Carbohydrate Chemistry - Week 4 PDF

Summary

These notes cover carbohydrate chemistry, defining carbohydrates, classifying them into groups, describing their properties, and discussing their biomedical importance. The document details the different types of sugars, including monosaccharides (like glucose and fructose), disaccharides (like sucrose and lactose), and their properties and functions.

Full Transcript

Carbohydrate Chemistry
When you hear carbohydrates
what comes into your minds
Objectives
To define carbohydrates in chemical terms
To classify carbohydrates into major groups with
examples for each group
To describe important properties of carbohydrates
To describe the biomedical importance of
carbohydrates
To learn the overview of carbohydrate metabolism
What is Carbohydrates

“Hydrate of Carbon”
Chemically simple – contains three elements (C·H2O)n
Carbohydrates are the most abundant molecule in nature
Chemically defined as polyhydroxy aldehydes and
ketones or substances that hydrolyzes to yield
polyhydroxy aldehyde and ketone.
The term 'sugar' is frequently applied to
monosaccharides and lower oligosaccharides.

IUPAC-IUBMB Joint Commission on Biochemical Nomenclature (JCBN)
Importance of carbohydrates
Is the most abundant class
of bioorganic molecules on
planet earth
Aside from dietary food ,
that we eat carbs can be
also in the form of cotton or
linen that can be used for
clothing
Ideally, the average human
diet should be composed of
2/3 carbohydrates
What are some of the function of
carbohydrates
Storage form of Structural
Source of energy Dietary fiber
energy component

Cellular
Constituent of Intercommunicat
Detoxification
nucleotides ion, Lubrication,
and Immunity
General Properties
Asymmetric carbon: a carbon to which four different
atoms or groups of atoms are attached
Stereoisomers: compounds which are identical in
composition and differs only in spatial configuration
Optical activity: when a beam of plane-polarized light is
passed through a solution exhibiting optical activity, it will
be rotated to the right or left
Dextrorotatory (d or + sign)
Levorotatory (l or –sign)
racemic
Aldehyde sugars (polyhydroxy
aldehyde) H H H H H

C O C O C O C O C O

(H C OH)n H C OH H C OH H C OH H C OH

CH 2OH CH 2OH H C OH H C OH H C OH

Aldose Aldotriose CH 2OH H C OH H C OH
n=1
Aldotetrose CH 2OH
n=2 H C OH
Aldopentose
CH 2OH
n=3

Ketose sugar (Polyhydroxy ketone)
Aldohexose
n=4

CH 2OH CH 2OH
CH 2OH
CH 2OH
C O C O CH 2OH
C O
C O
(H C OH)n H C OH C O
H C OH
CH 2OH
CH 2OH H C OH H C OH
CH 2OH
CH 2OH H OH
Ketose Ketotriose Ketotetrose
n=1 Ketopentose H C OH
n=0
n=2
CH 2OH
Ketohexose
n=3
Classify each of the ff: monosaccharides
according to both the number of carbon atoms
and the type of carbonyl group
Structural Representations of Sugar
Fisher projection: straight chain representation
Haworth projection: simple ring in perspective
Conformational representation: chair and boat
configurations
Structural Representations of Sugar
Representati Disadvantag
on Structure Advantages es
Doesn't accurately
Simple to draw and represent cyclic
Fisher projection Straight chain understand chirality structure
Accurate Can be difficult to
representation of visualize 3D
Haworth projection Cyclic structure cyclic structure conformation
Accurate
representation of
3D conformation
And understand
affect the stability
Conformational 3D arrangement of and reactivity of the Can be complex and
representation atoms sugar molecule. difficult to draw
Structural representation
Sugars can be drawn in the straight chain
form as either Fisher projections or
perspective structural formulas.
ENANTIOMERS

