Fixed Oils Slides 2024.pdf

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Lipids
PHMD 232

2024

Emelia Oppong Bekoe B.Pharm, M.Pharm, PhD

UGSoP, University of Ghana, Legon
Learning outcomes

Describe the occurrence and sources of fixed oils, fats, and waxes in natural
substances.
Explain the various methods of extraction used to obtain fixed oils, fats, and
waxes from their natural sources.
Identify the physical properties, such as appearance, texture, and melting point,
of fixed oils, fats, and waxes.
Evaluate the pharmaceutical significance of selected oils, fats, and waxes
commonly used in medicinal formulations, such as: Castor oil, Cod-liver oil, Shark
liver oil, Olive oil, Coconut oil etc. etc. , Beeswax
2
 Lipids

These are naturally occurring
organic compounds which are
are defined by their solubility in
nonpolar organic solvents (e.g. ether,
chloroform, acetone, and benzene) and insoluble in water.
They are comprised of fixed oils, fats and waxes.
They serve as structural components of biological membranes.
They provide energy reserves, predominantly in the form of triacylglycerols.
Both lipids and lipid derivatives serves as vitamins and hormones
 Lipids

Lipids (fixed oils, fats and waxes) are esters of
long-chain fatty acids and alcohols or of closely
related derivatives.

The chief difference between these substances is
the type of alcohol.
in fixed oils and fats, glycerol combines with the
fatty acids
in waxes, the alcohol has a higher molecular
weight. acetyl alcohol [CH3(CH2)15OH].
 Fats and oils

Fixed oils and fats are obtained from plants or
animal. They are rich in calories and in plant
source; they are present mostly in the seeds.
They differ only according to their melting point
and chemically they belong to the same group.
If a substance is liquid at 15.5 – 16.5 °C it is called
fixed oil and solid or semisolid at the above
temperature, it is called fat.
They float in water since their specific gravity is
less than 1.
 Fats and oils

Fats and oils are made from two kinds
of molecules : glycerol (a type of
alcohol with a hydroxyl group on each
of its three carbons) and three fatty
acids joined by dehydration synthesis.

Since there are three fatty acids
attached , these are known as
triglycerides.
Triglyceride

Where R1,R2, and R3 are long alkyl chains

The three fatty acids R1COOH ,R2COOH , R3 can all
be different, all the same, or only two the same.
 Structure of
fatty acids

The “tail” of a fatty acid is a long hydrocarbon chain,
making it hydrophobic. The “head” of the molecule
is a carboxyl group which is hydrophilic.
Fatty acids are the main component of soap , where
their tails are soluble in water to emulsify and wash
away the oily dirt.
However, when the head end is attached to glycerol
to form a fat, that whole molecule is hydrophobic.
 Structure of fatty
acids
Since fatty acids in these
triglycerides contain the
maximum possible amount of
hydrogens, these would be called
saturated fats.

The hydrocarbon chains in these
fatty acids are, thus, fairly straight
and can pack closely together,
making these fats solid at room
temperature.
 Structure of fatty acids

Oils mostly from plant sources have some double bonds
between some of their carbons in the hydrocarbon tail,
causing bends or ‘kinks’ in the shape of the molecules.
Because some of the carbons share double bonds, they
are not bonded to as many hydrogens as they could if
they were not double bonded to each other. Therefore,
these oils are called unsaturated fats.
Because of the kinks in the hydrocarbon tails,
unsaturated fats (or oils) cannot pack as closely
together, making them liquid at room temperature.
 Structure of fatty acids

Although most vegetable oils are liquid at ordinary temperatures and most animal
fats are solid, there are notable exceptions, such as cocoa butter, which is a solid
vegetable oil and cod liver oil, which is a liquid animal fat.
 Structure of fatty acids

In unsaturated fatty acids, there are two ways
the pieces of the hydrocarbon tail can be
arranged around a C-C double bond (cis and
trans).
In cis bonds , the two pieces of the carbon
chain on either side of the double bond are
either both ‘up’ or both ‘down’, such that both
are on the same side of the molecule.
In trans the two pieces of the molecule are on
opposite sides of the double bond ,that is ,one
is ‘up’ and one is ‘down’ across from each other.
 Structure of fatty acids

Naturally occurring unsaturated vegetable oils have almost all cis bonds but using oil
for frying causes some of the cis bonds to convert to trans bonds.

