Quality control tests for liquid dosage forms-2.pptx

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Quality control tests for
Oral liquid dosage forms
Dr Javed Qureshi

Liquid oral
• Liquid orals are the pharmaceutical dosage form in liquid form
containing one or more active ingredients with or without
additives dissolved in a suitable vehicle to be administered
orally either in the form of solution, suspension, emulsions,
elixir and many more.

Types of
liquid
dosage
forms

Type of oral liquids
• Syrup: “In medical terminology, medicinal syrups are nearly
saturated solutions of 85% of sugar in water in which
medicinal substances or drugs are dissolved.”
• Elixirs: “Elixir are clear, flavored Oral Liquids containing one
or more active ingredients dissolved in a vehicle that usually
contains a high proportion of sucrose or a suitable polyhydric
alcohol or alcohols and may also contain Ethanol (95 per
cent) or a dilute Ethanol.”

contd
• Suspensions : “Suspensions are Liquids containing one or more
active ingredients suspended in a suitable vehicle. Suspended
solids may slowly separate on keeping but are easily
redispersed”.
• Emulsions : “An emulsion is defined as a dibasic or heterogenous
liquid preparation immiscible liquids which is dispersed as a
minute globules in another liquid by adding emulsifying agent.

IPQC for liquid
dosage forms
CLEAN AND PURIFIED VEHICLE (WATER):- The
water is filtered and purified at the plant to destroy
any micro-organisms and to remove particles from
the water. Water is tested frequently to ensure that
it is clean and pure before the preparation
• Quality control technicians test the water
frequently to ensure that it is clean and pure.
• Volume in container
Ensure that the final pack contain the desired
volume.

Organoleptic properties
(Appearance)

Visual examination:
• The ingredients and the final
products are carefully examined
for purity and for appearance.
Physical appearance of products
for
patient
adherence
and
compliance is critical so it should
be Good looking, Elegant in
appearance.

pH MEASUREMENT:pH of the oral liquid preparations must be optimum as
per the pharmacopoeial standards and limits of pH .
pH is a measure of the hydrogen ion activity is important
from the standpoint of stability and physiological
suitability of drug and dosage form. The determination is
carried out at a temperature of 25±2°C, unless otherwise
specified in the individual monograph.

Assay
• To detect the strength of API by using suitable analytical
method to produce good finished pharmaceutical.
Uniformity of volume
• This test is suitable for oral liquids and oral suspensions of
viscous preparations. For this test select a sample of 10 filled
containers and determine the weight of the contents of
each container. Determine the weight per ml and calculate the
net volume of the content of each container.

• For non-viscous
and free-flowing
liquids pour completely the contents
of each container into calibrated
volume measures of the appropriate
size and determine the net volume of
the contents of the 10 containers.
• Limits : The average net volume of
the contents of the 10 containers
should not be less than the labeled
amount, and the net volume of the
contents of any single containers
should not less than the percentage
deviation as shown in Table.

Net
Volume
(mL)

Percenta
ge
deviatio
n
50 or less
9%
50-200 mL
5.5 %
200-300
3%

• If this requirement is not met, determine the net volume of the
contents of 10 additional containers.
• The average net volume of the contents of the 20 containers is not less
than the labeled amount and the net volume of the contents of not more
than 1 of the 20 containers is deviating from the limits as mentioned in
table.

SYRUP
Concentration of Syrup
According to B.P: 67.7% W/W
According to USP: 85% W/V
Components of syrup
• Sweetening Agent: Sucrose, Sugar.
• Antimicrobial Preservatives: Benzoic acid, Sodium benzoate, Methyl-, propyl-, and butylparabens.
• Flavorings agents: Orange oil, Vanillin and others.
• Colorants: green with mint, chocolate with brown etc.
• Alcohol (15 to 20%) [if alcohol soluble components are present in syrup]
• Purified water

Quality evaluation of Syrup
• Visual inspection/ Physical appearance.
• Light transmission matter/ Colour.
• PH measurement.
• Physical stability in syrups.
• Sucrose concentration.
• Weight per ml.
• Viscosity.
• Optical rotation
• Solubility.
• Assay of active ingredient

LIGHT TRANSMITTANCE
TEST (Color examination

• In a light transmittance meter, a liquid
sample is checked for colour by passing
light through the sample. The percent of
light transmission is compared to light
transmission rates set for different
grades.
• No fingerprints on test bottle and should
not have bubbles or cloudiness, Any of
these conditions may diminish the light
that is transmitted through the sample
and therefore lowers the grade of the
sample.

