Pharmaceutical Dosage Forms-1 PDF

Summary

This document contains notes on pharmaceutical dosage forms, emphasizing disperse systems. It covers various types of dispersed systems based on particle size and provides examples. It also touches upon related topics like molecular dispersions, colloidal dispersions, and coarse dispersions.

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TEXT BOOKS:
 Martin's Physical Pharmacy and Pharmaceutical Sciences Classification of dispersed systems on the
:Physical Chemical and Biopharmaceutical Principles in the Pharmaceutical
Sciences by Martin, Alfred N. Sinko, Patrick J. basis of particle size:
 Aulton's Pharmaceutics : the Design and Manufacture of 1. Molecular dispersions
Medicines by Michael E. Aulton (Editor); Kevin M. G. Taylor
2. Colloidal dispersions
 Introduction to Pharmaceutical Dosage Forms “by
Howard Ansel” 3. Coarse dispersions.
 Pharmaceutical Calculations; The Pharmacist s
Handbook
 Pharmaceutical Dosage forms and Drug Delivery
Systems
 Pharmaceutical Dosage Forms; Disperse System
 Comprehensive Pharmacy Review
Disperse Systems
Pharmaceutical Dosage Forms-1
The term "Disperse System"
Course Title Course Lecture Practical Total Periodic Practical Final Oral Total Exam
code Exam Time refers to a system in which one
Pharmaceutical PT 303 2 1 3 20 40 75 15 150 2 substance (the dispersed phase)
Dosage Forms -
1 is distributed, in discrete units,
throughout a second substance
(the continuous phase or
1-colloids vehicle).
2-Suspensions Each phase can exist in solid,
liquid, or gaseous state.
3-Emulsions
 B- Colloidal dispersion (Sol): TABLE 1.
Classification of Dispersed Systems on the Basis of Particle Size
1- 1 mµ to 0.5 µ (I mµ to 500 mµ). Class Range of
Particle Size
Characteristics of System Examples
2- Particles are not resolved by ordinary microscope Molecular Less than 1.0 nm
1 nm (nanometer) = 10-9 m
1. Particles invisible in electron Oxygen molecules,
dispersion microscope ordinary ions,
although they may be detected under the 2. pass through ultra filter and glucose
ultramicroscope; visible in the electron microscope; semi permeable membrane;
3. undergo rapid diffusion.
3- Pass through filter paper but do not pass through Colloidal
dispersion
1 nm to 0.5 µm 1. Particles are not resolved by
ordinary microscope
Colloidal silver sols,
natural and synthetic
1µm (micrometer) = 10-6 m
semipermeable membrane; 2. they may be detected under polymers
the ultra-microscope
4-Particles made to settle by centrifugation 3. visible in the electron
microscope
5- Diffuse very slowly. 4. pass through filter paper but
do not pass semi permeable
membrane; diffuse very
slowly.
Example: colloidal silver sols, natural and synthetic Coarse Greater than 0.5 µm 1. Particles visible under micro- Grains of sand, most
polymers. Dispersion scope;
2. do not pass through normal
pharmaceutical
emulsions and
filter paper or dialyze through suspensions, red
semi permeable membrane blood cells
3. particles do not diffuse.
A- Molecular dispersions: C- Coarse dispersion:
1- Less than I mµ (nm). 1-Greater than 0.5 µ (500 mµ).
2- Particles invisible in electron microscope; 2-Particles visible under microscope
3-Pass through ultrafilter and semipermeable membrane. 3-Do not pass through normal filter paper or dialyze
4-Particles do not settle down on standing through semipermeable membrane
5- Undergo rapid diffusion. 4-Particles settle down under gravity
Examples; Oxygen molecules, ordinary ions, glucose
5-Particles do not diffuse.
Examples, grains of sand, red blood cells, most
pharmaceutical emulsions and suspensions.
 Size and shape of colloidal particles:
COLLOIDS Particles lying in the colloidal size range
The first colloids studied were gelatins and glues, possess a surface area that is enormous
and so Thomas Graham (British chemist often compared with the surface area of an equal
volume of large particles.
referred to as “The father of colloid chemistry)
used the Greek word kolla, meaning glue, as the Thus, a cube having a 1-cm edge and a volume
of 1 cm3 has a total surface area of 6 cm2.
root for his newly coined term.
If the same cube is subdivided into smaller
cubes each having an edge of 100 mμ, the
 Colloid is short synonym for colloidal system. total volume remains the same, but the total
 The heterogeneous biphasic system surface area increases to 600,000 cm2. This
represents a 105-fold increase in surface area.