If oil is used only once like when you fry an egg, only a few of the bonds convert to
the trans, however, if oil is constantly reused, like in fast food French fry machines,
more and more of the cis bonds are changed to trans until significant numbers of
fatty acids with trans bonds build up. The reason for this concern is that fatty acids
with trans bonds are carcinogenic or cancer causing.
FATS VS FIXED OILS
FATS FIXED OILS
1.Mostly contain saturated fatty acids 1.Majority of the fixed oil contains
unsaturated fatty acids

2.Solid at room temperature 2.Liquid at room temperature

3.Higher melting point 3.Lower melting point
Fixed oil

Fixed oils Properties
Sources Uses
Chemical composition
Tests
Minor components Specific examples
Extraction methods

16
 Fixed Oils

Definition: Fixed oils, also known as non-
volatile oils, are glycerides of fatty acids
that do not evaporate at room
temperature and are not volatile.
Characteristics
Composed mainly of triglycerides.
Insoluble in water but soluble in
organic solvents.
Extracted primarily through cold
pressing or solvent extraction.
Used in food, pharmaceuticals, cosmetics,
and industrial applications
 Examples of Fixed Oils

Castor oil Almond oil
Olive oil Cotton seed oil
Peanut oil Corn oil
Soybean oil Safflower oil
Sesame oil Cocoa butter
 Sources of Fixed
Oils
Plant Sources:
Seeds: Sunflower, sesame,
flaxseed
Fruits: Olive, avocado
Nuts: Almond, coconut
Others: Castor, soybean
Animal Sources:
Fish: Cod liver oil.
Other: Lard, tallow
Chemical Composition
Triglycerides:
Esters derived from glycerol and three fatty acids.
The type of fatty acids (saturated, monounsaturated,
polyunsaturated) determines the oil's properties.
Fatty Acids:
Saturated Fatty Acids: No double bonds (e.g., palmitic acid, stearic
acid).
Monounsaturated Fatty Acids: One double bond (e.g., oleic acid).
Polyunsaturated Fatty Acids: Multiple double bonds (e.g., linoleic
acid, alpha-linolenic acid).
Fixed Oils & Fats : CHEMISTRY
Fixed oils are esters of fatty acid with glycerol. These may be –
Monoglycerides
Diglycerides
Triglycerides
Chemical Composition
Minor Components:

Vitamins (e.g., Vitamin E).

Sterols (e.g., beta-sitosterol).

Phospholipids.

Tocopherols.
Methods of Extraction
1. Cold Pressing:

Mechanical process without heat. Oil expelling is a mechanical method of extracting oil from
seeds or nuts by applying pressure using an expeller press. The expeller press can be a screw
press or a hydraulic press, and the process involves several steps

Retains natural nutrients and antioxidants.

2. Solvent Extraction:

Uses solvents like hexane to dissolve oils from plant material.

The solvent is then evaporated, leaving behind the oil.
Methods of Extraction
3. Extraction by expression

Mechanically crushing the seeds or nuts and then pressing them to extract the oil.
This can be done using various types of presses, such as hydraulic presses or screw
presses.

Fixed oils are obtained by expression in hydraulic presses. If the expression is
carried out in the cold , the oil is known as a “virgin oil” or a ‘cold pressed oil. In
contrast, if the expression is carried out in the heat , the oil is known as a ‘hot-
pressed oil’.
Methods of Extraction
4. Refining:

Involves degumming, neutralization, bleaching, and deodorization.
Produces oils with improved shelf life and sensory qualities but may
reduce nutrient content.
5. Animal Fat Rendering
Animals fats are separated from other tissues by rendering with steam, with or
without pressure.
The heat melts the fat, which rises to the top and may be separated by
decantation.
 Uses of Fixed Oils
1. Nutritional:

Source of essential fatty acids.
Used in cooking and food preparation (e.g., olive oil, canola oil).

2. Pharmaceutical:

Used as carriers for drug delivery (e.g., castor oil).
Emollients and moisturizers in topical formulations.
Uses Of Fixed Oils
3. Cosmetic:

Ingredients in skincare and haircare products.
Provide hydration, nourishment, and protection

4. Industrial:

Used in the production of biodiesel.
Lubricants and soaps.
Uses Of Fixed Oils
Suppositories, tablet coating

Dietary supplements

Emulsifying agents

Manufacture of paints, varnishes and lubricants

Therapeutic uses (castor oil)
CASTOR OIL
Synonyms:
Castor bean oil, castor oil seed, Ricinus oil
Biological Source:
It is the fixed oil obtained by cold expression of the
seeds of Ricinus communis Linn., belonging to family
Euphorbiaceae.
Geographical Source:
It is mainly found in India (Gujarat , Andhra, Pradesh),
Brazil , America, China, Thailand
Preparation
1. Castor oil is obtained from castor seeds.
2. The oil is obtained by two ways:
By removal of the seed coat, or
With the seed coat
3. By using grooved rollers seed coat are removed and then
they are subjected to a current of air to blow the testas.
4. The kernels are fed in oil expellers and then they are
expressed under high pressure (at room temperature) in order
to obtain about 30% oil.
Preparation
5.Then oil is filtered and steamed 80 – 100 Degrees to facilitate the coagulation and
precipitation of poisonous principle ricin, proteins and enzyme lipase present in it.

