Biochemistry Lecture Notes PDF

Summary

This document provides lecture notes on biochemistry, specifically focusing on carbohydrates. It covers their functions and classifications, including monosaccharides, disaccharides, and polysaccharides.

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BIOCHEMISTRY LEC
Prof. Josh Macallang | First Semester

BIOCHEMISTRY Cellulose
It can be defined as the science concerned with the chemical Serves as structural elements.
basis of life. Starch
It is the science concerned with the chemical constituents of living Provide energy reserves.
cells and with the reactions and processes they undergo.
A complete understanding of all chemical processes associated
with living cells. FUNCTIONS OF CARBOHYDRATES
The study of life at the molecular level. 1. Carbohydrate oxidation provides energy.
SUBDIVISIONS OF BIOCHEMISTRY 2. Carbohydrate storage provides a short-term energy reserve.
1. Structural and Functional Biochemistry 3. Carbohydrates supply carbon atoms for the synthesis of other
deals with the structure of each macromolecule and how they work biochemical substances
individually and with the others. 4. Carbohydrates form part of the structural framework of DNA
2. Informational Biochemistry and RNA molecules.
refers to the replication, transcription, and translation processes. 5. Carbohydrates linked to lipids are structural components of
3. Bioenergetics cell membranes
deals with how our cells synthesize ATP (energy) from the nutrients 6. Carbohydrates linked to proteins function in a variety of
we take in. cell–cell and cell–molecule recognition processes.
MEDICAL BIOCHEMISTRY Diseases Associated With Disorders Of Carbohydrate
Deals with the chemical basis of the human body. Metabolism
CLINICAL BIOCHEMISTRY - Diabetes mellitus
Deals with clinical diseases/pathological diseases of the human - Galactosemia
body. - Glycogen storage diseases
Fields examples are: Endocrinology, Immunology, Toxicology, - Lactose intolerance
Forensic Medicine, Molecular biology, Medical instrumentation, etc. Simple Carbohydrates
Use of Biochemical Investigations and Lab. Tests - Monosaccharides
1. Use: To reveal the fundamental causes and mechanisms - Disaccharides
of diseases Complex Carbohydrates
Example: Demonstration of the nature of the genetic - Oligosaccharides
defects in cystic fibrosis. - Polysaccharides
2. Use: To suggest rational treatments of diseases based on CLASSIFICATION
(No.1) above Monosaccharides
Example: A diet low in phenylalanine for treatment of Simple sugar.
phenylketonuria. Disaccharides
3. Use: To assist in the diagnosis of specific diseases 2 monosaccharide units.
Example: Use of the plasma enzyme creatine kinase Mb Oligosaccharides
(CK-MB) in the diagnosis of myocardial infarction. 3-10 monosaccharide units.
4. Use: To act as screening tests for the early diagnosis of
Polysaccharides
certain diseases
More than 10 sugar units
Example:Use of measurement of blood thyroxine for
Homopolysaccharides
thyroid-stimulating hormone (TSH) in the neonatal
Heteropolysaccharides
diagnosis of congenital hypothyroidism.
5. Use: To assist in monitoring the progress (e.g., recovery,
worsening, remission, or relapse) of certain diseases
Example: Use of the plasma enzyme alanine
aminotransferase (ALT) in monitoring the progress of
infectious hepatitis.
6. Use: To assist in assessing the response of disease to
therapy.
Example: Use of measurement of blood in
carcinoembryonic antigen (CEA) in certain patients who
have been treated for cancer of the colon.
CARBOHYDRATES CHIRALITY: HANDEDNESS IN
The most abundant organic molecules in earth MOLECULES
The empiric formula is C(H2O)n, “hydrates of carbon” It is needed to understand carbohydrate chemistry.
Carbohydrates are formed of carbon, hydrogen, and oxygen Molecules that possess “handedness” exist in two forms: a
atoms with a ratio of 1:2:1 “left-handed” form and a “right-handed” form.
It provide important part of energy in diet A left hand and a right hand are mirror images of each other
Act as the storage form of energy in the body
These are structural component of cell membranes
|1
 3. A carbon atom in a ring system, if not involved in
multiple bonding, can be chiral centers.

SIMPLE CARBOHYDRATES
The smallest unit of saccharides is a monosaccharide.
(“Mono” = one)
CHIRALITY: MIRROR IMAGES Examples: Glucose and Fructose
A mirror image is the reflection of an object in a mirror. Monosaccharides are also referred to as Simple Sugars.
Objects can be divided into two classes on the basis of their ○ (C6H12O6)
mirror images: ○ Glucose
○ Superimposable mirror images are images that ○ Fructose
coincide at all points when the images are laid ○ Galactose
upon each other. Further classified based on:
○ Nonsuperimposable mirror images are images 1. Number of carbon atoms
where not all points coincide when the images 2. Functional sugar group:
are laid upon each other. Aldehyde group - aldoses
Keto group - ketoses

CHIRALITY
For organic and bioorganic compounds, the structural
requirement for handedness is the presence of a carbon atom
that has four different groups bonded to it in a tetrahedral Polyhydroxy aldehydes or ketones, or substances that yield
orientation. these compounds on hydrolysis.
The tetrahedral orientation requirement is met only if the bonds
to the four different groups are all single bonds.
A chiral center is an atom in a molecule that has four different
groups bonded to it in a tetrahedral orientation.
A chiral molecule is a molecule whose mirror images are not
superimposable; have handedness
An achiral molecule is a molecule whose mirror images are
superimposable; do not possess handedness.
CHIRAL
Both can be written C3H6O3 or (CH2O)3
Empirical formula of many simpler carbohydrates: (CH2O)n
(hence the name hydrate of carbon)
Carbohydrate with an aldehyde group: Aldose
Carbohydrate with a ketone group: Ketose

ACHIRAL

GUIDELINES FOR DETERMINING
CHIRALITY
1. A carbon atom with multiple bonds is not a chiral
center.
2. A carbon atom containing two or more similar
substituents is not a chiral center.