 The color of colloidal dispersions is related to the size of the The shape of colloidal particles in dispersion is
particles present. Thus, the colour of finest gold sol is red.
Increasing the size of particles of gold, it becomes purple, important:
then colour becomes blue and finally the colour we observed  The more extended the particle the greater its
for gold is golden yellow.
specific surface the greater the attractive force
Antimony and arsenic trisulphides change from red to yellow
as the particle size is reduced from that of a coarse powder to between the particles of the dispersed phase
that within the colloidal size range. and the dispersion medium.
 Flow, sedimentation and osmotic pressure of
the colloidal system affected by the shape of
colloidal particles.
Shape of colloidal systems
The possession of a large specific surface area Many colloidal systems, including emulsions, liquid aerosols and
results in many of the unique properties of most dilute micellar solutions, contain spherical particles,
colloidal dispersions. Small deviations from sphericity are often treated using ellipsoidal
models.
For example: High molecular weight polymers and naturally occurring
Platinum is effective as a catalyst when in the macromolecules often form random coils in aqueous solution.
colloidal form as platinum black. This is Clay suspensions are examples of systems containing plate-like
particles
because catalyst acts by adsorbing the
reactants onto their surface.
Pharmaceutical Applications of Colloids:
I-Certain medicinal have been found to possess  Other synthetic polymers are applied as
unusual or increased therapeutic properties coating to solid dosage forms to protect drugs
when formulated in the colloidal state. that are susceptible to atmospheric moisture
 Colloidal silver chloride, silver iodide and silver or degradation under the acid condition of the
protein are effective germicides and donot cause stomach.
irritation that is characteristic of ionic silver salts.
 Coarsely powdered sulfur is poorly absorbed  Colloidal electrolytes (surface active agents)
when administered orally, yet the same dose of are sometimes used to increase the solubility,
colloidal sulfur may be absorbed so completely as stability and taste of certain compounds in
to cause a toxic reaction and even death. aqueous and oily pharmaceutical preparations.
 Colloidal copper has been used in treatment of
cancer, colloidal gold as a diagnostic agent for
paresis and colloidal mercury for syphilis.
II- Many natural and synthetic polymers are
 Particle shape may also influence the important in contemporary pharmaceutical
pharmacologic action. practice.
 Cromoglycic acid, an agent by inhalation to  Proteins are important natural colloids and are
control asthmatic attacks was found to be found in the body as components of muscle,
suitably deposited in the respiratory tract bone and skin.
when prepared as well formed rod-shaped  Naturally occurring plant macromolecules such
crystals as starch and cellulose that are used as
pharmaceutical adjuncts are capable of
existing in the colloidal state.
 Hydroxyethyl starch is a macromolecule used
as plasma substitute.
Types of Colloidal Systems:  Viscosity of the dispersion medium ordinarily is
Based on the nature of the interaction between the increased greatly by the presence of the dispersed
dispersion medium and the dispersed phase phase.
The dispersed phase of a colloidal dispersion may be  At sufficiently high concentrations, the sol may
classified as being either lyophilic (solvent-loving) or become a gel.
lyophobic (solvent-hating) and association.  Viscosity and gel formation are related to
 Lyophilic colloids solvation effect and to the shape of the molecules
which are usually highly asymmetric.
 Association (amphiphilic) colloids
 Dispersions are stable generally in presence of
 Lyophobic colloids
electrolytes. They may be salted out by high
If the solvent is water, these classifications are concentrations of very soluble electrolytes. Effect
termed as hydrophilic and hydrophobic, respectively. is due primarily to desolvation of lyophilic
molecules.
Absorption--- As colloidal dimensions are LYOPHILIC COLLOIDS
small enough, they have a huge surface area.  Dispersed phase consists generally of large
Hence, the drug constituted colloidal form is organic molecules lying with colloidal size
released in large amount. e.g- sulphur colloid range.
gives a large quantity of sulphur and this often
leads to sulphur toxicity  Molecules of the dispersed phase are solvated
i.e; they are associated with the molecules
Targeted Drug Delivery--- Liposomes are of comprising the dispersion medium.
colloidal dimensions and are preferentially
taken up by the liver and spleen.  Molecules dispersed spontaneously to form
colloidal solution.
 Viscosity of the system increases as the
LYOPHOBIC COLLOIDS:
concentration of the amphiphile increases as
micelles increase in number and become  Dispersed phase ordinarily consists of
asymmetric inorganic particles such as gold or silver.
