharide.
Multiple measurements of absorbance
Activators: CALCIUM and CHLORIDE
change
In order for us to know if there are
fluctuations in the absorbance while the
machine is assessing your sample.
○ Increasing in absorbance
○ Decreasing in absorbance

CALCULATION OF ENZYME ACTIVITY

INTERNATIONAL UNIT (IU)
Amount of enzyme that will catalyze the reaction of
1 MICROMOLE OF SUBSTRATE PER MINUTE Amylase follows the LINKAGE specificity; they are bound to
under specified conditions react with structures with α-1,4-glycosidic bonds.
if a structure is present which has that type of bond,
INTERNATIONAL UNIT PER LITER (IU/L) amylase will react.
Enzyme concentration
Used MOSTLY in the hospitals in the laboratory.

KATAL UNIT (mole/s): SI unit
Amount of enzyme that will catalyze the reaction of
1 MOLE OF SUBSTRATE PER SECOND under
specified conditions.
○ 1.0 IU = 16.7 nkat

PANCREATIC ENZYMES The type of amylase that is present in humans is ALPHA (α)
These enzymes are: Beta (β) is found in plants and microorganisms
AMYLASE This picture, the red arrows shows the way alpha
LIPASE amylase breaks down a polysaccharide in a
RANDOM manner.
as long as there is an α-1,4-glycosidic bond

TISSUE SOURCES OF AMS
SALIVARY GLANDS
○ Salivary AMS or PTYALIN
ACINAR CELLS OF THE PANCREAS
○ Pancreatic AMS

Amylase is also found in other organs but their presence in
that organ is negligible.

The fact also that the amylase has 2 major sources makes
the amylase NON-SPECIFIC.
If the patient has increased amylase concentration
then you can narrow it down to 2 organs.
The pancreas does not only produce amylase and lipase, it
also produces many other enzymes such as, elastase,
trypsin, pepsin. PROPERTIES OF AMS

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 MW: 50,000 – 55,000 ○ P3 is usually what's checked when we run
Readily filtered by the glomerulus due to its small a serum sample to check its amylase level
molecular weight. content
○ Once inside the glomerulus it is NOT HIGH P3 is indicative of having
REABSORBED by the tubules. acute pancreatitis
○ Thus we can detect amylase in URINE. These subtypes will only be measured through
The first amylase enzyme ELECTROPHORESIS.
discovered was from a urine ○ because our machines can only detect the
sample. GENERAL amylase; not specific.
MOUTH – initial digestion of starch by salivary AMS
○ Inactivated in the stomach DIAGNOSTIC SIGNIFICANCE
SMALL INTESTINE – final digestion by pancreatic
Acute Pancreatitis
AMS
○ Rise: 5-8 Hrs. after the onset of an attach
If the inflammation of the
ISOENZYMES OF AMS pancreas started at 6pm, later
P-type isoamylase 11pm pa mag start ug rise ang
○ Pancreas level sa amylase
○ P3: Predominant in AP ○ Peak: 24 Hrs.
S-type isoamylase (None pancreas) ○ Normalize: 3-5 days
○ Salivary gland Salivary Gland Lesions
○ Lungs (levels not significant) ○ Parotitis – disease in parotid glands
○ Fallopian tubes (levels not significant) (Mumps)
Intra-abdominal diseases
Each type of isoamylase has 3 subtypes: ○ Negligible
S – 1, 2, 3
P – 1, 2, 3

WHAT IS ACUTE PANCREATITIS? DUCT OBSTRUCTION
Acute pancreatitis has 3 possible causes:
There is something that OBSTRUCTS the
1. Duct Obstruction
pancreatic duct.
2. Acinar Cell Injury
○ Possible cause of obstruction is
3. Defective Intracellular Transport
GALLSTONES AND PARASITES.
because the gallbladder is near
Remember that in our pancreas we have proenzymes which
the pancreas.
acts as a safety net for the pancreas, since proenzymes are
○ The obstruction caused by the gallstone
inactivated protease, no digestion in itself will happen.
causes IMPAIRED BLOOD FLOW.
○ Thus no oxygen can pass through
But if the proenzymes are activated WITHIN the pancreas
○ No oxygen = NECROSIS
then that would lead to some serious trouble and would
○ Will also lead to the PREMATURE
cause the pancreas to be digested by its own enzyme.
ACTIVATION of the enzymes.