D L
Glyceraldehyde

Typically but not always
These molecules have a measurable
D - sugars
optical rotation, which depends upon
L – amino acids both the monomer residues and their
conformation
 Haworth projections are more realistic than the Fisher
projections
In general, if a substituents points to the right in the Fisher
structure, it points down in the Haworth. if it points left, it
points up.
 and  anomers:
OH group on the same side of the oxygen ring:  anomer
OH group on the opposite side of the oxygen ring:  anomer
CHIRALITY
Chiral center – an atom in a molecule that has 4
different group tetrahedrally bonded to it
Chiral molecule – a molecule whose mirror image are
non superimposable
Achiral molecule – a molecule whose mirror image are
superimposable
Classification and Nomenclature
Monosaccharide names
classify the compounds in
two ways simultaneously, by
combining two kinds of
prefixes before –ose:
Those with an aldehyde group
are aldoses; those with a
ketone group are ketoses
Those with three, four, five
and six carbons are trioses,
tetroses, pentoses and
hexoses respectively
D- Glucose ( Aldohexose)
Grape sugar , Dextrose , Blood sugar
Most abundant in nature
Most important from a human nutritional
standpoint
Tastes sweet and nutritious. They are
usually ripe fruits – ripe grapes that has
20-30% glucose by mass
Cell use glucose as a primary source of
energy
D- glucose = sweet and nutritious
L – glucose = tasteless , the body cannot
use it
USE OF MONOSACCHARIDE
Glucose ( 50%) is hypertonic
and provides a source of
calories in a minimal volume of
water.
Glucose 50% is frequently used
to restore blood glucose
concentrations in the treatment
of hypoglycemia resulting from
insulin excess or from other
causes.
Galactose (aldohexose)
Brain Sugar ( it is a
component of glycoproteins
found in the brain and nerve
tissue
Synthesized from glucose in
the mammary glands for use
in lactose
What makes it important: A
component of glycoproteins
found in brain and nerve
tissue
Present in the chemical
D- Fructose ( Ketohexose)
Levulose, Fruit Sugar
Most important ketohexose
Found in many fruits
Main sugar in semen
The most sweetest tasting of all sugars,
found in many fruits and it is equal in honey
in equal amounts with glucose
Used as a dietary sugar not because it has a
fewer in calories per gram but because less
is needed for the same amount of
sweetness
Structurally identical to glucose from carbon
3 to 6
Uses of Monosaccharides
Fructose: as an
intravenous energy
source for patients with:
Hepatic disease,
Uncontrolled diabetes
mellitus
Postoperative state.
What is Disaccharides?
A disaccharide consists of 2
monosaccharide units held
together by a glycosidic
bond( links a sugar to another
group)
Disaccharides

Sucrose Lactose Maltose
Condensation products of two monosaccharide units
Homo oligosaccharide
Maltose (D-glucopyranosyl- -1,4-D-glucopyranose)
Isomaltose (D-glucopyranosyl- -1,6-Dglucopyranose)
Cellobiose (D-glucopyranosyl- -1,4-Dglucopyranose)
Hetero oligosaccharide
Lactose (D-galactopyranosyl-β-1,4-D-glucopyranose)
Sucrose (D-glucopyranosyl--1,2-D-fructofuranoside)
Glycosidic linkage
The bond that links the two monosaccharides of a
disaccharide together
The bond in the disaccharide resulting to form the
reaction between the hemiacetal carbon atom OH group
of one monosaccharide and other OH group of
monosaccharide
It is always carbon – oxygen – carbon bond in a
disaccharide
MEME TIME

MONOSACCHARIDE
MONOSACCHARIDE
Cellobiose
Produced as an intermediate in the hydrolysis of the
polysaccharide cellulose
Contains two D-glucose monosaccharide units linked
through 91-4 glycosidic linkage. It differs in maltose in
one of the D-glucose untis , it has a beta configuration
Cannot be digested by humans
 Sucrose
Common table sugar, cane sugar
Most abundant disaccharide
Found in fruits and vegetables
Sucrose is a nonreducing sugar. No
hemiacetal is present in the
molecule because of the glycosidic
linkages involve by the reducing Formed by the acetal formation
between the hemiacetal –OH of
agent α-D-glucose and β-D-fructose
In the solid state and in solution Linkage: α,β (1 2)
exist in only one for there are no
beta or alpha isomers
The open chain form is not possible
for this
Lactose
Milk sugar
Occurs naturally only in milk
Enzymes in mammalian
mammary glands take glucose
from the blood stream and
synthesizing lactose
Milk contains the α and β
anomers of lactose in a 2:3 ratio
b-lactose is sweeter and more Souring of milk is caused by the
soluble than ordinary a- lactose conversion of lactose to lactic
Contains D-galactose and D-glucose acid by bacteria in the milk
joined by a β(1 - 4) glycosidic
linkage
From the hemiacetal –OH (at C1)
of D-galactose to the C4 position of
D-glucose
Why does milk bother me?
At your best friend's blowout
party
(for you! - having been
accepted to medical school) last
weekend, everyone pigged out on
cheese burger, cheese pizza, ice
cream and fruit shake. You were
having a great time, but after about
an hour you started feeling awful.
First your stomach felt really full -
almost too full. Then it started to ache
and you had a lot of gas - phew!
Before long, you were running to the
bathroom because you had to poop
and you couldn't wait! Oh, no!
Maltose
Malt sugar or corn sugar
Produced by the partial
hydrolysis of starch by amylase
Produced whenever the
polysaccharide starch breaks
down, as happens in plants
when seeds germinate and in
human beings during starches
digestion
Common ingredients in baby Malt – geminated barley that
food and found in malted milk has been baked or ground. It
contains maltose