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 DISACCHARIDE GROUPS

ISOMERISM
Structural Isomers: Compounds having same
chemical formula but different structural formula
Aldose Ketose

TRIOSE Glyceraldehyde Dihydroxyacetone

PENTOSE Ribose Ribulose

STRUCTURE OF THE D-KETOSES HEXOSE Glucose Fructose

ALDO-KETO ISOMERS
Example:
○ GLUCOSE (Aldose)
○ FRUCTOSE (Ketose)

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 STEREOISOMERS
Compounds with the same molecular formula, functional
groups, and position of functional groups but with different
conformations
Enantiomers are stereoisomers whose molecules are
nonsuperimposable mirror images of each other.
Diastereomers are stereoisomers whose molecules are not
mirror images of each other. Cis–trans isomers (of both the
alkene and the cycloalkane types) are diastereomers.

cis-trans isomers: with different conformation around double bonds

ENANTIOMERS (D- and L-Forms)
The term enantiomer comes from the Greek enantios, which
means “opposite.”
A dextrorotatory compound is achiral compound that rotates
the plane of polarized light in a clockwise direction.
A levorotatory compound is a chiral compound that rotates
the plane of polarized light in a counterclockwise direction.
If one member of an enantiomeric pair is dextrorotatory, then
the other member must be levorotatory.

Epimers
CHO dimers that differ in configuration around only one
specific carbon atom
Glucose and galactose, C4
Glucose and Mannose, C2
Galactose and mannose are not epimers

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 One member of an enantiomeric pair will rotate a plane of
The mirror images can’t be superimposed on each other, polarized light in a clockwise direction. It is said to be
i.e. they are different dextrorotatory which is labeled (+)
The mirror image isomers constitute an enantiomeric The other member of the pair will then rotate the light in a
pair; one member of the pair is said to be the enantiomer counterclockwise direction. It is said to be levorotatory
of the other. which is labeled (-)
Structures that are mirror images of each other and are D & L designate absolute configuration of the
designated as D- and L- sugars based on the position of asymmetric carbon atom farthest from the aldehyde or
–OH group on the asymmetric carbon farthest from the ketone group
carbonyl carbon
Majority of sugars in humans are D-sugars

D or L FORM

α- and β-Forms
Cyclization of Monosaccharides
Monosaccharides with 5 or more carbon are
predominantly found in the ring form
○ The aldehyde or ketone group reacts with the
–OH group on the same sugar
○ Cyclization creates an anomeric carbon (former
carbonyl carbon) generating the α and β
configurations

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 MUTAROTATION
In solution, the cyclic α and β anomers of a sugar are in
equilibrium with each other, and can be interconverted
spontaneously

Mutarotation: Spontaneous conversion of one anomer
to the other

Galactose - part of lactose
1. Found in milk
2. Converts to glucose in the body

Monosaccharides
Glucose - dextrose or blood sugar
1. Primary fuel for the body
2. Found in all disaccharides and polysaccharides

Ribose - component of ribonucleic acids (RNAs) and
energy-rich compounds such as adenosine triphosphate
(ATP)
- An aldopentose

Fructose – fruit sugar
1. Found in fruit, honey, syrup
2. Converts to glucose in the body

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 The "hotter" the final color of the reagent, the higher the
concentration of reducing sugar; formation of brick red
precipitate indicates a reaction with Benedict’s reagent.

REACTIONS OF MONOSACCHARIDES
OXIDATION USING WEAK OXIDIZING
(TOLLEN'S REAGENT)
It is a reaction that is used to distinguish aldehydes from
ketones; give an aldonic acid
Tollens' reagent, which is a mixture of silver nitrate and
ammonia, oxidizes the aldehyde to a carboxylic acid
With Tollens solution, glucose reduces Ag1 ion to Ag
The formation of a dark grey precipitate or silver mirror on
the bottom and sides of the test tube indicates a positive
result, which means that the given sample contains REACTIONS OF MONOSACCHARIDES
reducing sugars/ aldoses. OXIDATION USING WEAK OXIDIZING
(Heat, Acidic KMnO4 or HNO3)
Can oxidize both ends of a monosaccharide at the same
time (the carbonyl group and the terminal primary alcohol
group) to produce a dicarboxylic acid.
Such polyhydroxy dicarboxylic acids are known as aldaric
acids. For glucose, this oxidation produces glucaric acid.

