Lipid Chemistry Past Paper PDF

Summary

This document is a set of lecture notes detailing lipid chemistry. It covers topics such as classification of lipids, properties of fatty acids, and the interaction of lipids with aqueous phases.

Full Transcript

‫ْ‬ ‫ُ‬
‫َوقل َّرب زدني‬
‫ْ‬
‫عل ًما‬
‫سورة طه ‪ -‬اآلية ‪114‬‬
 Lipid
Chemistry
Directed by
Pro.Dr/ Maathir kamel
  Intended learning outcomes
(ILOs):
A) Knowledge and Understanding
By the end of the course, students should be able to:
1. Define simple and complex lipids
2. Indicate the structure saturated and unsaturated fatty acids
3. Explain the importance of essential fatty acids and eicosanoids
4. Outlines the structure of triacylgycerol, phospholipids, and
glycophopholipids and indicate their importance

B) Professional and Practical Skills
B1. Identify the physical and chemical properties of lipids.
 Lipids are heterogenous organic compounds
formed of alcohol and fatty acid. They have
the common property of being insoluble in
water and soluble in non-polar solvents such as
ether, chloroform and benzene.
  Importance of lipids:
1. In the body, fat serves as an efficient source of energy, each 1 gm of fat
gives 9.3 Kcal.
2. It serves as thermal insulators in the subcutaneous tissues and around
certain organs e.g kidney.
3. Lipids act as electrical insulators, allowing rapid propagation of the
depolarization waves along the myelinated nerves. The fat content of
nerve tissue is high.
4. Lipoproteins (combination of fat and protein) serve as means of
transporting lipids in the blood. They occur both in the cell membrane
and in the mitochondria within the cytoplasm.
5. The fat of natural foods contains fat-soluble vitamins and essential fatty
acids.
  Classification of lipids:
(A) Simple lipids:

These are esters of fatty acids with alcohol.
According to the alcohol, they are sub classified into:

1. Neutral fats: These are esters of fatty acids with
glycerol. A fat in the liquid state is called oil.

2. Waxes: These are esters of fatty acids with higher
molecular weight monohydric alcohols.
(B) Complex lipids:
These are esters of fatty acids with alcohol containing in
addition other groups. According to these groups, they are
sub classified into:
(1) Phospholipids:
These contain in addition to fatty acids and an alcohol, a
phosphoric acid residue.
(2) Glycolipids (Glycosphingolipids):
These contain in addition to fatty acids and sphingosin and
carbohydrate.
(3) Proteolipids:
These contain in addition to fatty acids and alcohols, a
protein radical.
(4) Other complex lipids:
Such as sulfolipids and amino lipids.
(C) Precursor lipids and derived lipids:
These include substances obtained by the hydrolysis of the
above groups. They include: fatty acids, glycerol, steroids,
alcohols in addition to glycerol and sterols, fatty aldehydes
and ketone bodies, hydrocarbons,
 GLYCEROL
Glycerol is colorless, odorless and sweet liquid
which is miscible with water, insoluble in fat
solvent.

Glycerol is a trihydric alcohol which can be
esterified with one, two or three fatty acids giving
mono-, di-, or triacylglyceol respectively.
 Glycerol is always phosphorylated at C-3 by
the enzyme glycerokinase giving glycerol-3
phosphate.
 FATTY ACIDS
Fatty acids are monocarboxylic acids, which occur mainly as
esters in natural fats & oils. Fatty acids occurring in natural fats
are usually straight chain & contain an even-number of carbon
atoms.
Carbon atoms are numbered from the carboxyl carbon (carbon
No.1). The carbon atom adjacent to the carboxyl group is
known as C-2.
Fatty acids may be saturated (containing no double bonds) or
unsaturated (containing one or more double bonds).

(A) Saturated fatty acids:
Saturated fatty acids contain no double bonds with general
formula CnH2nO2 and occur in nature. Saturated fatty
acids include:
Acetic acid:CH3COOH. It is an end product of
carbohydrate fermentation by rumen organisms.
Propionic acid: CH3CH2COOH.
Butyric acid:CH3CH2CH2COOH. It occurs in small
amounts in certain fats (especially butter).
Valeric acid: CH3(CH2)3COOH.
 Caproic acid:CH3(CH2)4COOH.

Palmitic acid: CH3(CH2)14COOH. Common in
animal and plant fats.

