Lipids - BIOMOL LEC PPT 3 PDF

Summary

This document provides a presentation on lipids, covering their structure, types, and properties. It includes learning objectives and examples of various lipid types, such as phospholipids and waxes.

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Lipids

COMPILED AND ARRANGED BY
JUSTIN RACHELLE P. DIMAGUIBA
 Learning objectives
To describe the molecular structure of a lipid
To classify different types of lipids
To name types of lipids
To describe the physical and chemical
properties of lipids
 Lipids
Organic molecules characterized by their
solubility in non polar solvents such as ether,
chloroform, and acetone
hydrophobic
Function as energy storage, protection of
organs, insulation, and absorption of vitamins
Others are energy sources, hormones or
vitamins
 Structure of Lipids
made of the elements Carbon, Hydrogen and
Oxygen, but have a much lower proportion of
water than other molecules such as
carbohydrates
Unlike polysaccharides and proteins, lipids are
not polymers—they lack a repeating
monomeric unit.
They are made from two molecules: Glycerol
and Fatty Acids
Structure of Lipids
 Structure of Lipids
A glycerol molecule is made up of three
carbon atoms with a hydroxyl group attached
to it and hydrogen atoms occupying the
remaining positions.
Fatty acids consist of an acid group at one end
of the molecule and a hydrocarbon chain,
which is usually denoted by the letter ‘R’.
They may be saturated or unsaturated.
A fatty acid is saturated if every possible bond
is made with a Hydrogen atom, such that
there exist no C=C bonds.
 Saturated FAs
A fatty acid is saturated if every possible bond
is made with a Hydrogen atom, such that
there exist no C=C bonds.
 Unsaturated FAs
Unsaturated fatty acids, on the other hand, do
contain C=C bonds. Monounsaturated fatty acids
have one C=C bond, and polyunsaturated have more
than one C=C bond.
Structure of Triglycerides

Triglycerides are lipids consisting of one glycerol
molecule bonded with three fatty acid molecules.
bonds between the molecules are covalent and
are called ester bonds
They are formed during a condensation reaction.
The charges are evenly distributed around the
molecule so hydrogen bonds to not form with
water molecules making them insoluble in water.
Structure of Triglycerides
Classification of Lipids
 Simple Lipids
Esters of fatty acids with various alcohols:
a) Neutral fats (Triacylglycerol, TG): These are tri-esters of fatty
acids with glycerol.
b) Waxes are esters of fatty acids with higher monohydroxy
aliphatic alcohols.
True waxes are esters of higher fatty acids with cetyl alcohol
(C16H33OH) or other higher straight chain alcohols.
Cholesterol esters are esters of fatty acid with cholesterol.
Vit A and Vit D esters are palmitic or stearic acids esters of Vit
A (Retinol) or Vit D respectively.
 Example of Simple Lipids

Waxes
Waxes are “esters” (an organic compound made by
replacing the hydrogen with acid by an alkyl or another
organic group) formed from long-chain carboxylic acids
and long-alcohols.
Waxes are seen all over in nature. The leaves and fruits
of many plants have waxy coatings, which may protect
them from dehydration and small predators.
The feathers of birds and the fur of some animals have
similar coatings which serve as a water repellent.
Carnauba wax is valued for its toughness and water
resistance(great for car wax).
 Compound Lipids

Esters of fatty acids containing groups, other than, and in
addition, to an alcohol and fatty acids.

a) Phospholipids: They are found chiefly in animal tissues.
They are substituted fats containing in addition to fatty acid
and glycerol, a phosphoric acid residue, a nitrogenous base
and other substituents.
 Examples of Compound Lipids