 In aqueous solutions, the critical micelle  Little, if any, interaction (solvation) occurs
concentration is reduced by the addition of between particles and dispersion medium.
electrolyte. Salting out may occur at higher  Material does not disperse spontaneously and
salt concentrations special procedures therefore must be adopted
to produce colloidal dispersion.
ASSOCIATION (AMPHIPHILIC) COLLOIDS
 Dispersed phases consist of aggregates
(micelles) of small organic molecules or ions
whose size individually is below the colloidal
range.
 Hydrophilic or lipophilic portion of the
molecule is solvated, depending on whether
the dispersion medium is aqueous or
nonaqueous.
 Colloidal aggregates are formed spontaneously
when the concentration of amphiphile exceeds
the critical micelle concentration (cmc).
 Comparison of Properties of Colloidal Sols
Lyophilic Association (Amphiphillc) Lyophobic
Types of colloidal dispersion
Dispersed phase consists Dispersed phase consists Dispersed phase Colloids can be made from almost any
generally of large organic of aggregates (micelles) consists of inorganic
molecules lying within colloidal size
range.
of small
molecules or
organic particles such, as gold
or silver.
combination of gas, liquid, and solid. The
ions whose size
individually is below the
particles of which the colloid is made are
colloidal range,
Molecules of the dispersed Hydrophilic or lipophific Very little
called the dispersed material.
phase are solvated, i-e., they are portion of the molecule is
associated with the molecules
comprising the dispersion medium
solvated, depending on
whether, the dispersion
Colloids are classified on the basis of
medium is aqueous or
non-aqueous.
the dispersed phase and the dispersion
medium
Molecules disperse spontaneously Colloidal aggregates are Material does not
to form Colloidal solution formed spontaneously disperse,
when concentration of spontaneously, and,
amphiphlie exceeds the therefore, special
critical micelle procedures must be
concentration (c m c) adopted to produce
colloidal dispersion.
Lyophilic Association Lyophobic
(Amphiphillc)
Viscosity of the dispersion Viscosity of the system Viscosity, of the,
 Viscosity of the dispersion medium is not medium is increased greatly
by the presence of the
increases as the
concentration
dispersion medium
is not greatly
greatly increased by the presence of dispersed phase. At
sufficiently high
of the amphiphile
increases; as micelles
increased ,by the
presence of
hydrophobic colloidal particles which tend to concentrations, the sol may
becomes a gel. Viscosity and
increase in number. lyophobic colloidal
particles, which tend
be unsolvated and symmetric. gel formation are related to
solvation effects and to the
to, be unsolvated
and symmetrical.
shape of the molecules,
 Lyophobic dispersions are unstable in the which are usually highly
asymmetric.
presence of even small concentration of Dispersions are stable In aqueous solutions, Lyophobic
electrolytes. Effect is due to neutralization of generally in the presence of
electrolytes. They may be
CMC is reduced' by the
addition of electrolytes.
dispersions are
unstable in the
the charge on the particles. Lyophilic colloids salted out by high
concentrations of very
Salting-out may occur
at higher salt
presence of even
small
exert a protective effect. soluble electrolytes. The
effect is due primarily to de-
concentrations, concentrations of
electrolytes. Effect
salvation of Iyophilic is due to
molecules, neutralization of the
charge on the
particles.
Physical Properties of Colloids Colligative properties
Heterogeneous nature The properties of a solution are determined
Colloidal solutions are inherently by the number of solute particles present,
heterogeneous. It is made up of a dispersed regardless of the identity or nature of the
phase and a dispersion medium. solute particle, i.e., shape, size, charge, and so
Visibility on.
Colloidal particles are too small to be seen Colloidal particles are more substantial
with the naked eye, but when viewed through aggregates. In comparison to a true solution,
an ultramicroscope, they appear as dark spots the number of particles per unit volume in a
against a dark background due to light colloidal solution is small.
scattering caused by them.
Filterbility
Because the size of the solute particles is
smaller than the pores of the filter paper, they
pass through easily. Colloidal particles, on the
other hand, cannot pass through the animal
membrane, parchment paper, or ultrafilters.
Surface tension and Viscosity
Surface tension and viscosity of lyophobic sols
are similar to those of the dispersion medium.
Lyophilic sols, on the other hand, have higher
viscosity and lower surface tension than the
dispersion medium.