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 Pancreas produces Amylase, LIPASE (LPS)
Lipase and Protease. E.C. 3.1.1.3 – Triacylglycerol Acylhydrolase
Which attacks CHO, FATS and Hydrolyzes the ESTER LINKAGE OF FATS to
PROTEINS. produce alcohols and fatty acids.
It can destroy the pancreas if
activated prematurely
ALCOHOLISM
○ Everytime you drink, THICKENED
PROTEIN BLOBS will start to deposit in
your pancreatic duct.
○ Until such time, it will totally obstruct the
pancreatic duct.
○ Alcohol is also TOXIC to the Acinar cells.
○ That is why chronic alcohol ingestion is
bad for the pancreas.
Lipase is bound to react with (Target) ESTER 1 (R1) and
ACINAR CELL INJURY ESTER 3 (R3)
Can be caused by: Alcohol, Drugs, Trauma,
Ischemia and Viruses. TISSUE SOURCES OF LPS
Which leads to the accidental activation of the Primarily in the PANCREAS
enzymes in the pancreas. Also present in liver, stomach, small intestine, white
blood cells, fat cells and milk.
DEFECTIVE INTRACELLULAR TRANSPORT Our tongue has lipase and it is called LINGUA
Inside the acinar cells there is a pathway for the LIPASE.
enzymes that NEEDS to become proenzyme and
enzymes that DOES NOT need to become a PROPERTIES OF LPS
proenzyme. MW: 45,000
For example trypsinogen. This enzyme should have Enzymatic activity is specific for the fatty acid
a different pathway from other enzymes released by residues at positions 1 and 3 of the TAG molecules
the pancreas such as the amylase and lipase. Substrate must be an emulsion for activity to occur
If trypsinogen goes to the pathway where amylase Reaction rate is accelerated by the presence of
and lipase goes then, trypsinogen will be activated COLIPASE and BILE SALTS
into trypsin. ○ Both of them are needed for the reaction of
This is problematic since the trypsinogen was lipase to occur.
activated within the pancreas itself and will now ○ The substrate must be an EMULSION for
lead to the digestion of its own cells. the activity to occur.
Lipase could not act on a lipid if it
ALCOHOLISM AND PANCREATITIS is not emulsified (emulsified by
Chronic alcohol ingestion results in the: bile).
Secretion of protein-rich pancreatic fluid that leads Bile is formed in the LIVER and
to the deposition of thickened protein plugs and stored in the GALLBLADDER.
obstruction of small pancreatic ducts
Transient increase in the pancreatic exocrine
DIAGNOSTIC SIGNIFICANCE
secretion and contraction of the sphincter of Oddi
Direct toxicity in the acinar cells Almost exclusive to the diagnosis of ACUTE
PANCREATITIS
○ Rise: 4-8 hours after onset of an attack
MACROAMYLASEMIA
○ Peak: 24 hours
This is the most common type of Hyperamylasemia ○ Persist for about 8-14 days
○ ↑Amylase yet essentially NORMAL > 14 days rise suggests POOR
Persistent increase in serum amylase is seen PROGNOSIS for pancreatic cyst
without clinical symptoms Can be due to Cancer
○ In these patients, the amylase binds to the (one of the deadliest)
ANTIBODIES or IMMUNOGLOBULINS. Found also in other intra-abdominal conditions
○ AMS molecules combine with IgG or IgA. ○ Duodenal ulcers, perforated peptic ulcers,
○ This molecules combined together will now intestinal obstruction, acute cholecystitis
become a big structure Normal in conditions with SALIVARY GLAND
○ Which cannot be filtered out by the involvement
glomerulus. ○ Patient has increased amylase yet normal
○ So it will GO BACK to the blood lipase; possible issue is in the salivary
circulation. gland.
○ Thus, having increased AMS yet the ○ If this was Acute pancreatitis bothe
patient feels normal. amylase and lipase should be high.