REACTIONS OF MONOSACCHARIDES
OXIDATION USING ENZYMES
Although it is difficult to do in the laboratory, in biochemical
systems enzymes can oxidize the primary alcohol end of
an aldose such as glucose, without oxidation of the
REACTIONS OF MONOSACCHARIDES aldehyde group, to produce an alduronic acid.
OXIDATION USING WEAK OXIDIZING For glucose, such an oxidation produces D-glucuronic
(BENEDICT’S REAGENT) acid.
It is a chemical test that can be used to check for the
presence of reducing sugars
Therefore, simple carbohydrates containing a free ketone
or aldehyde functional group can be identified with this
test.
Benedict’s solution, glucose reduces Cu21 ion to Cu1 ion
It is a complex mixture of sodium carbonate, sodium
citrate, and copper(II) sulfate pentahydrate.

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 REACTIONS OF MONOSACCHARIDES
FORMATION OF PHOSPHATE ESTER
The hydroxyl groups of a monosaccharide can react with
inorganic oxyacids to form inorganic esters
Alkyl/Aryl Acid Phosphates are formed by the reaction of
phosphoric anhydride (phosphoric pentoxide or P2O5) and
an alcohol (ROH).
Phosphate esters, formed from phosphoric acid and
various monosaccharides, are commonly encountered in
biochemical systems.

REACTIONS OF MONOSACCHARIDES REACTIONS OF MONOSACCHARIDES
REDUCTION TO PRODUCE SUGAR FORMATION OF AMINO SUGAR
ALCOHOL If one of the hydroxyl groups of a monosaccharide is
The carbonyl group in a monosaccharide can react with a replaced with an amino group, an amino sugar is
reducing agent like hydrogen or sodium borohydride produced.
(NaBH4) and is reduced to a hydroxyl group resulting to a In naturally occurring amino sugars, of which there are
polyhydroxy alcohol called sugar alcohol or alditol. three common ones, the amino group replaces the carbon
An example of a polyhydroxy alcohol is D- sorbitol / 2 hydroxyl group.
D-glucitol, a popular sweetening agent; It is the reduction Amino sugars and their N-acetyl derivatives are important
of D-glucose building blocks of polysaccharides found in chitin and
hyaluronic acid. The N-acetyl derivatives of
D-Glucosamine and D-galactosamine are present in the
biochemical markers on red blood cells, which distinguish
the various blood types

REACTIONS OF MONOSACCHARIDES
FORMATION OF GLYCOSIDE
The hydroxyl group of the anomeric carbon in a cyclic
structure of monosaccharide can react with another
alcohol molecule via formation of a glycosidic bond
The figure below shows the reaction between a-D-glucose
and methanol (CH3OH) in the presence of an acid
catalyst.
The product is Methyl-a-D-glucoside.

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 DISACCHARIDES Maltose is a reducing because the glucose unit on the
Monosaccharides combine together to form disaccharides right has a hemiacetal carbon atom (C-1)
(“Di” = two)
Joining of 2 monosaccharides by O-glycosidic bond:
○ Maltose (α-1, 4)= glucose + glucose
○ Sucrose (α-1,2) = glucose + fructose
○ Lactose (β-1,4) = glucose + galactose

The most important chemical reaction of maltose is that of
The bond that links the two monosaccharides of a hydrolysis. Hydrolysis of D-maltose, whether in a
disaccharide (glycoside) together is called a glycosidic laboratory flask or in a living organism, produces two
linkage. molecules of D-glucose.
Many disaccharides contain both a hemiacetal carbon Acidic conditions or the enzyme maltase is needed for the
atom and an acetal carbon atom, as is the case for the hydrolysis to occur.
preceding disaccharide structure. Hemiacetal and acetal HYDROLYSIS
locations within disaccharides play an important role in
the chemistry of these substances.
It is normally formed between the carbon-1 of one
monosaccharide and carbon-4 of the other
monosaccharide. The formation of glycosidic bonds
involves the condensation of water molecules. In a
disaccharide, the two monosaccharide units are joined by
an ether linkage.
Maltose - malt sugar
1. Glucose + Glucose
2. Found in germinating seeds & used in
fermentation to produce malted beverages (beer,
whiskey)
Malt (germinated barley that has been baked and ground) CELLOBIOSE
contains maltose; hence the name malt sugar 1. Glucose + Glucose
2. Produced as an intermediate in the hydrolysis of the
polysaccharide cellulose
Like maltose, cellobiose contains two D-glucose
monosaccharide units. It differs from maltose in that one of
the D-glucose units—the one functioning as a
hemiacetal—must have a b configuration instead of the a
configuration for maltose; resulting to a b(1 → 4)
CONDENSATION glycosidic linkage

9
 Like maltose, cellobiose is a reducing sugar, has three lactose-free diet for 3-4 weeks could give you the
isomeric forms in aqueous solution, and upon hydrolysis answers you want without expensive tests.
produces two D-glucose molecules 2. Standard Lactose Tolerance Test
Despite these similarities, maltose and cellobiose have - Blood glucose levels are measured before, at 30
different biochemical behaviors. These differences are minutes, and at 60 minutes after consuming 50g
related to the stereochemistry of their glycosidic linkages. of lactose. Your blood will then be analyzed for
Maltase, the enzyme that breaks the glucose–glucose lactose malabsorption. Malabsorption is also
a(1→4) linkage present in maltose, is found both in the correlated to symptoms such as abdominal
human body and in yeast. Consequently, maltose is bloating, discomfort diarrhea, and gas.
digested easily by humans and is readily fermented by 3. Lactose Hydrogen Breath Test
yeast. - After consuming 25-50g of a lactose liquid,
Both the human body and yeast lack the enzyme breath samples are taken every 30 minutes for
cellobiase needed to break the glucose glucose b(1 →4) up to 3 hours. A rise in breath hydrogen indicates
linkage of cellobiose. Thus, cellobiose cannot be malabsorption of lactose (an increase in
digested by humans or fermented by yeast. hydrogen is caused by fermentation of sugar by
your gut flora). NOTE! Approximately 25% of
patients will have a false negative breath test.