Phospholipids
Membranes are chiefly made of phospholipids
which are Phosphoacylglycerols.
Triacylglycerols and phosphoacylglycerols are
similar however the terminal OH group of the
phosphoacylglycerol is esterified with phosphoric
acid instead of fatty acid which leads to the
formation of phosphatidic acid.
The name phospholipid comes from the fact that
phosphoacylglycerols are lipids that contain a
phosphate group.
Phospholipids
 Phospholipids (Phosphatides): They are found chiefly in
animal tissues. Substituted fats, consisting of phosphatidic
acid; composed of glycerol, fatty acids and phosphoric
acid found in ester linkage to a nitrogenous base.
Examples of Phospholipids
Lecithin: Lecithin is found in brain, egg yolk and organ
meats. Phosphatidyl choline or serine—phosphatide
linked to choline; a lipotropic agent; important in fat
metabolism and transport— are used as emulsifying agent
in the food industry.
Examples of Phospholipids
Cephalin: Occurs predominantly in nervous tissue.
Phosphatidyl ethanolamine; phosphatide linkage to serine
or ethanolamine.
Examples of Phospholipids
Plasmalogen: They are found in brain, heart and muscle.
Examples of Phospholipids
Lipositol: They are found in brain, heart, kidneys and plant
tissues together with phytic acid. Phosphatidyl inositol means
phosphatide linked to inositol. Their rapid synthesis and
degradation takes place in brain.
Examples of Phospholipids
Sphingomyelin: They are found in nervous tissue, brain
and red blood cells. Sphingosine containing phosphatide;
yields fatty acids, choline, sphingosine, phosphoric acid
and no glycerol.
Examples of Compound Lipids

Glycolipids
Lipids containing carbohydrate moiety are called
glycolipids.
They contain a special alcohol called sphingosine or
sphingol and nitrogenous base in addition to fatty acids
but does not contain phosphoric acid or glycerol.
Examples of Glycolipids
Cerebroside or Glycolipid or Glycosphingosides: They are
found in myeline sheaths of nerves, brain and other tissues.
They upon hydrolysis yields sphingosine, galactose (or
glucose) and fatty acids.
Examples of Glycolipids
Ganglioside: Found in the brain, nerve tissue and other
selected tissues, notably spleen. They contain a ceramide
linked to hexose (glucose or galactose), neuraminic acid,
sphingosine and fatty acids.
Examples of Glycolipids
Sulfolipid: They are found in white matter of brain, liver and
testicle, also found in plant chloroplast. They are
sulphur-containing glycolipid. In sulfolipid, sulphate is
present in ester linkage to galactose.
Examples of Glycolipids

Aminolipids (Proteolipids): They are found in brain and
nerve tissue. They are the complexes of protein and lipids.
 Derived Lipids
Hydrolysis product of simple and compound lipids is
called derived lipids.
They include fatty acid, glycerol, sphingosine and steroid
derivatives.
Derivatives obtained by hydrolysis of those given in
group I and II, which still possess the general
characteristics of lipids.

a) Fatty acids may be saturated, unsaturated or cyclic.
b) Monoglycerides (monoacylglycerol) and Diglycerides
(diacylglycerol)
c) Alcohols
Examples of Derived Lipids

Fatty Acids
a carboxylic acid
either saturated, or unsaturated
a vital constituent of lipids and is released
during fasting from triacylglycerols to
accommodate the energy requirements of the
body
Fatty Acid Structure
 Systematic naming of the
fatty acids

Saturated fatty acids
PREFIX: # of hydrocarbons
SUFFIX: -anoic
Ex:
1. Capric acid (C-10)= decanoic acid
2. Palmitic acid (C-16)= hexadecanoic acid
 Systematic naming of the
fatty acids
Polyunsaturated fatty acids
PREFIX: # of hydrocarbons
SUFFIX: -enoic (1 double bond), dienoic( 2 double
bonds), etc
Ex:
1. Linoleic acid (C-18:2)= cis,
cis-9,12,-octadecadienoic acid
2. Gamma-Linolenic acid (18:3)
6,9,12-octadecadatrieonic acid
 Trivial names

contain no clues to the structures
one must learn the name and associate it with a separately
learned structure
names typically derive from a common source of the compound or
the source from which it was first isolated
EX:
palmitic acid is found in palm oil
oleic acid is a major constituent of olive oil (oleum)
stearic (from the Greek word meaning solid) acid is solid at room
temperature
Spiders (arachnids) contain arachidonic acid
 Greek letters
denote positions relative to the carboxyl
carbon
Classification of Fatty
Acids
 Types of fatty acids
Based on carbon chain length
a. Long-chain fatty acid (C-12 to C-26)
b. Medium chain fatty acid (C-8 and C-10)
c. Short-chain fatty acid (C-4 and C-6)
Types of fatty acids
Based on carbon to
carbon bonds
a. Saturated fatty
acids (SFAs)
b. Monounsaturated
fatty acids (MUFAs)
c. Polyunsaturated
fatty acids (PUFAs)
 Examples of Unsaturated
Fatty Acid