pH measurement

• Generally, plain syrup does not require pH adjustment. Only medicated
syrups require pH adjustment in the range of 3 to 6. This is because
general medicaments (drugs) are stable in acidic pH. Hence to ensure
the stability of drugs in syrup up to the defined shelf life (expiry period)
the pH of medicated syrups is adjusted.
• For antacids like Aluminum hydroxide, Magnesium hydroxide the
inherent pH of these drugs (salts) is alkaline and hence medicated
syrups containing these antacid drugs have pH at the alkaline side
(more than 8 to 10) to ensure the stability of formulations up to shelf
life.

Physical stability in syrups

•
•
•
•
•

The syrups must be stable physically e.g.
its appearance (no crystallization and microbial growth)
Color must be completely soluble with other ingredients.
Odor and taste (palatable)
Solid material is completely miscible in liquid.

• DETERMINATION OF SUCROSE CONCENTRATION (FOR
SYRUPS ONLY):- If the concentration of Sucrose in the syrup is
very high it may crystallize the syrup, less sucrose
concentrations give favor for the microbial growth. For the
determination sucrose in syrup, HPLC and UV -spectroscopy
are used.

Optical rotation:
Range is 50°-60°. Syrup should not be less than 50° &
not more than 60°. It is to check the inversion of syrup
Specific gravity:
Specific gravity of syrup either 66.7% w/w or 85% w/v
should be 1.313.

Elixirs

Elixirs are clear, sweetened hydro-alcoholic solutions intended for oral use
and are usually flavored to enhance their palatability.
Evaluation Parameters:
Determination of alcohol content:
Elixir usually contains 5 to 40% alcohol. For liquids, it is presumed to
contain less than 30% of alcohol.

DETERMINATION OF
VISCOSITY:
• Viscosity is a property of liquids that is directly
related to the resistance to flow.
• viscosity measurement is very important
quality control test in case of syrups an elixirs.
• viscosity and consistency directly relates with
stability of solutions.
• Determination of viscosity is done to assess the
changes that might take place during aging.
• The viscometers used are cone and plate
viscometers , Brookfield viscometer .

BIPHASIC
LIQUIDS:

EMUL
SIONS

SUSPE
NSIONS

Emulsion
• An emulsion is a thermodynamically unstable system
consisting of at least two immiscible liquid phases, one of
which is dispersed as globules ( the dispersed phase) in other
liquid phase ( the continuous phase) stabilized by the presence
of an emulsifying agent.

CLASSIFICATION OF EMULSIONS:-

Emulsions can be classified into the following types:1.
2.
3.
4.
5.
6.

Oil in water (o/w) type of emulsion.
Water in oil (w/o) type of emulsion.
Microemulsions ( 0.01 to 0.2 mm, Thermodynamically stable)
Macroemulsion ( 0.2 to 50 mm, Kinetically stable)
Nano emulsion ( 10-1000 nm, Kinetically stable)
Multiple/double emulsion. (o/w/o, w/o/w)

Kinetically stable
/thermodynamically stable
• Nanoemulsions are kinetically stable" means liquids in the
mixture will become separated very slowly. But the
separation will happen eventually.
• "Microemulsions are thermodynamically stable" means the
separation won't happen even waiting for a very-very long
time.
• Kinetic stability refers that from the reactant state (emulsion) to the product state
(separated liquids) the reaction barrier is very high, but the free energy change is
still negative (ΔG < 0). However, thermodynamic stability means the free energy
change from the reactant state to the product state are positive (ΔG > 0), which
means the reaction will not happen if there is no external energy input.

Identification Tests
• Since emulsion (o/w or w/o) looks the same in
appearance with naked eyes, therefore certain
tests have been developed to differentiate
between them. At least two tests should be done
to reach a conclusive decision about the identity
of the emulsion.
• Conductivity Test
• Dye Solubility Test
• Dilution test
• Cobalt Chloride Test
• Fluorescence Test

DILUTION TEST:-

• This test is based on the
solubility of external phase of
emulsion.
• o/w emulsion can be diluted
with water.
• w/o emulsion can be diluted
with oil.