Made by Miguel Astronomo and Daniel Budo 6
 CLINICAL CHEMISTRY-2 - LECTURE

PRELIMS TOPIC 3. LIVER ENZYMES / CLINICAL SIGNIFICANCE
Lecturer/s: Mr. Christian John Villahermosa, RMT, MSMT
August 28, 2023

ASPARTATE AMINOTRANSFERASE Vit. B6 is acquired through diet, thus a patient
serum should contain enough Vit. B6 in order for
the reaction to occur.
ENZYME 2.6.1.1
CLASSIFICATION
Why do these enzymes exist?
SYSTEMATIC L-Aspartate: 2-oxoglutarate Functions in the synthesis and degradation of
NAME Aminotransferase amino acids.
○ 1 amino acid is broken down and 1 amino
FUNCTION AND Transfer of an amino group acid is born.
PRODUCT between aspartate and alpha-keto ○ One amino acid has to go and 1 amino
acids to form oxaloacetate and
acid has to be produced because if you
glutamate
compare the two, GLUTAMATE is more
FORMER NAME Serum glutamic-oxaloacetic important.
transaminase (SGOT or GOT) ○ Because glutamate is a
NEUROTRANSMITTER
COFACTOR Pyridoxal phosphate (Vitamin B6)
What is the purpose of the keto acid formed from the
enzymatic reaction?
Ketoacids formed are ultimately oxidized by the
tricarboxylic acid.
○ They are sent to the TCA cycle
(Tricarboxylic Acid Cycle) to become an
energy source.

ISOENZYMES FRACTIONS
Both enzymatic reactions (AST & ALT) involve 1 Inside the hepatocyte, AST has a higher
AMINO ACID and 1 KETOACID. concentration than ALT.
○ In the forward reaction: Involves the giving ○ Cell cytoplasm (ASTc)
up of the amino acid group of L-Aspartate Predominant form in serum
to 2-Oxoglutarate ○ Mitochondria (ASTm)
○ In doing so, glutamate and oxaloacetate Increased in disorders producing
are formed CELLULAR NECROSIS

2-Oxoglutarate → L-Glutamate (Amino acid) Location of the Hepatocellular Enzymes
L-Aspartate → Oxaloacetate (Keto acid).
MODERN NAME is derived from the amino acid
substrate of the forward reaction (In this case:
Aspartate)
FORMER NAME is derived from the products of the
forward reaction.

Case from Henry’s
A patient with Cirrhosis (scarring of the liver) both
AST and ALT should be INCREASED.
Now when an ALCOHOLIC patient with
CIRRHOSIS undergoes testing both the enzymes
are at normal ranges.
The reason behind the normal test results of an
alcoholic w/ cirrhosis patient is that TOO MUCH
ALCOHOL INTAKE can ELIMINATE Pyridoxal
Phosphate (Vit. B6).
The major diagnostic hepatocellular enzymes are
○ Without Vit. B6 → AST/ALT reaction will
located at various sites in the hepatocyte, giving
not occur