In its symbols form First no. represent C numbers and Second no. represent the double
bond. Greek letter delta( ) signifies double bond.
Types of fatty acids
Fatty acids with carbon-carbon double bond are unsaturated. Saturated fatty acids lack this
double carbon bonding.
 Saturated Fatty Acids

fatty acids have a
single C-C bond
solid at room
temperature
usually contain 12-22
carbon atoms
Ex: Ghee, Butter,
Palmito-oleic acid
etc.
 Saturated Fatty Acids

These belong to the acetic series and have the
general formula of CnH2nO2
Palmitic acid make up about 15 to 50% of the total
fatty acids in fats.
Myristic and stearic acids are also present
Tuberculo- stearic (10-methyl stearic acid) acid
occurs in the lipids of human tubercle bacilli
They are abundant in butter, animal fat, lard,
coconut and peanut oil
 Monounsaturated fatty acid
fatty acids that have one double bond in
the fatty acid chain with all of the remainder
carbon atoms being single-bonded
typically liquid at room temperature but start
to turn solid when chilled
EX: Olive oil, canola oil, peanut oil, safflower
oil and sesame oil.
 Monounsaturated fatty acid
can help reduce bad
cholesterol levels in the
blood
Lowers the risk of heart
disease and stroke
provides nutrients to
help develop and
maintain body’s cells.
contribute vitamin E to
the diet, an antioxidant
vitamin
 Polyunsaturated fatty acids
contain more than one double bond in their
backbone
includes many important compounds, such as
essential fatty acids
give drying oils their characteristic property.
 Polyunsaturated fatty acids
can help reduce bad cholesterol levels in the
blood which can lower your risk of heart
disease and stroke
Oils rich in polyunsaturated fats also provide
essential fats that your body needs but can't
produce itself – such as omega-6 and
omega-3 fatty acids.
 Polyunsaturated fatty acids
Linoleic acid series (18 : 2; 9, 12)
It contains two double bonds between C9 and
C10; and between C12 and C13.
Their general formula is CnH2n–3 COOH.
Dietary sources: Linoleic acid is present in
sufficient amounts in peanut oil, corn oil,
cottonseed oil, soyabean oil and egg yolk
 Polyunsaturated fatty acids
Linolenic acid series (18 : 3; 9, 12, 15): It
contains three double bonds between 9 and
10; 12 and 13; and 15 and 16. Their general
formula is CnH2n–5 COOH.
Dietary Source: Found frequently with linoleic
acid, but particularly present in linseed oil,
rapeseed oil, soybean oil, fish visceras and liver
oil (cod liver oil).
 Polyunsaturated fatty acids
Arachidonic acid series (20 : 4; 5, 8, 11, 14): It
contains four double bonds. Their general
formula: CnH2n–7 COOH
Dietary source: Found in small quantities with
linoleic acid and linolenic acid but particularly
found in peanut oil. Also found in animal fats
including Liver fats.
 Unsaturated Fatty acids

have the Double C-C bond
are LIQUID at room temperature
If one double bond present in fatty acid it is
called Monosaturated or Monoenoic fatty
acids.
If more than one double bond present in fatty
acid it is called Polysaturated or Polyenoic
fatty acid. For e.g. vegetable oil.
Omega-3 polyunsaturated fatty acids
found in oil from
certain types of fish,
vegetables, and other
plant sources
not made by the body
and must be consumed
in the diet
are used together with
diet and exercise to
help lower triglyceride
levels in the blood.
 Omega-6 polyunsaturated fatty acids
are used for
reducing the risk of
heart disease
lower total
cholesterol levels,
lowering "bad" (LDL)
cholesterol levels
raising "good" (HDL)
cholesterol levels
Reduce the risk of
cancer
Omega-6 polyunsaturated fatty acids
family of polyunsaturated fatty acids that
have in common a final carbon-carbon
double bond in the n-6 position
the sixth bond, counting from the methyl
end.
Examples of Derived Lipids

Steroids

The chemical messengers in our bodies are
known as hormones which are organic
compounds synthesized in glands and
delivered by the bloodstream to certain
tissues in order to stimulate or inhibit the
desired process.
 Steroids
-Steroids are a type of hormone which is usually recognized by
their tetracyclic skeleton, consisting of three fused
six-membered and one five-membered ring