Conductivity Test:
The basic principle of this test is that water is a good conductor of
electricity. Therefore, in case of o/w emulsion this test will be +ve as water
Bulb
is the external phase.
=

Electrode

Bulb glows with O/W

= Bulb doesn’t glow
with W/O

Emulsion

In this test, an assembly is used in which a pair of electrodes connected to an
electric bulb is dipped into an emulsion. If the emulsion is o/w type, the electric
bulb glows.

DYE SOLUBILITY TEST
• When an emulsion is mixed with an oil soluble dye such as
amaranth and observed under the microscope.
• If the continuous phase appears red, then it means that the
emulsion is o/w type as water is the external phase.
• If the scattered globules appear red and continuous phase is
colour less, then it is w/o type.

DYE TEST

Fluorescence test

Principle: When oils are exposed to ultraviolet radiations they
get fluorescence
Test: A small quantity of sample emulsion is allowed to exposing
to ultraviolet radiations and observes the results.
Observations
A fluorescent droplets are observed against colorless
background indicating the type of emulsion is oil in water (O/w)
emulsion or fluorescent background against colorless droplets
indicating the type of emulsion is water in oil (w/o)emulsion

Cobalt chloride test
• When
a
filter
paper
soaked in cobalt chloride
solution is dipped into an
emulsion and dried, it
turns from blue to pink,
indicating
that
the
emulsion is o/w type.

Stability of
Emulsion

What is called a stable emulsion?

A system in which the globules retain their initial character & remain
uniformly distributed throughout the continuous phase.
The three (3) major problems associated with physical stability of emulsion
are:
1. Creaming or sedimentation (upward or downward movement of
dispersed droplets in continuous phase).
2. Cracking (aggregation or coalescence of dispersed droplets to reform
separation).
3. Phase inversion (O/W invert to become a W/O and vice versa)

Flocculation
• This process refers to aggregation of the droplets
(without any change in primary droplet size) into larger
units.
• Flocculation occurs when there is not sufficient
repulsion to keep the droplets apart to distances where
the van der Waals attraction is weak.
• Flocculation may be ‘‘strong’’ or ‘‘weak,’’ depending on
the magnitude of the attractive energy involved

Creaming / sedimentation
Creaming is the rising (upward creaming) or
settling (downward creaming) of floccules to form
a concentrated layer at the surface or at the
bottom of the emulsion. Its a reversible instability
which can be restored by simple agitation
It can be observed by a difference in colour
shade of the layers.

Creaming or Sedimentation
This process results from external forces usually gravitational or centrifugal. When
such forces exceed the thermal motion of the droplets (Brownain motion), a
concentration gradient builds up in the system with the larger droplets moving faster
to the top (if their density is lower than that of the medium) or to the bottom (if their
density is larger than that of the medium) of the container
This is not a serious instability problem as a uniform dispersion can be re-obtained
simply by shaking the emulsion. (It’s a reversible process).
Disadvantages:
• 1.Inelegant in appearance.
• 2.Possibility of inaccurate dosage.
• 3.Increase probability of globules coalescence

Factors affecting creaming :
These factors are described in Stoke’s Law as follows:
V = d2 (ρ1 – ρ2) g / 18 η
• V is the velocity of creaming
• d = diameter of globule/ particles
• ρ1 = density of the particle/globule, ρ2 = density of the vehicle,
• (ρ1 – ρ2) is the density difference of the disperse phase &
dispersion medium
• η is the viscosity of the dispersion medium.

Creaming is decreased by:
• Reduction in globule size (using homogenizer).
• Decrease in the density difference between two phases.
• Increase the viscosity of the continuous phase
(use thickening agent as methyl cellulose).

Viscosity measurement
• As the viscosity increases flocculation of globules will be
reduced simultaneously the Brownian movement of
globules will also be hindered leading to creaming.
• Due to this antagonistic effect an optimum viscosity is
desirable for good emulsion stability.

Globule size
• As the globule size is reduced they tend to exhibit
Brownian movement.
• According to stokes law the diameter of the globule is
considered as a major factor in creaming of emulsion.
• The rate of creaming decreases four folds when the
globule diameter is halved.
• So it is necessary to choose the optimum globule size
for maximum stability.

Globule size distribution
• Globules of uniform size impart maximum stability.
• In such emulsions globules pack loosely and globule to
globule contact is less.
• Globule distribution is affected by viscosity, phase
volume ratio, density of phases etc.
• An optimum degree of size distribution range should be
chosen to achieve maximum physical stability

Globule size
determination

• Microscopic examination of
globule size distribution
analysis is a useful tool to
evaluate the physical stability.