Lactose - milk sugar Sucrose - table sugar
1. Glucose + Galactose 1. Glucose + Fructose
2. Lactose intolerance missing digestive enzymes 2. Refined from sugar beets and cane
needed to split into two monosaccharide parts to It is the most abundant of all disaccharides
absorb it.
Souring of milk is caused by the conversion of
lactose to lactic acid by bacteria in the milk.

Sucrose, unlike maltose, cellobiose, and lactose, is a
nonreducing sugar. In sucrose, the hemiacetal center
(anomeric carbon atom) of each monosaccharide is
involved in the glycosidic linkage.
The result is a molecule that contains two acetal centers.
Sucrose, in the solid state and in solution, exists in only
Lactose can be hydrolyzed by acid or by the enzyme one form—there are no a and b isomers, and an
lactase, forming an equimolar mixture of galactose and open-chain form is not possible.
glucose
Genetic condition lactose intolerance, an inability of the
human digestive system to hydrolyze lactose.

Sucrase, the enzyme needed to break the a, b(1→2)
linkage in sucrose, is present in the human body. Hence
LACTOSE INTOLERANCE TESTS sucrose is an easily digested substance. Sucrose
1. Elimination DIY Test hydrolysis (digestion) produces an equimolar mixture of
- Try a lactose-free diet; this is as simple as it glucose and fructose called invert sugar
sounds. If you suffer from clinical symptoms (like
abdominal cramps and diarrhea), sticking to a

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 stomach and small intestine. In the large intestine, they
are fermented by bacteria that do possess the α-GAL
enzyme and make short-chain fatty acids.

OTHER TYPES OF GLYCOSIDIC LINKAGES
Three of the four disaccharides considered in this section -
maltose, cellobiose, and lactose- have (1 to 4) glycosidic
linkages. The other disaccharide considered, sucrose, has
a (1 to 2) glycosidic linkage. Other carbon atoms besides
1, 2, and 4 can also participate in glycosidic linkages. An
additional common type of glycosidic linkage is one that
involves carbons 1 and 6. Several disaccharides not
derailed in this section have α (1 to 6) glycosidic linkages.
The following structure is for two α-D-glucose molecules
connected via an α (1 to 6) glycosidic linkage.

Stachyose

This disaccharide is an entirely different compound than
maltose or cellobiose, both of which involve two glucose
molecules connected, respectively, via α (1 to 4) and β (1
to 4) glycosidic linkages.
OLIGOSACCHARIDES
3 – 10 Monosaccharides combine together to form
oligosaccharides (“Oligo” = few / small quantities)
Joining of 3-10 monosaccharides by O-glycosidic bond:
- Two naturally occurring oligosaccharides found in
onions, cabbage, broccoli, brussel sprouts, whole
wheat, and all types of beans
Nystose
1. Raffinose = galactose + glucose +
Represents a fructooligosaccharide with two fructose
fructose
molecules linked via beta(1----2) bonds to the fructosyl
moiety of sucrose. This tetrasaccharide was subjected to
2. Stachyose = galactose + galactose +
an array of in vitro tests designed for the assessment of
glucose + fructose
potential sugar substitutes before animal or human
3. Nystose = fructose + fructose + studies.
fructose + galactose

Humans lack the digestive enzymes necessary to
metabolize either raffinose or stachyose. Hence these
oligosaccharides, when ingested in food, pass undigested
Raffinose
Can be hydrolyzed to D-galactose and sucrose by the
enzyme α-galactosidase (α-GAL), an enzyme synthesized
by bacteria found in the large intestine
It is non-digestible in humans and other monogastric who
do not possess the αGAL enzyme to break down RFOs.
These oligosaccharides pass undigested through the