Preparation of Colloids
I- Lyophilic Colloids
The affinity of lyophilic colloids for the dispersion
medium leads to the spontaneous formation of
colloidal dispersion.
Lyophilic colloidal sols are usually obtained simply by
dissolving the material in the solvent being used.
For example, acacia, tragacanth, methylcellulose
and certain other cellulose derivatives disperse in
water.
This simple method of dispersion is a general one
for the formation of colloids. As with lyopliilic sols,
formation of association colloids is spontaneous,
provided that the concentration of the amphiphile in
solution exceeds the CMC.
Because colloidal particles are typically
associated, the number of particles in the II-Lyophobic colloids
solution decreases as a result of association, as In contrast to lyophilic colloids, it is necessary
does the colligative property. As a result, given to employ special methods to prepare
an equal concentration of the true solution and lyophobic colloids.
colloidal solution, the latter's colligative values These are
will be less than the former's. (a) Dispersion methods, in which coarse
particle are reduced in size.
(b) Condensation methods, in which materials
of subcolloidal dimensions are caused to
aggregate into particles lying within the
colloidal size range.
3-Colloid mill:
Chemical reaction
Milling and grinding processes may be used
although the efficiency is low. Colloidal silver iodide may be obtained by
So-called colloid mills, in which the material is reacting dilute solutions of silver nitrate and
sheared between two rapidly rotating plates set potassium iodide
close together, reduce only a small proportion
of the total particles to the colloidal size range. Colloidal sulphur is produced from sodium
thiosulphate and hydrochloric acid solutions
Colloidal hydrated ferric oxide is produced
from boiling ferric chloride with an excess of
water.
(a) Dispersion methods: (b) Condensation methods:
1-Ultrasonic generator: Change in solvent:
Dispersion may be achieved by the use of high, intensity
ultrasonic generators operating at frequencies in excess of The required conditions for the formation of
20,000 cycles per second. lyophobic colloids by condensation or
2-Electric arc: (Bridge‘s arc method) aggregation involve a high degree of initial
A second dispersion method involves the production of an supersaturation followed by the formation
electric arc within, a liquid. Owing to the intense heat
generated by the arc, some of the metal of the electrodes and growth of nuclei.
is dispersed as vapor, which condenses to form colloidal
particles. Supersaturation may be brought about by
change in solvent or reduction in temperature.
For example, if saturated solution of sulphur
in acetone is poured slowly into hot water, the
acetone vaporizes leaving a colloidal
dispersion of sulphur.
 The most important use of dialysis is the purification
At equilibrium, the colloidal material is retained in
compartment A, whereas the sub-colloidal material is of blood in artificial kidney machines.
distributed equally on both sides of the membrane.. Thus, ions and small molecules pass readily from
By continually removing the liquid in compartment-B, it is the blood, through a natural semipermeable
possible to obtain colloidal material in compartment-A which membrane, to the tissue fluids; the colloidal
is free from sub-colloidal contaminants components of the blood remain within the capillary
system.
Purification of colloidal dispersions
Because of their size, colloidal particles can be The process of dialysis may be hastened by:
separated from molecular particles with 1. Stirring:
relative ease. to maintain a high concentration gradient of diffusible
The technique of separation, known as molecules across the membrane and
dialysis, uses a semipermeable membrane of 2. By renewing the outer liquid from time to time.
collodion or cellophane, the pore size of which 3. Ultrafiltration: By applying pressure (or suction)
will prevent the passage of colloidal particles, the solvent and small particles may be forced across a
yet permit small molecules and ions, such as membrane but the larger colloidal particles are
retained.
urea, glucose, and sodium chloride, to pass
4.Electrodialysis: Movement of ions across the
through.
membrane can be speeded up by applying an
electric current through the electrodes induced in
the solution.
 1. Brownian motion ;
Properties of colloids: - is the random zigzag motion of particles that
A- Kinetic properties. can be seen under a microscope. The motion
is caused by the collision of molecules with
B- Optical properties.
colloid particles in the dispersing medium.
C- Electrical properties.
Electrodialysis is the applied potential between A) Kinetic properties
the metal screens supporting the membranes
speeds up the migration of small ions to the Several properties of colloidal systems that
membrane surface prior to their diffusion to the relate to the motion of particles with respect
outer liquid.
to the dispersion medium.
The motion may be thermally induced
(Brownian movement, diffusion, osmosis),
gravitationally induced (sedimentation), or
applied externally (viscosity).