Ostwald Ripening
(Disproportionation)
• This results from the finite solubility of the liquid phases.
• Liquids that are referred to as being immiscible often have
mutual solubilities that are not negligible. With emulsions,
which are usually polydisperse, the smaller droplets will have
larger solubility when compared with the larger ones
• With time, the smaller droplets disappeared, and their
molecules diffuse to the bulk and become deposited on the
larger droplets. With time, the droplet size distribution shifts to
larger values.

Ostwald
ripening

Coalescence
• Coalescence is followed by creaming stage. It’s an irreversible damage to emulsion.
• In this process the emulsifier film around the globules is destroyed to a certain extent. Globules tends to
fuse together and forms bigger globules
• This step can be recognized by increased globule size and reduced number of globules.
• Cracking can be caused by any chemical, physical or biological effect that changes the nature of the
interfacial film of an emulsifying agent tends to make unstable.
Coalescence is observed due to
a)
insufficient amount of the emulsifying agent
b)
altered partitioning of the emulsifying agent
c)
incompatibilities between emulsifying agents
d)
Change in temperature
e)
Presence of micro-organism

Factors causing coalescence
1. Addition of opposite type emulsifying agent:
Example:
1.Soaps of monovalent metals produce o/w emulsions while
soaps of divalent metals produce w/o emulsions. Addition of a
monovalent soap to a divalent emulsions, or addition of divalent
soaps to monovalent emulsions leads to cracking of emulsions.
2. Addition of anionic and cationic emulsifying agents in same
emulsion may leads to cracking of emulsions, because they are
mutually incompatible.

2. Decomposition or Precipitation of emulsifying agents.
• Alkali soaps are decomposed by acids, hence addition of acetic
acid solution to turpentine oil liniment results precipitation of
soft soap leads to cracking of emulsions.
• Addition of alcohol to the emulsions prepared with gums and
the proteins results precipitation of emulsifying agents leads to
cracking of emulsions, because these are incompatible with
alcohol.

3. Addition of common solvent
Addition of liquid in which both dispersed phase and dispersion medium
are soluble forms one phase system and destroys the emulsion ex:
Addition of sufficient alcohol to turpentine liniment results clear solution
because alcohol dissolves soft soap, water and turpentine oil.
4. Microbial action
Emulsions not intended for immediate use should contain preservative
to prevent growth of moulds and bacteria that might over a long period
destroy the emulsifying agent and cause cracking of emulsions.

Incorporation of excess dispersed phase
In a given space the maximum concentration of dispersed phase
can be incorporated into the ideal emulsion is not greater than
74%.
Emulsions with a dispersed phase concentration in excess of 74%
have a marked tendency to crack the emulsion.
Creaming
Keeping creaming condition of emulsion for longer duration of time
may leads to cracking of emulsions.

Phase Inversion
Phase inversion is the result of inverting O/W emulsion into W/O
emulsions or W/O emulsion into O/W emulsion. It is mainly due to
following reasons.
1. Addition of a substance that alters the solubility of the
emulsifying agent
Ex: An o/w emulsion stabilized with Na stearate can be inverted to
w/o type by adding Ca Cl2 To form Ca stearate.
Ex: Addition of monovalent metal soaps to W/O emulsions or addition
of Divalent soaps to O/W emulsion results in phase inversion:

2. Phase volume ratio
• Phase inversion may also be produced by alterations in phasevolume ratio (i.e the proportion or concentration of dispersed
phase in continuous phase).
• The most stable range of disperse phase concentration is 30 to
60%. Incorporation of higher concentration may lead to phase
inversion.

Chemical Stability
3 types
• Oxidation
• Microbial Contamination
• Adverse storage conditions.
• Causes: Change in pH, fluctuation in storage condition, presence of light
in case of light sensitive products, oxidative decomposition

Oxidation
• Many of the oils and fats used in emulsion are of animal or
vegetable sources and can be susceptible to oxygen by the
atmospheric oxygen or by the action of microorganism
• Microbial oxidation can be controlled by antimicrobial agents
• Atmospheric oxidation can be controlled by the addition of
antioxidant like BHA (butylatedhydroxyanisole)

Microbial contamination
• Adversely affect the physicochemical properties of the product:
gas production, color and odor changes, hydrolysis of fats and
oil, pH change and breaking of emulsion.
• w/o products have less chance of microbial spoilage
• Commonly used antimicrobial are Mehtyl paraben and Propyl
paraben