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 ABO Blood Type & Oligosaccharides
Human blood is classified into four types: A, B, AB, and O.
The biochemical basis for the various types of blood
involves oligosaccharide molecules that are attached to The absence or presence of a fifth monosaccharide
the plasma membrane of red blood cells. (attached to the second galactose) determines the
Four monosaccharides contribute to the make-up of the blood type.
oligosaccharide “marking system. COMPLEX CARBOHYDRATES
The arrangement of these monosaccharides in the In nutrition, monosaccharides and disaccharides are
biochemical marker determines blood type. called simple carbohydrates, and polysaccharides are
called complex carbohydrates.
A polysaccharide is a polymer that contains many
monosaccharide units bonded to each other by glycosidic
linkages.
Polysaccharides are often also called glycans.
Homopolysaccharides:
Branched (Storage Polysaccharides):
- Glycogen and starch (α-glycosidic polymer)
Unbranched (Structural Polysaccharides):
- Cellulose (β-glycosidic polymer), chitin
Homopolysaccharides:
E.g., GAGs, Hyaluronic Acid, Heparin
PARAMETERS TO DISTINGUISH GLYCANS
FROM ONE TO ANOTHER
1. The identity of the monosaccharide repeating unit(s) in the
polymer chain.
A homopolysaccharide is a polysaccharide in
which only one type of monosaccharide
monomer is present
A heteropolysaccharide is a polysaccharide in
which more than one (usually two) type of
monosaccharide monomer is present
2. The length of the polymer chain
3. The type of glycosidic linkage between monomer units.
4. The degree of branching of the polymer chain.
Unlike monosaccharides and most disaccharides,
polysaccharides are not sweet and do not test positive
in Tollens and Benedict’s solutions. They have limited
water solubility because of their size. However, the -OH
groups present can individually become hydrated by water
Note that all three of the oligosaccharide markers molecules. The result is usually a thick colloidal
have a common four monosaccharide sequence in suspension of the polysaccharide in water.
their structure: Polysaccharides, such as flour and cornstarch, are often
used as thickening agents in sauces, desserts, and
gravy.

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 4. Glycogen is about three times more highly branched than
amylopectin, and it is much larger, with up to 1,000,000 glucose
units present.

POLYSACCHARIDES
Cellulose
– unbranched glucose polymer; structural component of plant
cell walls, is the most abundant naturally occurring polysaccharide
1. The “woody” portions of plants
2. Glucose residues present in cellulose have a beta-configuration
3. Cellulose molecules tend to have linear structures
4. contain about 5000 glucose units
POLYSACCHARIDES 5. Humans lack the enzymes (cellulase) capable of catalyzing the
Starch hydrolysis of b(1 : 4) linkages in cellulose.
– long chains of glucose found in plants; energy storage of plants – second most abundant naturally occurring polysaccharide;
When the cell cannot get enough glucose from outside the cell, it 1. to give rigidity to the exoskeletons of crabs, lobsters, shrimp,
hydrolyzes starch to release glucose. insects, and other arthropods
1. Cereal grains 2. cell walls of fungi
(wheat, rice, corn, etc.), legumes (beans & peas), and root 3. identical to cellulose, except the monosaccharide present is the
vegetables (potatoes, yams). glucose derivative N-acetyl-D-glucosamine (NAG) rather than
2. Amylose D-glucose itself.
a straight-chain glucose polymer usually accounts for 15%–20% of 4. Chitin polymers contain both glycosidic linkages and amine
the starch; amylopectin, a branched glucose polymer, accounts for bonds, both of which can be broken via hydrolysis.
the remaining 80%–85% of the starch.
3. Iodine
is often used to test for the presence of starch in solution; Starch
containing solutions turn a dark blue-black when iodine is added

Amylopectin, the other polysaccharide in starch, has a high degree
of branching in its polyglucose structure. A branch occurs about
once every 25 - 30 glucose units. The branch points involve a(1
→6) linkages & a(1→4) linkages; Up to 100,000 glucose units
present.
POLYSACCHARIDES
Glycogen
– long chains of glucose found in animals and humans
– Also known as “animal starch”
1. Stored in liver & muscles
2. Helps maintain blood glucose and important source of “quick
energy”, esp. during exercise (lasts only about 12 hrs)
3. Glycogen has a structure similar to that of amylopectin; all
glycosidic linkages are of the a type, and both (1 → 4) and (1 → 6) ACIDIC POLYSACCHARIDES
linkages are present.