Formed by two D-glucose residues
linked by an α(1 4) glycosidic
linkage
Uses of Disaccharides

Maltose can be converted from
icodextrin which is used in dialysis
solutions.
Sucrose : It is often used in
medications to impart a more
pleasant taste to often unpalatable
chemicals
Iron Sucrose : is a medicine
which is used in iron deficiency
POLYSACCHARIDES:
Made up of repeating units of monosaccharides held
by glycosidic bonds
During its formation, a water molecule is released at
each condensation
4 parameters to distinguish
POLYSACCHARIDES
Identify of the monosaccharide repeating unit in the
polymer chain which is homopolysac or heteropolysac
Length of the polymer chain
Type of glycosidic linkage between monomer units A
&B
The degree of the branching of the polymer chain
POLYSACCHARIDES:
They are ideal as STORAGE AND AS STRUCTURAL
COMPONENTS
They are of 2 types Homoglycans and
Heteroglycans.
Polysaccharides
Homoglycans
Amylose: linear chain of -D-glucose linked via -1,4 glycosidic
bonds
Amylopectin: branched chain structure composed of -D-
glucose in -1,4 linkages and -1,6 linkages at branching points
Starch: a mixture of amylose and amylopectin
Glycogen: resembles amylopectin in having -1,6 branches
from an -1,4 chain, although more branched
Cellulose: unbranched chain of D-glucose with -1,4 linkages
Starch
Polymers of D-glucose
α-linkage in starch, β-linkage in cellulose
Types of starches distinguished by degree
of chain branching:
Amylose- linear polymer of glucose linked by
α(1,4) bonds

Amylopectin- branched-chain polymer with
branches starting at α(1,6) linkages along the
chain of α(1,4) linkages
Amylose and amylopectin are the 2 forms
of starch. Amylopectin
is a highly branched structure, with
branches occurring every
12 to 30 residues
USES OF POLYSACCHARIDES

This polysaccharide is
produced by most green
plants as an energy
store
Starch
Unlike cellulose, starch can
be metabolized by humans.
Starches provide the bulk of
the energy we obtain from
grains, potatoes etc.

Amylose

Amylopectin
Suspensions of amylose
in water adopt a helical
conformation

Iodine (I2) can insert in
the middle of the amylose
helix to give a blue color
that is characteristic and
diagnostic for starch
Cellulose
Linear homopolymer of b-D-glucose all linked by
b(1,4) glycosidic bonds
Most abundant of all carbohydrates

Individual polysaccharide chains are hydrogen bonded
giving plant fibers mechanical strength
Cellulose

n ~ 5000-10000
Also found in some bacteria, Wood cell (fiber) cell walls
algae, fungi, seed hairs, and are made of cellulose +
animals (tunicates or sea Microfibrils lignin and hemicelluloses
squirts) of cellulose
 Cellulases are found
in bacteria including
those that inhabit
the digestive tracts
of grazing animals
and insects
Yields glucose upon
complete hydrolysis
Partial hydrolysis
yields cellobiose
Gives no color with
iodine
 Why can’t we eat
cellulose?
An angry delusional
vegan is making you eat
grass
Why grass is a good food
for a cow and not for
humans?
They learned from their
teacher that potatoes, rice
and cellulose in grass have
Animals lack the enzyme
similarities in their
cellulase which
composition butattack β-
not grass
linkages
Glycogen
A highly branched polymer of
glucose..
Glycogen
Known as animal starch
Branched-chain polymer of α-D-
glucose with a chain of a(1,4)
linkages with a(1,6) linkages at
branch points
Branch points occur every 10
residues (every 25 in amylopectin)