Electrodialysis
 According to Fick's first law, the amount, dq, of
substance diffusing in time, dt, across a plane of
It is unaffected by the nature of the colliding area, S, is directly proportional to the change of
particles but is affected by their size and the concentration, dc, with distance traveled, dx.
viscosity of the solution.
The smaller the particle size, the lower the
viscosity and the faster the particle
movement. Where dq/dt is diffusion rate
Increasing the viscosity of dispersion medium D is the diffusion coefficient
decreases and then stop Brownian motion. S is the area of diffusion
At higher temperatures, the motion becomes dc/dx is the concentration gradient
more intense. The minus sign denotes that diffusion takes place in the
direction of decreasing concentration.
The Brownian movement was named after
Robert Brown, who first observed this type of
motion. 2. Diffusion:
The erratic motion, which may be observed Particles diffuse spontaneously from a region
with particles as large as about 5 μm of higher concentration to one of lower
The unbalanced bombardment of particles by concentration until the concentration of the
the molecules of the dispersion medium system is uniform throughout.
causes the Brownian movement. Diffusion is a direct result of Brownian
The Brownian movement has a stirring effect movement.
that keeps particles from settling and is thus
responsible for sol stability.
 Replacing c with cg/M in equation, in which cg is
At small particle size (less than 0.5 um) the grams of solute per liter of solution and M is
Brownian motion is significant & tend to the molecular weight, we obtain
prevent sedimentation due to gravity &
promote mixing in stead
The equation is valid for very dilute solutions in
so, we use an ultracentrifuge which provide which the molecules do not interact mutually.
stronger force so promote sedimentation in Osmotic pressure is inversely proportional to
a measurable manner. molecular weight; so that the pressures observed
for say, proteins of molecular weight 5000 will be
very low.
3. Sedimentation 4- Osmotic pressure:
The method is based on van't Hoff's law, according to
This is influenced by gravitational force, applicable for
which the osmotic pressure p depends on molar
particle size > 0.5 μm. concentration of the solute and on temperature. This
The velocity V of sedimentation of spherical particles is shown following equation, where:
is given by Π = CRT
Π = osmotic pressure
Stoke’s law; C = molarity = moles ÷ volume(L)
– V = 2r2 g ( ρ - ρo) / 9 ηo R = ideal gas constant
– v : velocity of sedimentation of spherical particles. T = temperature (K)
– r : the radius of particle
– ρ : density of the spherical particles.
– ρo : density of the medium.
– ηo: viscosity of the medium.
– g : acceleration due to gravity.
 B- Optical properties:
1- Light scattering (Tyndall effect):
When a beam of light passed through the colloidal
sol, the path of light is illuminated (a visible cone
formed) due to the scattering of the light by the
colloidal particles, this phenomenon is known as
Faraday- Tyndall effect.
Light scattering measurements are of great value for
estimating of Particle size, Shape and Molecular
weight of colloidal particles
5. Viscosity
Viscosity is an expression of the resistance to flow of
a system under an applied stress.
The more viscous a liquid is, the greater is the
applied force required to make it flow at a particular
rate.
The shapes of particles of the disperse phase affect
the viscosity of colloidal dispersions.
Spherocolloids form dispersions of relatively low
viscosity, whereas systems containing linear particles
are more viscous.
 For particles less than 0.1 m in diameter which are too
small to be truly resolved by the light microscope,
Electron Microscope
under the ultramicroscope, they look like stars in the
dark sky.
Their differences in size are indicated by differences in
brightness.
Electron microscope:
2- Ultramicroscope: - Ultra-microscope has declined in recent years as it
Colloidal particles are too small to be seen with an does not able to resolve lyophilic colloids.
optical microscope. - Electron microscope is capable of yielding pictures
Light scattering is made use of in the ultramicroscope of actual particles size, shape and structure of
first developed by Zsigmondy, in which cell colloidal particles.
containing the colloid is viewed against a dark
background at right angles to an intense beam of - Electron microscope has high resolving power, as its
incident light. radiation source is a beam of high energy electrons,
The particles, which exhibit Brownian motion, while that of optical microscope is visible light.
appear as spots of light against the dark background.
The ultramicroscope is used in the technicque of
microelectrophoresis for measuring particle charge.