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 is a polysaccharide with a disaccharide repeating unit in glucose, thus pushing blood glucose levels back up to normal.
which one of the disaccharide components is an amino
sugar and one or both disaccharide components has a THE GLUCOSE JOURNEY
negative charge due to a sulfate group or a carboxyl - from food to fuel via the bloodstream
group. Glucose starts its journey as a carbohydrate food.
acidic polysaccharides are heteropolysaccharides; two When the food is eaten, It passes through the mouth,
different monosaccharides are present in an alternating stomach and small intestine.
pattern. All of these areas help to digest (break down) the food to
Acidic polysaccharides are involved in a variety of cellular glucose.
functions and tissues Glucose starts its journey as a carbohydrate food.
Two of the most well-known acidic polysaccharides are When the food is eaten, it passes through the mouth,
hyaluronic acid and heparin, both of which have stomach and small intestine.
unbranched-chain structures. All of these areas help to digest (break down) the food to
HYALURONIC ACID HEPARIN glucose.
The glucose is absorbed from the small intestine into the
The structure of hyaluronic It consists of repeating unit are blood stream.
acid contains alternating a sulfate derivative of The blood stream carries the glucose to its next stop, all
residues of N-acetyl-b-D D-glucuronate the body's cells, particularly muscles, the brain and the
glucosamine (NAG) and (Dglucuronate-2-sulfate) and a liver.
D-Glucuronate. doubly sulfated derivative of
The glucose can only enter the cells with the help of
D-glucosamine
Alternating pattern of (N-sulfo-D-glucosamine-6-sulf insulin, a hormone which is made in the pancreas.
glycosidic bond types, ate) As the blood glucose level rises after eating, the pancreas
b(1 :→3) and b(1 → 4) releases insulin into the blood stream.
Insulin travels to the cells, where it works to allow glucose
to enter the cells.
BLOOD SUGAR
Glucose is also directed to the liver to be stored for later
Blood sugar or blood glucose refers to sugar that is transported
use.
through the bloodstream to supply energy to all the cells in our
Between meals and overnight our body can draw on the
bodies. The sugar is made from the food we eat. The human body
stored glucose for energy.
regulates blood glucose levels so that they are neither too high nor
Digestion
too loW.
Mouth
Or
–Salivary amylase (carbohydrates), Lingual lipase (lipids)
Sugar is a simple, crystalline, edible carbohydrate and comes in a
Stomach
variety of forms, all of them sweet. Our body digests carbohydrates
–Fibers and satiety, Pepsin (Proteins)
into glucose, a simple sugar that can easily convert to energy. The
Small Intestine
chemical formula for glucose is C6H1206
-Maltase, sucrase, lactase
The human digestive system breaks down the
Pancreas
carbohydrates from food into various sugar molecules -
–Pancreatic amylase (CHO), Trypsinogen (Proteins), Pancreatic
one of them is glucose, the body's principal source of
Lipase (Lipids), Nucleases (Nucleic Acids)
energy. The glucose goes straight from the digestive
Large Intestine
system into the bloodstream after we have consumed and
-Fermentation of viscous fibers → Water, gas, short-chain fatty
digested food. Glucose can only enter cells if there is
acid production.
insulin in the bloodstream too. Without any insulin the cells
would starve.
After we eat, blood sugar concentrations rise, the
pancreas releases insulin automatically so that the
glucose enters cells, as more and more cells receive
glucose, blood sugar levels come down to normal again.
Excess glucose is stored as glycogen (stored glucose in
the liver and muscles.
After a meal blood glucose levels
rise, insulin is released from the
pancreas into the bloodstream,
blood sugar levels fallback.

If you have not eaten for a while
and blood glucose concentrations
keep dropping, the pancreas
releases another hormone called
glucagon. Glucagon triggers the
breakdown of glycogen into

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 METABOLISM
- Glucose in the Body
Used for energy – fuels most of the body’s cells
Stored as glycogen – 1/3 in the liver and 2/3 in muscles
Made from protein – gluconeogenesis
Converted to fat – when in excess of body’s needs
Constancy of Blood Glucose
Regulating hormones – maintain glucose homeostasis
1. Insulin
– moves glucose from the blood into cells.
2. Glucagon
– signals the liver to release glucose into the blood.
3. Epinephrine
– released when emergency fuel needed.
Regulation of Carbohydrate Metabolism
INSULIN
is the primary hormone responsible for the entry of
Regulation of Carbohydrate Metabolism
glucose into the cell.
Two hormones produced by the adrenal gland affect carbohydrate
It is synthesized by the ß-cells of the islets of Langerhans
metabolism: Epinephrine & Glucocorticoids
in the pancreas.
1. Epinephrine (adrenal medulla)
When these cells detect an increase in body glucose, they
increases plasma glucose by inhibiting insulin secretion,
release insulin.
increasing glycogenolysis, and promoting lipolysis.
The release of insulin causes an increased movement of
is released during times of stress.
glucose into the cells and increase glucose metabolism.
is normally released when glucose levels are high and 2. Glucocorticoids (cortisol)
is not released when glucose levels are decreased. are released from the adrenal cortex on stimulation by
It decreases plasma glucose levels by increasing the adrenocorticotropic hormone (ACTH).
transport entry of glucose in muscle and adipose tissue by Cortisol increases plasma glucose by decreasing intestinal
way of nonspecific receptors. entry into the cell and increasing gluconeogenesis, liver
It also regulates glucose by increasing glycogenesis, glycogen, and lipolysis.
lipogenesis and glycolysis and inhibiting glycogenolysis. Regulation of Carbohydrate Metabolism
Insulin is the only hormone that decreases glucose levels Two anterior pituitary hormones, growth hormone and ACTH,
and can be referred to as hypoglycemic agent. promote increased plasma glucose.
GLUCAGON 1. Growth hormone
is the primary hormone responsible for increasing increases plasma glucose by decreasing the entry of
glucose levels. glucose into the cells and increasing glycolysis.
It is synthesized by the α-cells of islets of Langerhans in Its release from the pituitary is stimulated by decreased
the pancreas and released during stress and fasting glucose levels and inhibited by increased glucose.
states. Decreased levels of cortisol stimulate the anterior pituitary
When these cells detect a decrease in body glucose, to release ACTH.
they release glucagon. 2. ACTH
Glucagon acts by increasing plasma glucose levels by in turn, stimulates the adrenal cortex to release cortisol
glycogenolysis in the liver and an increase in and increases plasma glucose levels by converting liver
gluconeogenesis. glycogen to glucose and promoting gluconeogenesis.
It can be referred to as hypoglycemic agent. Regulation of Carbohydrate Metabolism