Stored in muscle and liver

Glycogen and iodine gives a red-
violet color
USES OF POLYSACCHARIDES

Glycogen:
Storage of excess sugar
in animals;
Stored in liver and
muscles
It is the animal short-term
storage form of energy
Chitin
Similar in structure and function as cellulose

Linear homopolysaccharide with all residues
linked in β(1,4) glycosidic bonds

Monomer is N-acetyl-β-D-glucosamine

Major structural component of the
exoskeletons of insects and crustaceans and
in cell walls of algae, fungi, and yeasts
USES OF
POLYSACCHARIDES
C H I T I N : U S E D A S A S T R U C T U R A L M AT E R I A L I N
Dextrins
produced by the partial
hydrolysis of starch
amylodextrins, erythrodextrins or
achrodextrins

used in infant formulas to
prevent the curdling of milk in
baby’s stomach
Dextrans
contains a (1,4), a (1,6) and a (1,3) linkages

MW: 40,000; 70,000;
75,000
used as
plasma also used as
extenders in molecular
the sieves in gel
treatment of filtration
shock chromatograph
y
USES OF POLYSACCHARIDES

Dextran :
Polysaccharide made of many
glucose
It is used medicinally as an
antithrombotic, to reduce
blood viscosity
Glycosoaminoglycans
Complex
carbohydrates
containing amino
sugars and uronic
acids
May be attached to
a protein molecule
to form a
proteoglycan
Proteoglycans
provide the ground
or packing
substance of
connective tissue
Glycosoaminoglycans
(mucopolysaccharides)
Long unbranched polysaccharide
chains composed of repeating
disaccharide units – a uronic acid
(except keratan sulfate) and an
amino sugar.
The different classes are
distinguished by:
Sugar residue
Type of linkage between these
residues
Number and location of the sulfate
groups
Repeating disaccharide unit:D- Repeating disaccharide unit:
glucoronic acid or L-iduronic acid D-galactose and N-acetyl-D
glucosamine-6-sulfate

Linkage of the two sugars is by - Linkage of the two sugars is by -
1,3 and in between disaccharide 1,4 and in between disaccharide
units is -1,4 units is -1,3
Carbohydrates as membrane components
Bacterial cell wall
Bacterial cell wall is made of carbohydrates covering the
outside of cell membrane.
Gram positive bacteria have simpler but a thick wall of
peptidoglycan
Gram negative have less peptidoglycan, but more complex in
structure with periplasmic space and lipopolysaccharides.
Plant cells also use cell wall to stabilize their structures.
Animal cells have extra-cellular (outside of the cell) matrix
instead and they are more dynamics (being formed or
disorganized quickly).
Bacterial cell wall