Nernst and Zeta Potentials. The movement of a charged surface with
The potential at the solid surface, due to the potential- respect to the adjacent liquid phase is the basic
determining ion, is the electrothermodynamic (Nernst)
potential, E, principle underlying four electrokinetic
phenomena :
Nernst potential, is defined as the difference in potential
between the actual surface and the electroneutral region of
Electrophoresis
the solution. Electroosmosis
The potential located at the shear plane is known as the Sedimentation Potential
electrokinetic, or zeta, potential, ζ. Streaming Potential
The zeta potential is defined as the difference in potential
between the surface of the tightly bound layer (shear plane)
and the electroneutral region of the solution.
Electric Properties Of Colloids: Zeta potential has practical application in the
The particles of a colloidal solution are electrically stability of systems containing dispersed particles
charged and carry the same type of charge, either since this potential, rather than the Nernst potential,
negative or positive. governs the degree of repulsion between adjacent,
The colloidal particles therefore repel each other and similarly charged, dispersed particles. If the zeta
do not cluster together to settle down. The charge potential is reduced below a certain value (which
on colloidal particles arises because of the depends on the particular system being used), the
dissociation of the molecular electrolyte on the attractive forces exceeds the repulsive forces and the
surface. particles comes together. This phenomenon is known
as flocculation
 Electro-osmosis
Two main mechanisms for colloid
This is essentially the opposite of stabilization:
electrophoresis.
1-Steric stabilization i.e. surrounding each
In electro-osmosis, the dispersion medium particle with a protective solvent sheath
(either a liquid or a gas) moves under the which prevent adherence due to Brownian
influence of an electric field, while the movement
colloidal particles remain stationary.
2-electrostatic stabilization i.e. providing the
This phenomenon can be utilized to measure particles with electric charge
the zeta potential, a parameter related to the
stability and size of the particle.
Electrophoresis Stability of colloids
If an electric potential is applied to a colloid, Stabilization serves to prevent colloids from
the charged colloidal particles move toward aggregation.
the oppositely charged electrode. The presence and magnitude, or absence of a
This is known as electrophoresis and may be charge on a colloidal particle is an important
used to separate a mixture of colloidal factor in the stability of colloids.
substances such as proteins.
The charge of the particles can be determined
by observing the buildup near the electrodes.
If the particles are gathered near a positive
electrode, their charge is negative, and vice
versa.
 2- addition of less polar solvent
- e.g. alcohol, acetone
- Coagulation also result from mixing of
- The addition of less polar solvent renders the
oppositely charged colloids.
solvent mixture unfavourable for the colloids
B- Lyophilic sols and association colloids: solubility
- Stable ** Coacervation:
- Present as true solution Definition: the process of mixing negatively and
- Addition of moderate amounts of electrolytes positively charged hydrophilic colloids, and
not cause coagulation (opposite lyophobic) hence the particles separate from the
dispersion to form a layer rich in the colloidal
aggregates (coacervate)
A- Lyophobic sols: Salting out:
- Unstable. Definition: agglomeration and precipitation of lyophilic
- The particles stabilized only by the presence of colloids.
electrical charges on their surfaces through the This is obtained by:
addition of small amount of electrolytes. 1- Addition of large amounts of electrolytes
- The like charges produce repulsion which prevent - Anions arranged in a decreasing order of
coagulation of the particles and subsequent settling. precipitating power: citrate > tartrate > sulfate >
- Addition of electrolytes beyond necessary for acetate > chloride> nitrate > bromide > iodide
maximum stability results in accumulation of - The precipitation power is directly related to the
opposite ions and decrease zeta potential hydration of the ion and its ability to separate water
coagulation precipitation of colloids. molecules from colloidal particles
 The hydrophilic colloid shields the
hydrophobic system from the destabilizing
effects of electrolytes; thus the hydrophilic
substance is called a "protective colloid".
Stability of such a system is enhanced,
because in order to precipitate the
hydrophobic colloid, both the protective
solvent sheath surrounding it and the electric
charge must be removed.
Gelatin and methylcellulose derivatives are
commonly used as protective colloids.
Protection: When we need to remove colloids to from
The addition of large amount of hydrophilic dispersing media. This accomplished by:
colloid (protective colloid) to a hydrophobic
colloid tend to stabilize the system. Heating – increased molecular motion leads
The addition of a hydrophilic colloid to a to increased collisions and adhesion of
particles, leading to coagulation and settling.
hydrophobic one causes the hydrophilic
colloid to adsorb onto and completely Adding electrolytes – the colloid particle
charge is neutralized by the addition of
surround the hydrophobic particles which
soluble ionic compounds.
then take on some of the properties of the
Using semi-permeable membranes – ions pass
hydrophilic colloid.
through, particles do not. (dialysis)
n-gl.com