Made by Miguel Astronomo and Daniel Budo 1
 rise to different patterns of enzyme release with ALP was NOT REQUESTED because if the hepatocyte is
different causes of injury. damaged at one end (hepatocyte facing the bloodstream) the
Alanine aminotransferase (ALT) and the other hepatocyte facing the canaliculi end REMAINS
cytoplasmic isoenzyme of aspartate INTACT.
aminotransferase (ASTC) are found primarily in - Remember that AST and ALT are found in the
the cytosol. cytoplasm and when the viral infection destroys the
○ With membrane injury, as in viral or hepatocyte, it will cause leakage.
chemically in-duced hepatitis, these - Ni gawas na nuon si ALT and AST
enzymes are released and enter the (Specifically ASTC; not so much ASTm)
sinusoids, raising plasma AST and ALT - Causing now increased AST and ALT in our serum.
activities.
Mitochondrial aspartate aminotransferase ASTc is leaked along with ALT but not ASTm
(ASTm) is released primarily with mitochondrial
injury caused by ethanol, as in alcoholic hepatitis. Hepatobiliary (ALP)
Alkaline phosphatase (ALP) and y-glutamyl ○ ALP is what is tested in this disorder
transferase (GGT) are found primarily on the ○ Common example: GALLSTONE or
canalicular surface of the hepatocyte. OBSTRUCTION sa bile duct
○ Bile acids accumulate in cholestasis and ○ If there is an obstruction in the bile duct,
dissolve membrane fragments, releasing the bile cannot pass through therefore it
bound enzymes into plasma. will go back.
GGT is also found in the microsomes, represented ○ Which now damages the hepatocytes,
as pink rings in the figure; microsomal specially the part of the hepatocyte facing
enzyme-inducing drugs, such as phenobarbital and the canaliculi.
Dilantin (phenytoin), can also increase CGT
synthesis and raise plasma GGT activity. The location of the enzyme can be a clue of what disorder a
person might have. All 3 of them are LIVER ENZYMES but
AST is found in: Cytosol and Mitochondria they have different directions and diagnosis.
ALT is found in: Cytosol
ALP is found in: One part only (hepatocyte facing the DIAGNOSTIC SIGNIFICANCE
canaliculi) Limited mainly to the evaluation of hepatocellular
disorders and skeletal muscle involvement
In diagnosing AMI it is not useful because a rise in
AST does not automatically refer to AMI.
Remember in AMI time is of the essence; it has to
be diagnosed immediately
○ ACUTE MYOCARDIAL INFARCTION
Rise: 6-8 hours
Peak: 24 hours
Normalizes within 5 DAYS
Not useful in the
One end of the hepatocyte is near the canaliculi, the diagnosis of AMI
other is near the blood vessel. ○ Pulmonary embolism
ALP is seen in the area of the hepatocyte closest to ○ Congestive heart failure
the bile. ○ Acute hepatocellular Disorders
Viral hepatitis: 100 times upper
LIVER DISORDERS limit of Normal (ULN)
Hepatocellular (ALT & AST) Ex. 30-60, in this case
○ Diseases that damage the hepatocyte the ULN is 60,
directly. 100 times of 60 that is
e.g. Hepatitis and Cirrhosis the usual value of the
○ Hepatitis B is a viral infection and can be patient if the patient has
acquired through sex or contaminated Acute hepatocellular
blood products Disorder.
○ Which will go through our blood circulation Liver Cirrhosis: 4 times ULN
and will travel all throughout the body. ○ Muscular Dystrophies: 4-8 times ULN
○ Once they reach the liver, from the blood ○ Inflammatory conditions
vessel, the viral infection will target the
hepatocyte facing the bloodstream.
○ So what is damaged is the entire
hepatocyte.That's why in hepatocellular
disorders what is requested is AST and
ALT alone.