Bacterial cell wall polysaccharides consist of
repeating units of N-acetyl glucosamine and N-
acetylmuramic acid linked by -1,4 bonds.
USES OF
POLYSACCHARIDES
Inulin
Polymer of fructose i.e. fructosan
Found in bulbs, garlic, onion etc.
Inulin is not readily metabolized in the
human body and is readily filtered
through the kidney. Hence used for
testing kidney function
 Biomedical Importance of
Carbohydrates
Preferential source of energy
Form of stored chemical energy
Cellular structure (chitin, cellulose, pectins)
Components of biologically important substances
Aid in molecular recognition
EXCESS CARBOHYDRATES
What is Glucose oxidase?
Glucose oxidase converts glucose to gluconic
acid and hydrogen peroxide
When the reaction is performed in the presence
of peroxidase and o-dianisidine a yellow color is
formed
The basis for the measurement of urinary and
blood glucose
Testape, Clinistix, Diastix (urinary glucose)
Dextrostix (venous glucose)
Glucose measurement methods
Most These
methods are reactions
enzymatic produce either
methods a product that
3 enzyme can be
systems are measured
currently used photometricall
to measure y or an
glucose: electrical
Glucose oxidase current that is
Glucose proportional
dehydrogenase to the initial
Hexokinase glucose
concentration
Esterification Reactions
The hydorxyl group of
sugars can react with
acids and derivatives
of acids to form esters.
Phosphate esters are
the usual
intermediates in the
breakdown of
carbohydrates to
provide energy.
Oxidation to produce acidic
sugars
The primary alcohol oxidize into aldehyde and the
aldehyde is then will undergo oxidation to produce
carboxylic acid.
Reduction to produce sugar alcohol
Aldehyde will be reduced to primary alcohol
The main product/end product is the sugar alcohol
called Alditol
Reduction
Sorbitol
Used as moisturizing
agent in food and
cosmetics industry
High affinity for water
Also used as a
sweeting agent in
chewing
Glucose after reduction will
become sorbitol
Carbohydrate Metabolism
Terms to Remember
 Glycolysis
Glycolysis is the process in which glucose is broken
down to produce energy.
It produces two molecules of pyruvate, ATP, NADH and
water.
The process takes place in the cytoplasm of a cell and
does not require oxygen.
Glyconeogenesis
is the process of creating
glycogen and sugars like
glucose from non-
carbohydrate sources, such
as amino acids and lactate.
Importance of Gluconeogenesis
During deprivation, the gluconeogenesis cycle is
important for blood glucose regulation.
Many cells and tissues, including RBCs, neurons,
skeletal muscle, the medulla of the kidney, testes,
and embryonic tissue, rely on glucose to meet their
energy needs.
The Neoglucogenesis cycle removes metabolites
such as lactate (produced by muscles and RBCs)
and glycerol from the bloodstream (produced from
adipose tissue).
Gluconeogenesis
takes place in the liver and cortex of kidneys. It usually
takes place when the carbohydrates in the diet are
insufficient to meet the demand of glucose in the body.

Glucagon is a hormone that is secreted by the α-cells
of pancreatic islets when the body’s blood glucose level
begins to drop. By two mechanisms, glucagon regulates
the transition of fructose 1, 6-bisphosphate to fructose
6-phosphate or promotes the process of
gluconeogenesis.
What is Glycogenesis
Glycogenesis is the
metabolic process by
which glucose is
converted into glycogen
and stored primarily in
the liver and muscles.
It is essential for
maintaining blood sugar
levels and providing a
readily available energy
source.
Glycogen Storage
Liver glycogen: Serves as
a glucose reservoir for the
whole body, especially
during fasting.
Muscle glycogen: Primarily
used as a local energy
source for muscle
contraction.
Regulation of Glycogenesis:
Insulin: Stimulates glycogenesis by activating glycogen
synthase and inhibiting glycogenolysis (the breakdown
of glycogen).
Glucagon: Stimulates glycogenolysis and inhibits
glycogenesis.
Adrenaline: Stimulates glycogenolysis in muscle cells to
provide energy for a fight-or-flight response.
Allosteric regulation: Glucose-6-phosphate can
allosterically activate glycogen synthase.
Glycogenolysis
Glycogenolysis is the
process of glycogen
degradation.
Glycogenolysis happens in
the liver and kidney to
produce glucose for
balancing the blood sugar;
however, it produces G6P
in muscle cells to be used
as the energy supplier of
myocytes.
 Activity of the Day
Choose one of the Infographic Requirements:
Visual Appeal: Use a visually appealing design
following carbohydrate- with clear fonts, colors, and images.Content:
Title: A catchy and informative title that
related illnesses and accurately reflects the topic.
research its causes, Introduction: A brief overview of the illness
Prevalence and statistics
symptoms, and Causes: Explain the underlying causes or risk
prevention strategies.
Carbohydrate-Related Illnesses: factors.
Symptoms: Describe the common symptoms
Type 1 Diabetes
Then, design and create
Type 2 Diabetes
experienced by individuals with the illness.
Prevention: Discuss preventive measures, such
anCeliac
infographic
Disease that as dietary changes, lifestyle modifications, or
clearly
Lactoseand concisely
Intolerance
medical treatments.
Treatment: Provide information about available
presents this Diseases
Glycogen Storage treatment options.
Sources: Cite credible sources for your
information. information (e.g., medical journals, health
organizations).