-The four rings are
designated as A, B, C & D
as noted in blue, and the
numbers in red represent
the carbons.
 Steroids
Cholesterol is waxy like substance, found only
in animal source foods. Triglycerides, LDL,
HDL, VLDL are different types of cholesterol
found in the blood cells.
Cholesterol is an important lipid found in the
cell membrane. It is a sterol, which means that
cholesterol is a combination of steroid and
alcohol. In the human body, cholesterol is
synthesized in the liver.
 Steroids
These compounds are biosynthesized by all living cells
and are essential for the structural component of the
cell membrane.
In the cell membrane, the steroid ring structure of
cholesterol provides a rigid hydrophobic structure that
helps boost the rigidity of the cell membrane. Without
cholesterol, the cell membrane would be too fluid.
It is an important component of cell membranes and is
also the basis for the synthesis of other steroids,
including the sex hormones estradiol and
testosterone, as well as other steroids such as
cortisone and vitamin D.
 Anabolic steroids pose health risks

Anabolic steroids are abused by some athletes
with serious consequences, including
– violent mood swings,
– depression,
– liver damage,
– cancer,
– high cholesterol, and
– high blood pressure.

© 2012 Pearson Education, Inc.
Examples of Derived Lipids

Eicosanoids
are signalling molecules made by the
enzymatic or non-enzymatic oxidation of
arachidonic acid or other polyunsaturated
fatty acids (PUFAs) that are, similar to
arachidonic acid, 20 carbon units in length.
Examples of Derived Lipids
Eicosanoids

Most eicosanoids are produced from
arachidonic acid, which is a polyunsaturated
fatty acid that you get from eating foods like
animal fats. They have many effects on your
body, including inflammation, fever
promotion, blood pressure regulation, and
blood clotting.
Three classes of eicosanoids
There are three classes of eicosanoids:
prostaglandins, thromboxane, and
leukotrienes.
various eicosanoids are produced
in different cell types by different synthetic
pathways, and have different target cells and
biological actions.
 Examples of Derived Lipids
Ketone bodies
Ketone bodies are produced by the liver
and used peripherally as an energy source
when glucose is not readily available.
The two main ketone bodies
are acetoacetate (AcAc) and
3-beta-hydroxybutyrate (3HB), while
acetone is the third, and least abundant,
ketone body.
 Examples of Derived Lipids
Ketone bodies
Ketone bodies are readily transported into
tissues outside the liver, where they are
converted into acetyl-CoA —which then
enters the citric acid cycle and is oxidized
for energy.
Examples of Derived Lipids
 Examples of Derived Lipids
Ketone bodies
serves as energy fuels for extrahepatic
tissues like brain, heart, or skeletal muscle
play pivotal roles as signaling mediators,
drivers of protein post-translational
modification (PTM), and modulators of
inflammation and oxidative stress.
 Miscellaneous Lipids
Squalene
-a polyunsaturated hydrocarbon with a
formula of C₃₀H₅₀
-found in certain fish oils, especially shark
liver oil, in high amounts and some vegetable
oils in relatively smaller amounts
- Human sebum also contains 13% squalene
as one of its major constituents.
 Miscellaneous Lipids
Carotenoids
-are among the most widely distributed
pigments and naturally exhibit red, orange
and yellow colors
-lipid-soluble pigments, which can be found
in many kinds of fruit, vegetables, fungi,
flowers and some kinds of animals
(Ötles and Çagindi, 2008)
Carotenoids are ubiquitous and essential pigments in photosynthesis.
They absorb in the blue-green region of the solar spectrum and transfer
the absorbed energy to (bacterio-)chlorophylls, and so expand the
wavelength range of light that is able to drive photosynthesis.
Physical Properties of Lipids
Saturated fatty acids are solid at room temperature.
Unsaturated fatty acids are liquid at room temperature.
The long chain length of fatty acid has a high melting point
than short-chain fatty acids.
The solubility of fatty acids decrease due to increase in no.
of the methylene group
Presence of double bond increases the solubility of fatty
acids.
Acetic acid is completely miscible with water because it
contains only 1 methyl group. Palmito-oleic acid is more
soluble than palmitic acid.
Fatty acids form salts with alkali and alkaline earth metal.
Physical Properties of Lipids
Salts of sodium, potassium, calcium, and
magnesium are formed when fatty acids react
with these salts.
Fats have the specific gravity less than 1 and, also
lower than water, therefore, they float on water.
The melting point of fats depends upon their
constituent fatty acids. Greater the amount of
unsaturated fatty acids in the fat molecule, lower
will be the melting point.
Physical Properties of Lipids
Freshly prepared fats are colorless, odorless
and tasteless. Any color or taste is due to
association with other foreign substances.
Example: The yellow color of butter or is due to
the presence of plant pigments carotene and
xanthophyll.
 Chemical Properties of
Lipids
Hydrolysis
Saponification
Reactions due to unsaturation
Saponification number and Iodine number
Rancidity
 Hydrolysis