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 ALANINE AMINOTRANSFERASE
4. Kidney 5. Pancreas
5. Pancreas 6. Spleen
ENZYME 2.6.1.2 6. Erythrocytes 7. Erythrocytes
CLASSIFICATION
Intracellular level: 7000 Intracellular level: 3000
SYSTEMATIC L-Alanine: 2-oxoglutarate times more than plasma times more than plasma
NAME Aminotransferase
AST is not used as a marker of a heart problem because it is
FUNCTION AND Transfer of an amino group found in SO MANY OTHER tissue sources.
PRODUCT between alanine and alpha- keto
- We have TROPONIN I for cardiac tissues.
acids to form glutamate and
pyruvate
PHOSPHATASES
FORMER NAME serum glutamic-pyruvic
transaminase (SGPT or GPT)
Alkaline Phosphatase Acid Phosphatase
(ALP) (ACP)
COFACTOR Pyridoxal phosphate (Vit. B6)
Tissue Sources: Tissue Sources
1. Liver - focus 1. Prostate (richest
a. Sinusoidal and source)
bile canalicular 2. Bone
membranes 3. Liver
2. Bone - focus 4. Spleen
a. Osteoblasts 5. Kidney
6. RBC
3. Intestine 7. Platelets
4. Spleen
The same chemical reaction with the AST, the only 5. Placenta
difference is the substrate used and the product 6. Kidney
produced.
○ Instead of L-Aspartate on the amino group ALKALINE PHOSPHATASE (ALP)
substrate we now use L-Alanine which will
yield Pyruvate
ENZYME 3.1.3.1
2-Oxoglutarate → L-Glutamate (Amino acid) CLASSIFICATION
L-Alanine → Pyruvate (Keto acid)
SYSTEMATIC Orthophosphoric Monoester
NAME Phosphohydrolase (Alkaline
DIAGNOSTIC SIGNIFICANCE Optimum)
Confined mainly to the evaluation of hepatic
disorders (hepatocellular disorders): ALT elevation Optimum pH 9.0 -10.0
is frequently higher than AST due to its LONGER
HALF-LIFE in the blood FUNCTION AND Catalyze the hydrolysis of various
○ 47 hours (ALT) vs. 17 hours (ASTc) PRODUCT phosphomonoesters at a certain
○ HALF-LIFE is the time needed by the pH
enzyme to half its level in the blood.
Liberate inorganic phosphate
Note: in acute hepatocellular injury, initially AST > from an organic phosphate ester
ALT but ALT > AST within 24-48 hours (except in with the concomitant production of
ALCOHOL-INDUCED HEPATOCYTE INJURY an alcohol
which damages the mitochondria;
○ Na release si mitochondrial AST tungod COFACTOR Magnesium and Zinc
kay na damage through alcohol.
○ Mitochondrial AST has a half-life of 87
hours;
○ De Ritis ratio: 3-4:1
Compares the value of AST and
ALT (Respectively)

TISSUE SOURCES

Aspartate Alanine Aspartate (ALT) 4 MAJOR ISOENZYMES:
Aminotransferase (AST) Placental ALP
Liver ALP
1. Cardiac tissue - 1. Liver - highest Bone ALP
highest 2. Kidney Intestinal ALP
2. Liver 3. Heart
○ Common in patients w/ Blood Type B or O
3. Skeletal Muscles 4. Skeletal muscle
and are SECRETORS

Made by Miguel Astronomo and Daniel Budo 3
 Are individuals that their blood
type can be determined on their
body fluids.
e.g. tears, saliva, breast
milk, semen.
80% Secretors
In persons with Type A blood type
their Intestinal ALP is bound to
RBCs.

ACID PHOSPHATASE (ALP)

ENZYME 3.1.3.2
CLASSIFICATION

SYSTEMATIC Orthophosphoric Monoester
NAME Phosphohydrolase (Acid Optimum)

Optimum pH 5.0

FUNCTION AND Catalyze the hydrolysis of various
PRODUCT phosphomonoesters at a certain
pH

Liberate inorganic phosphate
from an organic phosphate ester
with the concomitant production of
an alcohol

COFACTOR Magnesium and Zinc

Made by Miguel Astronomo and Daniel Budo 4
 CLINICAL CHEMISTRY-2 - LECTURE

PRELIMS TOPIC 4. / Phosphatases and Its Clinical Significance
Lecturer/s: Mr. Christian John Villahermosa, RMT, MSMT
August 17, 2023