Adverse storage condition
• Adverse storage condition may also cause emulsion instability.
• Increase in temperature increases the rate of creaming due to decreased
viscosity of continuous phase
• Increasing in temperature causes increase in kinetic motion of both dispersed
phase and emulsifying agent which results in more expanded monolayer so
coalescence is more likely.
• Freezing of aqueous phase produces ice crystal which may exert a pressure on
disposed globule and on emulgent layer. In addition the dissolved electrolyte will
concentrate in unfrozen water therefore changing the charge density on
globules. Which leads to cracking
• Certain emulgent may also get precipitate at low temperature

• EVALUATION OF SUSPENSION

Viscosity measurement
• Stability of a suspension is solely dependent on the
sedimentation rate of dispersed phase which is dependent on
the viscosity of the dispersion medium.
• The viscosity of the dispersion medium is measured before
mixing with dispersed phase and also viscosity after mixing is
determined using Brook field viscometer.
• The calculated values are compared with standard values and
if any difference is found necessary corrective action is taken
to get optimized viscosity.

Particle size
determination

• DETERMINATION OF PARTICLE
SIZE:- It is performed by optical
microscopy and Coulter counter
apparatus.

Principle of Coulter counter
In a COULTER COUNTER instrument, a tube with a small aperture on the wall is
immersed into a beaker that contains particles suspended in a low-concentration
electrolyte. Two electrodes, one inside the aperture tube and one outside the tube but
inside the beaker, are placed and a current path is provided by the electrolyte when an
electric field is applied.
The impedance between the electrodes is then measured. The aperture creates what is
called a "sensing zone". Particles in low concentration, suspended in the electrolyte,
can be counted by passing them through the aperture. As a particle passes through the
aperture, a volume of electrolyte equivalent to the immersed volume of the particle is
displaced from the sensing zone. This causes a short-term change in the impedance
across the aperture. This change can be measured as a voltage pulse or a current
pulse. The pulse height is proportional to the volume of the sensed particle.

Principle
of coulter
counter

Principle of optical microscopy
• This
method
for
particle
characterization can generally be
applied to particles not less than 1
μm.
• The microscope eyepiece is fitted
with a micrometer by which the
size of the particles may be
estimate

Principle of optical microscopy

• According to the optical microscopic method, an emulsion or
suspension is mounted on ruled slide on a mechanical stage.
• The microscope eyepiece is fitted with a micrometer by which
the size of the particles can be estimated.
• The ordinary microscope used for measurement the particlesize in the range of 0.2 to about 100 µm

Brownian movement
• Brownian movement of particles prevents sedimentation.
• Brownian movement can be observed, if the size of the particle
is about 2 to 5μm,provided densities of the particles and
viscosity of the medium are favorable.
• Theory of Brownian movement proposes particle size and
viscosity as the major factors.
• Brownian movement depends on the density of dispersed
phase and the density and viscosity of the disperse medium.
• The kinetic bombardment of the particles by the molecules of
the suspending medium will keep the particles suspending,
provided that their size is below critical radius (r).

STABILITY OF SUSPENSIONS:SEDIMENTATION

• Sedimentation means settling
of particle (or) floccules occur
under gravitational force in
liquid dosage form.
• Velocity of sedimentation
expressed by Stoke’s equation

Limitations of Stokes law:
• Stokes’ law is based upon several assumptions, which may not always hold
true for pharmaceutical suspensions. The law has following limitations:
• Valid for only diluted pharmaceutical suspensions that are composed of no
more than 2% solids.
• Considers only free particle settling of particles without interference
• Considers all particles are spherical (Stokes law assumes spherical and
monodisperse particles, which may not be encountered in real system)
• Stokes’ equation is invalid if the density difference in the equation is
negative that is when the particles are lighter than the dispersion medium

• not valid for high content of dispersed solids: When the
solid content of a suspension is high, Stokes’ equation
may not show the real sedimentation rate. High solid
content imparts additional viscosity to the system,
which must be taken into consideration if the correct
rate of settling is to be determined. The equation
contains only the viscosity of the medium.

Application of stokes law
Stokes law is useful in fixing factors to prevent sedimentation.
• Particle size: If the particle size is reduced to half of its original size
the rate of sedimentation decreases by a factor of four.
• Viscosity of medium: The viscosity of suspension should be optimum.
• Density of the medium: The density of medium should be high so
that the difference in densities will be minimal.
• The density of medium can be increased by including ingredients
such as polyvinyl pyrrolidine, sugars, polyethylene glycols, glycerin etc.