through heating of fats with water at high
temperature and pressure
The hydrolysis of ingested fats is efficiently
accomplished by enzyme Lipase present in
pancreatic juice.
Hydrolysis of fats
 Saponification

By boiling with strong alkanes such as NaOH,
the fats are readily decomposed into Glycerol
and salts of constituent fatty acids (Soap).
 Reactions due to
Unsaturation

The double bonds of unsaturated fatty acids in
fats undergo the reaction such as:
Hydrogenation
Halogenation
Oxidation
 Hydrogenation
-Hydrogen can be added across the C to C double
bond
-This reaction is called hydrogenation and
decrease the level of unsaturation in the fatty
acid
 Trans Fatty Acid Overview

one sub-type of fatty acid
referred to trans fatty acids simply as trans
fats
helps preserve the shelf life of food
To create a trans fat, an unsaturated fatty acid
and force hydrogen ions in it, under high
pressure
 Health Effects of Trans Fats

association between consumption of trans fats and heart disease
no physiological need for the consumption of trans fats
Trans fats occur in nature only to a small degree (and these may in
fact be healthy)
avoid manufactured trans fats
partially hydrogenated oil on the label, there is trans fat in the
product.
hydrogenated soybean oil, not a healthy fat
Manufacturers are now required to list the grams of trans fat on
the label, but manufacturers can write 0 grams on the nutrition
facts panel, even if there is 0.5 gram of trans fat. To figure out if a
product has trans fat, look for partially hydrogenated and
hydrogenated oil on the ingredient list.
 Halogenation
- Neutral fats containing unsaturated fatty acids have the
ability if adding halogens (hydrogen / hydrogenation and
iodine or iodination) at the double bonds
- for the determination of the degree of unsaturation of
the fat / oil that determines its biological value
 Oxidation

Polyunsaturated fatty acids are oxidized by
non-enzymatic or enzymatic reactions. In
non-enzymatic reaction, lipid peroxidation is an
autoxidation process initiated by the attack of free
radicals, such as reactive oxygen and nitrogen
species (·OH and ONOO−).
 Saponification Number

the number of milligrams of KOH required to
neutralized the fatty acids liberated from 1 gram of fat
Short chain fatty acids have a higher saponification
number.
Long chain fatty acids have high MW and lower
saponification number value= fewer number of
carboxylic functional groups per unit mass of the fat.
Example: Butterfats has a relatively higher
saponification number, as it is rich in short-chain fatty
acids.
https://www.researchgate.net/publication/322818556_Coconut_Oil_Chemistry_and_Nutrition/figures?lo=1
Sample Computation on Saponification
value in post-lab discussion
 Iodine Number

“The number of grams of iodine which will be
absorbed by 100 grams of fat is termed its
iodine number”.
More unsaturated fatty acids have higher
iodine number value than more saturated
fatty acids.
Sample Computation on Iodine
number in post-lab discussion
 Rancidity

Many fats develop an unpleasant odor and
taste when they are allowed to stand in
contact with air at room temperature.
Can be reduced by refrigeration
 The Process of Rancidity
Rancidity is due to two different processes:
1. Oxidative Rancidity
2. Hydrolytic Rancidity
 Oxidative Rancidity

Oxidation of fat molecules gives rise to some
short chain aldehydes and ketones which
have taste and odor.
The oxygen of the air is necessary for the
occurrence of this type of rancidity.
Prevention from Oxidative Rancidity :
This can be prevented by the addition of
anti-oxidants such as Vitamin E to food
containing fat.
 Hydrolytic Rancidity

due to the slow hydrolysis of fats
In case of fats like butter results in the liberation
of short chain fatty acids
with odor and taste
Hydrolysis of fats may be hastened by bacterial
contaminants which produce enzyme lipase
Rancidity also results in a loss of certain essential
dietary constituents such as vitamins A and E,
carotenes and linoleic acid.
Hydrolytic rancidity of fats
End of presentation