Stearic acid: CH3(CH2)16COOH. Common in
animal and plant fats.

Lignoceric acid: CH3(CH2)22COOH. Found in
cerebrosides and peanut oil.
 (B) Unsaturated fatty acids:

These contain one or more double bonds.
The number and position of double bonds
can be indicated by the greek letter delta
e.gΔ9 means a double bond between
carbon atoms 9 and 10 of the fatty acids as
in oleic acid.
 The position of double bonds can be indicated
according to its relation to the methyl carbon
as, omega-6 in linoleic and arachidonic acids
and omega-3 in linolenic acid.
 Unsaturated fatty acids:
According to the degree of unsaturation, they are
subdivided into:
(1) Monounsaturated (monoethenoid) fatty acids:
These contain one double bond ; general formula CnH2n–
1-COOH. Examples include: palmitoteic and oleic acids.
Palmitoleic acid: (C16: Δ9)
CH3-(CH2)5-10CH=9CH-(CH2)7COOH (ω-7)
Oleic acid: (C18:Δ9)
CH3-(CH2)7-10CH=9CH-(CH2)7.COOH (ω-9)
(2) Poly unsaturated ( potyethenoid) fatty acids:
These contain 2 or more double bonds. Examples include:
Linoleic acid: (C 18:2,∆ 9,12) (ω-6)
CH3-(CH2)4- 13CH=12CH.CH2.10CH=9CH-(CH2)7.COOH

Linolenic acid: (C18: 3,∆ 9,12,15) (ω-3)
CH3-.(CH2.CH=CH)3-(CH2)7.COOH
Arachidonic acid: (C20: 4, ∆5,8,11,14) (ω-6)
CH3-(CH2)3.(CH2.CH=CH)4-(CH2)3.COOH
CH3-CH2-CH=CH-CH2-CH=CH-CH2-CH=CH-(CH2)7-COOH
 Essential fatty acids
These are polyunsaturated fatty acids cannot be
synthesized in the body at a sufficient rate and must be
taken in diet e.g. linoleic acid and linolenic acid.
Sources
1- Plant oils e.g. corn oil, safflower, sunflower and
linseed oil.
2- Fish oils e.g. shark liver oils which contain ω-3
polyunsaturated fatty acids.
Importance of essential fatty acids:
They are important for:
1- Formation of phospholipids and cholesterol ester.
2- Enter in structure of cell membrane and are required
for the fluidity of cell membrane.
3- Normal growth.
4- They protect against atherosclerosis and coronary
heart disease by decreasing cholesterol and LDL.
5- Arachidonic acid is a precursor of eicosanoids.
  Properties of fatty acids:
The chain length & degree of unsaturation affect the
physical and physiological properties of fatty acids.
These properties include:

(1) Solubility:

The short chain fatty acids (FA) up to 6 are
soluble in water, while the long chain ones are
insoluble in water soluble in fat solvent.
(2) Melting point:

The melting point of FA increases with the chain
length and decreases according to the
unsaturation. Thus acetic and oleic acids are
liquids while palmitic & stearic acids are solids
 Triacylglycerols (Neutral fats)
The triacyiglycerol (triglycerides) are esters of
fatty acids with glycerol.

They are the main storage forms of Fat.
 Oils are triacylglycerol with high content of
unsaturated FA → low Tm = fluid at room
temperature.
 Fats are triacylglycerols with high content of
saturated FA → high Tm = solid at room
temperature..
Chemical properties of triacylglycerols::
(1) Hydrogenation (Hardening):
Unsaturated FA adds 2 hydrogen atoms per double bond, forming
the corresponding saturated FA e.g. oleic acid gives stearic acid.

Adding H2 to saturate the double bonds of unsaturated FA of oils
→ Solid Fat.
(3) Addition of oxygen (Oxygenation):

The unsaturated FA in fats add 2 oxygen atoms
per double bond, forming peroxides which are
unstable, breaking into short chain aldehydes,
ketons and acids.
(4) Rancidity:
Rancidity is the development of bad odor and
taste in the fat.
It is caused by its exposure to moisture, oxygen,
warmth, light and certain metals as copper and
lead.
 Rancidity forms peroxides which break into short
chain aldehydes, ketones, alcohols, and acids

 Peroxidation of lipids is responsible for the
deterioration of food and also for damage to the
tissues in vivo causing cancer, inflammatory
disease, atherosclerosis and aging.