Sedimentation parameters
Sedimentation volume (F) or height (H) for flocculated
suspensions:
Sedimentation volume is a ratio of the ultimate volume of sediment
(Vu) to the original volume of sediment (VO) before settling.
F = V u / VO
Where,
• Vu = final or ultimate volume of sediment
• VO = original volume of suspension before settling

Sedimentation volume

The sedimentation volume gives only a qualitative
account of flocculation.

• F has values ranging from less than one to greater than one.
When F < 1
Vu < Vo
When F =1
Vu = Vo
• The system is in flocculated equilibrium and show no clear
supernatant on standing.
When F > 1
Vu > Vo
• Sediment volume is greater than the original volume due to the
network of flocs formed in the suspension and so loose and fluffy
sediment

• A suspension consisting of floccules held together loosely will have large β, while
suspension containing sediment has small β.
• The lower limit of β is equal to 1; which means there is no flocculation, i.e.,
vu = v∞
• How can you induce flocculation?
• You can do that by use of flocculating agents, such as electrolytes, detergents and
polymers.
• Flocculating agents are agents that are added to the medium to promote
flocculation by counter acting the effect of protective layer the thus decrease zeta
potential.

Degree of flocculation (β)

• It is the ratio of the sedimentation volume of the flocculated
suspension ,F , to the sedimentation volume of the deflocculated
suspension, F∞
ß = F / F∞
𝞫
• The maximum value of ß is 1,when flocculated suspension
sedimentation volume is equal to the sedimentation volume of
deflocculated suspension.

Electrokinetic properties

• Electrical Double layer
• Zeta potential
• DLVO theory

Electrokinetic properties
• Zeta Potential: The zeta potential is defined as the difference
in potential between the surface of the tightly bound layer
(shear plane) and electro-neutral region of the solution.
• As the potential drops off rapidly at first, followed more gradual
decrease as the distance from the surface increases.
• This is because the counter ions close to the surface acts as a
screen that reduce the electrostatic attraction between the
charged surface and those counter ions further away from the
surface

• Zeta potential has practical application in stability of systems containing
dispersed particles .
• Since this potential, rather than the Nernst potential, governs the degree
of repulsion between the adjacent, similarly charged, dispersed particles.
• If the zeta potential is reduced below a certain value , the attractive
forces exceed the repulsive forces, and the particles come together
• The flocculated suspension is one in which zeta potential of particle is -20
to +20 mV.
• Thus, the phenomenon of flocculation and de flocculation depends on
zeta potential carried by particles

Electrical Double
layer
EDL is a transition region between
two phases consists of,
• An inner molecular layer
• A layer intermediate between
inner molecular layer and the
outer diffuse layer
• An outer diffuse region

Electrical Double
Layer
According to Stern, an electrical double
layer consists of two parts;
One part of the double layer , known as
fixed part (STERN LAYER) remains almost
fixed to the solid surface. It has positive or
negative ions. There is a sharp fall of
potential.
The second part of the double layer, known
as diffuse part (DIFFUSE LAYER) extends to
some distance into the liquid phase. This
layer contains ions of both signs. Its net
charge is equal and opposite to that on the
fixed part. There is gradual fall of potential
into the bulk of the liquid where the charge
distribution is not uniform.

DLVO theory
• Theory is explained by Derjaguin, Landau, Verway, Overbeek
So it is known as DLVO Theory. According to this theory ,The
forces on colloidal particles in a dispersion medium are due to
its total potential energy function VT.
VT = VA + VR
VR = Electrostatic Repulsion
VA= London type Vander Waals Attraction

DLVO theory
• DLVO theory suggests that the stability of a colloidal system is determined by the
sum of these van der Waals attractive (VA) and electrical double layer repulsive
(VR) forces that exist between particles as they approach each other due to the
Brownian motion they are undergoing.
• This theory proposes that an energy barrier resulting from the repulsive force
prevents two particles approaching one another and adhering together. But if the
particles collide with sufficient energy to overcome that barrier, the attractive force
will pull them into contact where they adhere strongly and irreversibly together.
• Therefore, if the particles have a sufficiently high repulsion, the dispersion will
resist flocculation and the colloidal system will be stable. However, if a repulsion
mechanism does not exist then flocculation or coagulation will eventually take
place

DLVO theory

Thanks