Are individuals that their blood
PHOSPHATASES type can be determined on their
body fluids.
e.g. tears, saliva, breast
Alkaline Phosphatase Acid Phosphatase
(ALP) (ACP) milk, semen.
80% Secretors
Tissue Sources: Tissue Sources In persons with Type A blood type
1. Liver - focus 1. Prostate (richest their Intestinal ALP is bound to
a. Sinusoidal and source) RBCs.
bile canalicular 2. Bone
membranes 3. Liver The most commonly tested isoenzyme of ALP are LIVER
2. Bone - focus 4. Spleen
and BONE
a. Osteoblasts 5. Kidney
6. RBC because if we look into placental and intestinal
3. Intestine 7. Platelets diseases, there are other tests specific for them.
4. Spleen Application of ALP testing in the lab is purely in
5. Placenta bone and liver disorders
6. Kidney ○ e.g if a person has high ALP supposedly it
should be differentiated into which
ALKALINE PHOSPHATASE (ALP) isoenzyme

Because if ALP is high you will not know
ENZYME 3.1.3.1 which organ or tissue has a disease if its
CLASSIFICATION
isoenzyme is not differentiated
SYSTEMATIC Orthophosphoric Monoester
NAME Phosphohydrolase (Alkaline In medical practice (In other contries)…
Optimum) ALP is tested, not to have an idea of what disease a
patient might have, but it is used for
Optimum pH 9.0 -10.0 CONFIRMATION that the patient has this type of
disease.
FUNCTION AND Catalyze the hydrolysis of various Examination is done first → After Enzyme is tested
PRODUCT phosphomonoesters at a certain
pH
Methods used to differentiate the isoenzymes and other
Liberate inorganic phosphate multiple forms of ALP
from an organic phosphate ester
Electrophoresis
with the concomitant production of
an alcohol Stability to denaturation by heat or chemicals
Response to the presence of selected inhibitors
COFACTOR Magnesium and Zinc Affinity for specific lectins
Immunochemical characteristics

Isoenzymes (Electrophoresis)
LIVER → migrates fastest
BONE
PLACENTAL
INTESTINAL → Migrates slowest
Liver ALP: migrates the fastest and most anodal; It
4 MAJOR ISOENZYMES: has 2 Classifications which points to different
Placental ALP disorders which vary in severity
Liver ALP ○ Major liver fraction: usually in the EARLY
Bone ALP STAGES of hepatobiliary conditions
Intestinal ALP Disease is only in the bile duct
○ Common in patients w/ Blood Type B or O and the liver
and are SECRETORS