6.Oil is then filtered and this oil with 1% acidity is used for medical purpose.
7. The oil cake (contains of ricin, lipase and about 20% oil) which remains is
grounded, steamed and expressed under high pressure which yields second quality
of oil with 5% acidity and is used for industrial purpose.

8. The residual cake which remains after the expression of the second quality oil
still contains about 8% to 10% and extracted by Soxhlet apparatus which is used as
manure and not fed to animal due to the presence of ricin. The cake is also used for
the production of lipase.
Chemical Constituents
Castor oil consists of glyceride of ricinoleic acid, isoricinoleic, stearic, and
dihydroxy stearic acid (responsible for laxative activity).
Ricinoleic acid, binds to receptors on the smooth muscle cells of your intestinal
walls, and it is absorbed. It causes those muscles to contract and push out stool,
just as other stimulant laxatives do.
Castor oil is non-edible oil, defers from all other oils as having ricinoleic acid as a
major constituent.
Compared to all other oils castor oil is highly viscous, less soluble in hexane and
more soluble in ethanol as a consequence of presence of ricinoleic acid which is a
hydroxyl fatty acid.
Olive oil
Olive oil
Is the fixed oil obtained from the ripe fruits of Olea europaea. Family : Oleaceae
Olive oil is a pale yellow or light greenish yellow liquid with a mild but
characteristic odor.
Constituents:
Glycerides of –
✓Oleic acid(75%), Linoleic acid (9%), Stearic acid, Arachidic acid, Palmitic acid

Uses: Laxative, Nutrient, Emollient, Demulcent (an agent that forms a soothing film
over a mucous membrane, relieving minor pain and inflammation),
PEANUT OIL or ARACHIS OIL
Peanut oil is the refined fixed oil obtained from the seed kernels of Arachis
hypogaea. Family :Leguminosae

Constituents: Glycerides of
✓Oleic acid (50-65%)
✓Linoleic acid (18-30%)
✓Palmitic acid (8-10%)
✓Stearic acid ,Behenic acid, Arachidic Acid and Lignoceric acid (10-12%)
PEANUT OIL or ARACHIS OIL
Uses:
✓Vehicles in emulsions, liniments, plasters, soap.
✓Ink manufacture
✓Preparation of hydrogenated vegetable oil.
COCONUT OIL

Botanical origin
Coconut oil is obtained from dried solid
part of endosperm of Cocos nucifera.
Family : Palmae
Plant part used : Dried solid part of
endosperm
COCONUT OIL
Constituents: Glycerides of –
✓Lauric acid (50%), Myristic acid(20%), Capric acid, Caprylic acid, Caproic acid,
Oleic acid, Palmitic acid, Stearic acid
Uses:
✓Confectionaries
✓Cosmetics
✓Ointment base
Tests for Fixed Oils
 Purpose: To identify, quantify, and determine the quality and purity of fixed
oils.

Significance: A combination of qualitative and quantitative tests provides a
comprehensive analysis.
Essential for quality control in food, pharmaceutical, and cosmetic industries
 Qualitative Tests

Organoleptic Evaluation:

Principle: Sensory analysis based on appearance, odor, and taste.
Procedure:
Observe the color and clarity of the oil.
Smell to detect any rancid or unusual odors.
Taste (if safe) to check for any off-flavors.
Result: Initial assessment of quality and possible contamination
Solubility Test:

Principle: Assessing solubility in various solvents.
Procedure:
Mix the oil with solvents such as ethanol, ether, and chloroform.
Observe the solubility behavior.
Result: Fixed oils are insoluble in water but soluble in organic solvents like ether
and chloroform.
Spot Test:

Principle: Determines the presence of fixed oils through their ability
to leave a translucent spot on paper.
Procedure:
Place a drop of oil on a piece of filter paper.
Allow it to stand and observe the spot.
Result: A persistent translucent spot indicates the presence of a
fixed oil.
Quantitative Tests
Iodine Value:

Principle: Measures the degree of unsaturation in the oil.
Procedure:
1.Dissolve the oil in chloroform.
2.Add iodine monochloride solution.
3.Allow the reaction to proceed and add potassium iodide.
4.Titrate the liberated iodine with sodium thiosulfate.
Result: A higher iodine value indicates a higher degree of unsaturation.
 Quantitative Tests
Saponification Value:

Principle: Measures the amount of alkali required to saponify a given amount of
oil.
Procedure:
1.Heat the oil with an alcoholic potassium hydroxide solution.
2.Titrate the excess alkali with hydrochloric acid.
Result: Provides information on the average molecular weight of fatty acids in the
oil. Higher values indicate shorter chain fatty acids.
 Quantitative Tests

Acid Value:

Principle: Measures the free fatty acids present in the oil.
Procedure:
1.Dissolve the oil in a solvent mixture (ethanol and diethyl ether).
2.Titrate with a standardized sodium hydroxide solution using phenolphthalein as an
indicator.
Result: Higher acid value indicates a higher concentration of free fatty acids, implying
hydrolysis or rancidity.
Peroxide Value:

Principle: Measures the extent of primary oxidation by quantifying peroxides in
the oil.
Result: Higher peroxide value indicates higher levels of oxidative rancidity
Ester Value:

Principle: Indicates the amount of ester present in the oil, derived from the
saponification and acid values.
Result: Provides insight into the ester content of the oil, reflecting the level of
esterification.
Refractive Index:

Principle: Measures the degree to which light is bent as it passes through the
oil.
Procedure:
Place a drop of oil on a refractometer.
Measure the refractive index at a specific temperature.
Result: Each oil has a characteristic refractive index, which can indicate purity
and quality.
Specific Gravity:

Principle: Measures the density of the oil relative to water.
Procedure:
Use a pycnometer or a digital density meter to measure the oil's specific
gravity at a specific temperature.
Result: Provides information about the purity and concentration of the oil.
Waxes
Like fats, waxes are esters of fatty acids. The alcohol, however, is not glycerol but
usually a long-chain, high-molecular weight alcohol e.g. cetyl and stearyl alcohols

In plants, waxes are generally found covering the external parts, like the
epidermis of leaves and fruits, where their main function is to prevent the loss of
water.

Wax is also produced by insects , e.g. the honeycombs of bees and wasps.
Waxes

USES OF WAX
Wax is used in pharmacy to make soft ointments harder and to prepare lip salves.
The technical uses of waxes are substantial e.g. in the shoe polishes and car
waxes.
Waxes
Wax has a melting point above approximately 45 degree celsius (which
differentiates waxes from fats and oils).

Fats and oils may be saponified by means of either aqueous or alcoholic alkali but
waxes are only saponified by alcoholic alkali (this fact is used for the detection of
fats when added as adulterants to waxes).
Examples of waxes
Jojoba wax (Simmondsia chinensis)
Carnauba wax ( Copernicia cerifera)
Beewax (Apis mellifera)
BEES WAX OR YELLOW WAX
Bees wax or yellow wax
Source: Bees wax or yellow wax is the purified wax
obtained from the honeycomb of the bee Apis
nullifera, Family : Apidae
It is a solid varying in colour from yellow to
greenish brown.
Constituents :
✓Esters of fatty & wax acids (72%), chiefly myricyl
palmitate
✓Free wax acids (14%), chiefly cerotic acid
✓Hydrocarbons (12%)
BEES WAX OR YELLOW WAX
USES :
✓In foods and beverages, white beewax and beewax
absolute (yellow beewax treated with alcohol), are
used as a stiffening agent or edible coatings.
✓Component of yellow ointment, cold creams.
✓Beeswax is used in the preparation of ointments,
plasters, fragrant and long-burning candles, body
care products, and polishes
✓Beeswax – based nanoparticles used in topical
applicated protect the skin and increase hydration.
BEEWAX

Swarm bees, the bees that set out to start
a new hive, gorge on the honey stored in
their current hive in order to produce the
beeswax needed to start their new colony.
The bees then digest the honey and
convert the carbs into liquid beeswax.
Beeswax is produced from a gland in the
abdomen of honeybees and is excreted to
create the hive itself. The female worker
bees have 8 glands in their abdomens to
produce the wax when it is time to build
the honeycomb.
 BEEWAX

The wax that is secreted hardens as soon as it hits
the air and forms a wax scale.
After removal of honey, honeycomb is melted in
boiling water.
On cooling the melted wax gets solidified and
floats on the surface of water while the impurities
settle below and honey leftovers get dissolved in
water.
The pure wax is then poured into earthen vessels
wiped with damp cloth and the wax obtained is
yellow wax.
BEEWAX
The yellow beeswax is run on a thin steam of spinning wet drum, from which long
ribbon like strips are scrapped off.

White beeswax is further obtained by bleaching of yellow beeswax under sunlight.

Then chemically obtained with potassium permanganate , chromic acid or chlorine
or charcoal.
ADULTERANTS
Beeswax is adulterated by solid paraffin, ceresin, carnauba wax, or other fats and
waxes of animal or mineral origin.