Rancidity can be prevented by phenols and anti-
oxidants, avoidance of exposure to oxygen of the
air, moisture or bacteria..
 Waxes
Waxes are esters of fatty acids with higher
molecular weight monohydric alcohols. They are
solids and resistant to hydrolysis.
 COMPOUND LIPIDS
Compound lipids contain groups in addition to an
alcohol and a fatty acid. They include the following:

(A) Phospholipids

(B) Glycolipids

(C) Proteolipids
 (A) Phospholipids
I. Glycerophospholipids
II.Shingolipids
Phospholipids (phosphatides) are compound lipids
containing a phosphate radical. They include:
 Glycerophospholipids
 They are the main lipid constituents of cell
membranes.
 They may be regarded as derivatives of
phosphatidic acid.
(1) Phosphatidic acid:
It consists of glycerol esterified with 2 FA and
phosphoric acid at the third position.
-Phosphatidic acid is important as an intermediate in
the synthesis of triacylglycerols and phosphoglycerols.
It is not found in tissues.
Glycerophospholipids include:
(2) Phosphatidylcholines (Lecithins):

Lecithins consist of phosphatidic acid
esterified with choline.
 The most important phospholipids of the cell
membrane.
They represent the body’s store of choline which is
important in nervous transmission and acts as doner
of methyl groups.
Dipalmitoyl-lecithin (lung surfactant) is a very
effective surface active agent, preventing adherence
of the inner surfaces of the lungs.. It is absent from
the lungs of premature infants causing respiratory
distress syndrome.
(3) Phosphatidyl ethanolamine (Cephalins):
Cephalins consist of phosphatidic acid esterified with
ethanolamine. It is present mainly in myelin sheath
of nerves and liver cell membrane.

Ethanolamine
(6) Cardiolipin (Diphosphatidylglycerol):

Cardiolipin consists of 2 molecules of phosphatidic
acids connected through one molecule of glycerol. It
is the major lipid of mitochondrial membranes.
 II.Sphingophospholids
 They contain sphingosine alcohol instead of
glycerol e.g., Sphingomyelins which consists
of:
 Sphingosine + fatty acid (Ceramide) +
phosphoric acid + choline
 They are found in large quantities in brain
and nerve tissue.
 (B) Glycolipids
These are lipids containing a carbohydrate radical.
The major glycolipids found in animal tissues are
glycosphingolipids. They contain ceramide and one
or more sugars and include the following:-
(1) Galactosylceramide (Galactocerebroside):

It is the major glycosphingolipid of the brain and
nervous tissues.

Galactosylceramide consists of sphingosine, a
fatty acid (usually C24) and galactose.
(2) Glucosylceramide:
This is the predominent simple glycosphingolipids of
extraneural tissues. It consists of sphingosine, a fatty acid
(C24) and glucose.
 (C) Proteolipids
These are complex lipids in which the lipid
surrounds the protein, making the molecule insoluble
in water and soluble in fats and fat solvents.
Proteolipids are found in nervous tissues.
 DERIVED LIPIDS
Derived lipids include the following:
(1) Fatty acids
(2)Alcohols e.g. glycerol, myricylalcohol (C30), sterols,
vitamins A &D and sphingosine.
(3) Hydrocarbon e.g. squalene.
(4) Steroids including: sterols, bile acids and steroid
hormones.
(5) Carotenoids.
(6) Vitamins E.
 INTERACTION OF LIPIDS WITH AQUEOUS PHASES

Lipids are insoluble in water, since they contain a predominance of non-
polar groups.
However, phospholipids, sphingollpids, bile salts and to lesser extent
cholesterol posses both polar groups (water-soluble or hydrophilic) and
non-polar groups (water-insoluble or hydrophobic).These lipids are
called amphipathic lipids.
At oil-water interfaces, these lipids become oriented with the polar
group in the water phase and the non-polar group in the oil phase.
A bilayer of these amphipathic lipids
has been suggested as a basic structure
in biologic membranes e.g. plasma,
nuclear, mitochondrial and lysosomal
membranes. In such membranes, the
lipid molecules arrange themselves so
that the non-polar groups of the two
bilayers are towards each other, while
the polar groups are towards the
surrounding aqueous phases.