Made by Miguel Astronomo and Daniel Budo 1
 It suggests that the patient has a 3M Urea - Inhibits bone ALP
hepatobiliary condition.
Since it is in its early stages we Abnormal Isoenzymes (Abnormal Fractions associated with
can easily manage the disease Neoplasms): Ectopic production of an enzyme by malignant
itself. tissues; NOT PRESENT in normal individuals only in patients
○ Fast liver fraction (Alpha1 liver): Found in with a certain type of cancer.
metastatic carcinoma of the liver and
hepatobiliary diseases (valuable indicator This isoenzymes are produced by cancer cells
of obstructive liver disease)
The cancer started somewhere CARCINO PLACENTAL ALKALINE PHOSPHATASE
else 1. Regan Isoenzyme
Bone ALP: Osteoblast activity 2. Nagao Isoenzyme
Placental ALP 3. Kasahara Isoenzyme
Intestinal ALP - Found in all of the following cancers:
Hepatocellular/ gastric/ maxillary/
Isoenzymes (Heat Stability) pulmonary/ bladder carcinoma
ALP activity is measured BEFORE AND AFTER heating the
serum at 56°C for 10 min. Similarities to the placental isoenzyme
PLACENTAL → Most heat stable 3% - 15% in cancer patients
Produced by CANCER CELLS
INTESTINAL
LIVER Carcino are found in cancer patients only and most of their
BONE → Most heat labile properties is SIMILAR with PLACENTAL ALP
Placental ALP: Most heat stable (resist heat Not all cancer patients produce this enzymes; only
denaturation at 65°C for 30 min) 3-15%
Intestinal ALP This isoenzymes are NOT USED TO DIAGNOSE
Liver ALP CANCER due to its small numbers
Bone ALP
ABNORMAL ALP ISOENZYMES
When you heat a patient serum you can target the BONE REGAN ISOENZYME
and LIVER only, since these isoenzymes are the most tested Detected in various carcinomas
in the laboratory, the other 2 are not so much regarded. ○ Increased in ovarian (highest incidence)
Both are heat sensitive yet heating can still be used and gynecological cancers (better used
to detect the presence of the last 2 isoenzymes as therapy monitor)
under heat stability ○ Can be used to determine the
EFFECTIVENESS OF THERAPY
HOW TO KNOW IF THE MEASURED ACTIVITY IS FOR Ex. For a cancer patient after a
BONE ALP OR LIVER ALP therapy it should go down, but if it
If the activity is < 20% of the before level that is doesn’t it indicates that the
BONE (Most heat sensitive) therapy is not working for the
○ Na denature ang bone ALP after heating patient.
If the activity is >20% of the before level that is MOST HEAT STABLE OF ALL ALP: resists
LIVER denaturation (65°C for 30 min)
○ PRESUMED only to be liver because there ○ It assumes the properties of PLACENTAL
are other isoenzymes above the liver ALP in heating
which are much stable. Inhibited by phenylalanine and migrates like bone
ALP
Isoenzymes (Chemical Inhibition) ○ In electrophoresis BONE ALP is its
Using chemical inhibition, it is Impossible to differentiate the equivalent when regan isoenzymes
four fractions; It is DIFFICULT to measure ALL FOUR. migrate.

There is no chemical that can detect all four NAGAO ISOENZYME
It has the same properties with Regan except on the
Phenylalanine - Inhibits intestinal ALP and SOURCE OF CANCER and CHEMICAL INHIBITION
placental ALP to a much greater extent than liver Identical to the Regan Fraction (considered as a
and bone ALP variant of Regan)
Levamisole - Inhibits bone ALP and liver ALP Inhibited by both Phenylalanine and L-leucine
(Henry) Detected in metastatic carcinoma of pleural
○ you will not know if the patient has bone surfaces and adenocarcinoma of the pancreas
related disease or liver related disease and bile duct
since both of them are inhibited and ○ The source of adenocarcinoma is the
through that we cannot measure them. epithelial cells

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 DIAGNOSTIC SIGNIFICANCE (ALP) ○ Cysts and carcinoma
Hepatobiliary Disorders ○ Parasitic infection
○ Biliary Tract Obstruction: 4-10 times ULN Intrahepatic (in the liver)
due to increased synthesis of the enzyme ○ Viral hepatitis
induced by CHOLESTASIS (Translocation ○ Cholestasis in pregnancy (due to estrogen)
of ALP to the sinusoidal surface) RARE in the general population
Since the bile flow was blocked, yet COMMON in most pregnant
the bile will go back to where it woman
came from Increased ESTROGEN → SLOW
until the pressure exerted by the bile flow
bile on the hepatocyte will
damage the hepatocyte itself May lead to CHOLANGITIS (Inflammation on the bile duct;
Will now then cause the ALP on side effect of cholestasis)
the canalicular surface to Normally our bile contains its own antibody (IgG),
translocate in the sinusoidal which helps our body fight off micro bacterial or
surface parasitic infection that could potentially enter the
Hepatocellular Disorders bile flow and damage the liver.
○ Hepatitis and cirrhosis (usually less than 3 In cases of blockage, the antibody from the normal
times ULN) flow of bile is no longer to be found; thus, the
normal flora found in our small intestine could go up
the duct and cause infection.
Which now leads to cholangitis which could cause
SEPSIS (if bacterial infection will spread)
Cholestasis is most of the time ASYMPTOMATIC; it
will only show its signs and symptoms if something
obstructed already the bile duct.