15
Two other hormones affect glucose levels: thyroxine and Type 2 diabetes – Gestational diabetes mellitus
somatostatin. 1. Type 1 diabetes
1. Thyroid gland is characterized by inappropriate hyperglycemia primarily a result of
is stimulated by the production of thyroid-stimulating hormone to pancreatic islet ßcell destruction and a tendency to ketoacids.
release thyroxine that increases plasma glucose by increasing 2. Type 2 diabetes
glycogenolysis, gluconeogenesis and intestinal absorption of In contrast, includes hyperglycemia cases that result from insulin
glucose. resistance with an insulin secretory defect.
2. Somatostatin Diabetes Mellitus
produced by the δ-cells of the islets of Langerhans of the pancreas, An intermediate stage, in which the fasting glucose is
increases plasma glucose levels by the inhibition of insulin, increased above-normal limits but not to the level of
glucagon, growth hormone and other endocrine hormones. diabetes, has been named impaired fasting glucose.
Use of the term impaired glucose tolerance to indicate
HYPOGLYCEMIA glucose tolerance values above normal but below diabetes
The warning signs and symptoms of hypoglycemia are all levels was retained.
related to the central nervous system. Also, the term GDM was retained for women who develop
The release of epinephrine into the systemic circulation glucose intolerance during pregnancy
and of norepinephrine at nerve endings of specific Type 1 diabetes mellitus
neurons acts in unison with glucagon to increase plasma is a result of cellular-mediated autoimmune destruction of
glucose. the ß-cells of the pancreas, causing an absolute deficiency
Glucagon is released from the islet cells of the pancreas of insulin secretion.
and inhibits insulin. Upper limit of 110 mg/dL on the fasting plasma glucose is
Hypoglycemia involves decreased plasma glucose designated as the upper limit of normal blood glucose.
levels and can have many causes – some are transient Type 1 constitutes only 10% to 20% of all cases of
and relatively significant, but others can be life diabetes and commonly occurs in childhood and
threatening. adolescence.
The plasma glucose concentration at which glucagon and Initiated by an environmental factor or infection (usually a
other glycemic factors are released is between 65 and 70 virus) in individuals with a genetic predisposition and
mg/dL (3.6 to 3.9 mmol/L); at about 50 to 55 mg/dL (2.8 causes the immune destruction of the ß-cells of the
to 3.1 mmol/L), observable symptoms of hypoglycemia pancreas and, a decreased production of insulin.
appear. Characteristics of type 1 diabetes include abrupt onset,
HYPERGLYCEMIA insulin dependence, and ketosis tendency.
is an increase in plasma glucose levels. This diabetic type is genetically related.
In healthy patients, during a hyperglycemia state, insulin is One or more of the following markers are found in 85% to
secreted by the ß-cells of the pancreatic islets of 90% of individuals with fasting hyperglycemia: islet cell
Langerhans. autoantibodies, insulin autoantibodies, glutamic acid
Insulin enhances membrane permeability to cells in the decarboxylase autoantibodies and tyrosine phosphatase
liver, muscle and adipose tissue. autoantibodies.
It also alters the glucose metabolic pathways. Signs and symptoms include:
Hyperglycemia, or increased plasma glucose levels, is polydipsia (excessive thirst)
caused by an imbalance of hormones. polyphagia (increased food intake)
Constancy of Blood Glucose polyuria (excessive urine production)
rapid weight loss
Diabetes
hyperventilation
–Type 1 diabetes / Juvenile Failure of insulin production mental confusion
possible loss of consciousness (due to increased
Obesity glucose to brain).
–Type 2 diabetes / Adult Complications include:
Onset microvascular problems such as nephropathy, neuropathy, and ret
Autoimmune Increased heart disease is also found in patients with diabetes.
–Type 3C diabetes
Idiopathic type 1 diabetes
Hypoglycemia Rare in healthy people is a form of type 1 diabetes that has no known etiology, is
strongly inherited, and does not have ß-cell autoimmunity.
Glycemic response Glycemic index Individuals with this form of diabetes have episodic
requirements for insulin replacement.
Laboratory Findings in Hyperglycemia:
Diabetes Mellitus
Increased glucose in plasma and urine
is actually a group of metabolic diseases characterized by
Increased urine specific gravity
hyperglycemia resulting from defects in insulin secretion, insulin
Increased serum and urine osmolality
action, or both.
Ketones in serum and urine (ketonemia and
ADA/WHO guidelines recommend the following categories:
ketonuria)
Type 1 diabetes – Other specific types of diabetes
Decreased blood and urine pH (acidosis)