Hallmarks:
Charcot’s triad
○ (1) Fever, (2) Right upper quadrant pain,
(3) Jaundice
Reynold’s pentad
○ (1) Fever, (2) Right upper quadrant pain,
(3) Jaundice, (4) Shock (low blood
volume), (5) Altered mental state
Tokyo Guidelines are also used

BONE DISORDERS
Paget Disease (osteitis deformans; increased ALP)
○ Gain in bone mass (disordered/ unsound
In cases of hepatobiliary disorders, ALP has a
new bone)
higher concentration compared in cases of
○ Normally our bones are REMODELED
hepatocellular disorders
ANNUALLY (10%).
This is due to the fact that most ALP are found in
○ In paget disease, remodelling is MORE
the canalicular end of the hepatocyte
frequent yet the quality of remodelled bone
is of NOT GOOD quality.
Most of the time,tests for ALP in cases of hepatobiliary
osteomalacia and rickets
disorders.
○ The difference between the two is that
osteomalacia occurs in ADULTS while
Any blockage on the bile ducts could lead to
rickets occurs in CHILDREN.
CHOLESTASIS
○ Due to the LACK OF VITAMIN D
○ Bile cannot pass through; hampers the
Deformed bones
flow of bile through the bile duct.
Hyperparathyroidism
Osteogenic carcinoma
CHOLESTASIS Healing bone fractures
Failure of bile excretion or transport During periods of physiologic bone growth
Extrahepatic (outside liver)
○ Gallstones (cholelithiasis and NORMAL PREGNANCY
choledocholithiasis)
Increased ALP; due to the increase of placental
Lith = Bato/Stones
ALP
Cholelithiasis → blockage of the
Can be detected between weeks 16 and 20 and
Cystic duct
persists until the onset of labor
Choledocholithiasis → blockage
of the Common bile duct

Made by Miguel Astronomo and Daniel Budo 3
 May be elevated in hypertension, preeclampsia, Useful in investigation of rape: Vaginal washings
threatened abortion are examined for seminal fluid ACP activity, which
can persist for up to 4 days
GENETIC ABNORMALITY ○ Presumptive evidence of rape: ACP
activity > 50 U/L = POSITIVE
Decreased ALP is observed in HYPOPHOSPHATASIA (An
○ If ACP is detected there is semen
inborn error of metabolism)
contamination because the semen went
- Defect in the gene that encodes for ALP
through the prostate gland
isoenzymes (Kidney, liver, bone)
Increased ACP
ACID PHOSPHATASE (ACP)
Bone disease
○ Associated with OSTEOCLASTS
ENZYME 3.1.3.2 Paget’s disease
CLASSIFICATION ○ because it includes osteoclasts also
Breast cancer with bone metastases
SYSTEMATIC Orthophosphoric Monoester ○ Spread through the bone
NAME Phosphohydrolase (Acid Optimum)
Gaucher disease
Optimum pH 5.0 ○ Cause by a deficiency of the enzyme
GLUCOCEREBROSIDASE leading to the
FUNCTION AND Catalyze the hydrolysis of various buildup of fatty substances in certain
PRODUCT phosphomonoesters at a certain organs
pH ○ it hydrolyzes glycolipids; within the cell
there is a glycolipid that it should degrade.
Liberate inorganic phosphate
from an organic phosphate ester
with the concomitant production of Thrombocytopenia
an alcohol Increased ACP
Resulting from excessive platelet destruction from
COFACTOR Magnesium and Zinc