16
 Electrolyte imbalance 4. Formation of (Hb A1c) is nonenzymatic and occurs over the life
Type 2 diabetes mellitus span (average 120 days) of the red blood cell.
is characterized by hyperglycemia as a result of an 5. Because RBC is freely permeable to blood glucose, the amount
individual’s resistance to insulin with an insulin secretory of total Hb A1c is related to the time averaged glucose
defect. concentration over the 4 to 6 weeks before the measurement.
This resistance results in a relative, not an absolute, 6. A level of 8% or less is considered “good” glycemic control.
insulin deficiency. 7. The test is not used to diagnose diabetes.
Type 2 constitutes the majority of the diabetes cases. 8. Common analyzers can use an enzymatic assay: diazyme A1c.
Most patients in this type are obese or have an increased 9. Other methods: electrophoresis, ion-exchange chromatography,
percentage of body fat distribution in the abdominal and high-performance liquid chromatography.
region. Diabetes Mellitus
This type of diabetes often goes undiagnosed for many Women identified through the oral glucose tolerance should
years and is associated with a strong genetic receive a diagnosis of GDM.
predisposition, with patients at increased risk with an Diagnostic Criteria for GDM:
increase in age, obesity and lack of physical exercise. 1. FPG ≥ 92 mg/dL (5.1 mmol/L)
Characteristics usually include adult onset of the disease 2. One-hour plasma glucose ≥ 180 mg/dL (10 mmol/L)
and milder symptoms than in type 1, with ketoacidosis 3. Two-hour plasma glucose ≥ 153 mg/dL (8.5 mmol/L)
seldom occurring. Causes of GDM include metabolic and hormonal changes.
However, these patients are more likely to go into a Patients with GDM frequently return to normal postpartum.
hyperosmolar coma and are at an increased risk of However, this disease is associated with increased
developing macrovascular and microvascular perinatal complications and an increased risk for the
complications. development of diabetes in later years.
Other specific types of diabetes are associated with Infants born to mothers with diabetes are at increased risk
certain conditions (secondary), including genetic defects of for respiratory distress syndrome, hypocalcemia, and
ß-cell function or insulin action, pancreatic disease, hyperbilirubinemia.
diseases of endocrine origin, drug- or chemical-induced Fetal insulin secretion is stimulated in the neonate of a
insulin receptor abnormalities, and certain genetic mother with diabetes.
syndromes. However, when the infant is born and the umbilical cord is
The characteristics and prognosis of this form of diabetes severed, the infant’s oversupply of glucose is abruptly
depend on the primary disorder. terminated, causing severe hypoglycemia.
Maturity-onset diabetes of youth is a rare form of diabetes
that is inherited in an autosomal dominant fashion.
GDM
has been defined as any degree of glucose intolerance
with onset or first recognition during pregnancy.
However, the latest recommendations suggest that “high
risk” women found to have diabetes at their initial prenatal
visit, using standard criteria receive a diagnosis of overt,
not gestational diabetes
Diagnostic Criteria for Diabetes Mellitus
1. HbA1c ≥ 6.5% using a method that is NGSP certified and
standardized to the DCCT assay.
2. Fasting plasma glucose ≥ 126 mg/ dL (≥ 7.0 mmol/L)
3. Two hour plasma glucose ≥ 200 mg/dL (≥ 11.1 mmol/L during
OGTT.
4. Random plasma glucose ≥ 200 mg/dL (≥ 11.1 mmol/L plus
symptoms of diabetes. Microalbuminuria
NGSP (National Glycohemoglobin Standardization Program) DM causes progressive changes to the kidneys and
OGTT (Oral Glucose Tolerance Test) ultimately results in diabetic renal nephropathy.
This complication progresses over years and may be
NOTE: In the absence of unequivocal hyperglycemia, these criteria delayed by aggressive glycemic control.
should be confirmed by repeat testing on a different day. The fourth An early sign that nephropathy is occurring is an increase
measure (OGTT) is not recommended for routine clinical use in urinary albumin.
Glycosylated Hemoglobin is defined as persistent albuminuria
1. Long term estimation of glucose concentration - Measurement of in two out of three urine collections of 30 to 300 mg/24 h,
glycosylated hemoglobin(Hb A1c). 20 to 200 µg/min, or an albumin-creatinine ratio ≥ 300
2. Hemoglobin A (Hb A) is formed when glucose binds to amino mg/24 h, >200 µg/min, or ≥ 300 µg/mg.
group that is part of the Hb A protein. Although three methods for microalbuminuria screening
3. The reaction occurs at the N-terminal valine of the hemoglobin are available, the use of random spot collection for the
beta chains. measurement of the albumin creatinine ratio is the
preferred method.

17
 NATURAL SUGAR intake with emphasis on complex
is a sugar naturally present in whole foods. -Daily Value: 300 g/day
Milk and fresh fruit are two important sources of natural Fiber
sugars. –Daily Value: 25 g/day
REFINED SUGAR –AI: 14 g/1000 kcal/day
is a sugar that has been separated from its plant source. Alternative Sweeteners
Sugar beets and sugar cane are major sources of refined Two Categories
sugars 1. Sugar Alcohols – mannitol, sorbitol, xylitol
2. Artificial sweeteners – sugar substitutes (calorie-free); in
Health Effects of Sugar moderation, useful for blood sugar & weight control
Sugar in excess 1. Sugar Alcohols
1. Contains no nutrients and may contribute to malnutrition 1. CHOs that provide less energy than sucrose (2-3 kcals/gm)
2. Causes dental caries (tooth decay) because not completely absorbed
3. Does not cause, but can contribute to: obesity, diabetes, heart 2. May cause gas, abdominal discomfort, diarrhea
disease, & behavorial problems 3. Less cariogenic than sugar
2. Artificial Sweeteners
Recommended Intakes of Sugars 1. Saccharin = “Sweet ‘N Low” or “Sugar Twin”
DRI 2. Aspartame = “Equal” or “Nutrasweet” must avoid if have
– No more than 25% of total daily energy intake phenylketonuria
– Limit added sugars to