Microencapsulation
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MICROENCAPSULATION TECHNIQUES
Ravindra Kumar Gupta M.Pharm, DIPR
Lecturer
B.R. Nahata College of Pharmacy , Mandsaur (M.P.)
Ravindra Kumar Gupta M.Pharm, DIPR
Lecturer
B.R. Nahata College of Pharmacy , Mandsaur (M.P.)
Microencapsulation is a process by which very tiny droplets or particles of
liquid or solid material are surrounded or coated with a continuous film of
polymeric material.
The product obtained by this process is called as micro particles,
microcapsules.
Particles having diameter between 3 - 800µm are known as micro particles or
microcapsules or microspheres.
Particles larger than 1000µm are known as Macroparticles .
INTRODUCTION
liquid or solid material are surrounded or coated with a continuous film of
polymeric material.
The product obtained by this process is called as micro particles,
microcapsules.
Particles having diameter between 3 - 800µm are known as micro particles or
microcapsules or microspheres.
Particles larger than 1000µm are known as Macroparticles .
INTRODUCTION
CLASSIFICATION OF MICROPARTICLE
Generally Micro particles consist of two components
a) Core material
b) Coat or wall or shell material.
1.Microcapsules: The active agent forms a core surrounded by an inert diffusion barrier.
2.Microspheres: The active agent is dispersed or dissolved in an inert polymer.
Generally Micro particles consist of two components
a) Core material
b) Coat or wall or shell material.
1.Microcapsules: The active agent forms a core surrounded by an inert diffusion barrier.
2.Microspheres: The active agent is dispersed or dissolved in an inert polymer.
ADVANTAGES:
To Increase of bioavailability
To alter the drug release
To improve the patient’s compliance
To produce a targeted drug delivery
To reduce the reactivity of the core in relation to the outside environment
To decrease evaporation rate of the core material.
To convert liquid to solid form & To mask the core taste.
To Increase of bioavailability
To alter the drug release
To improve the patient’s compliance
To produce a targeted drug delivery
To reduce the reactivity of the core in relation to the outside environment
To decrease evaporation rate of the core material.
To convert liquid to solid form & To mask the core taste.
FUNDAMENTAL CONSIDERATION :
Core material Coating material Vehicle
Solid Liquid
Microencapsulation
Polymers
Waxes
Aqueous Nonaqueous
Resins
Proteins
Polysaccharides
Core material Coating material Vehicle
Solid Liquid
Microencapsulation
Polymers
Waxes
Aqueous Nonaqueous
Resins
Proteins
Polysaccharides
ROLE OF POLYMERS :
Polymers are substances of high molecular weight made up by repeating
monomer units.
Polymer molecules may be linear or branched, and separate linear or
branched chains may be joined by crosslinks.
Polymers are used widely in pharmaceutical systems as adjuvants, coating
materials and, a components of controlled and site- specific drug delivery
systems
Polymers are substances of high molecular weight made up by repeating
monomer units.
Polymer molecules may be linear or branched, and separate linear or
branched chains may be joined by crosslinks.
Polymers are used widely in pharmaceutical systems as adjuvants, coating
materials and, a components of controlled and site- specific drug delivery
systems
MICROENCAPSULATION TECHNIQUES:
Air suspension techniques( Wurster)
Coacervation process
Spraydrying & congealing
Pan coating
Solvent evaporation
Polymerization
Extrusion
Single & double emulsion techniques
Supercritical fluid anti solvent method (SAS)
Nozzle vibration technology
Air suspension techniques( Wurster)
Coacervation process
Spraydrying & congealing
Pan coating
Solvent evaporation
Polymerization
Extrusion
Single & double emulsion techniques
Supercritical fluid anti solvent method (SAS)
Nozzle vibration technology
WURSTER PROCESS:
COACERVATION / PHASE SEPARATION
Polymeric
Membrane
Droplets
Homogeneous
Polymer Solution
Coacervate
Droplets
PHASE
SEPARATION
MEMBRANE
FORMATION
1.Formation of three immiscible phase
2.Deposition of coating
3.Rigidization of coating.
Polymeric
Membrane
Droplets
Homogeneous
Polymer Solution
Coacervate
Droplets
PHASE
SEPARATION
MEMBRANE
FORMATION
1.Formation of three immiscible phase
2.Deposition of coating
3.Rigidization of coating.
COMPLEX COACERVATION :
Polymer
+ Volatile organic solvent
Organic Polymeric Phase
Formation of Oil-in-Water
Emulsion
Solvent Evaporation
Particle Formation by
PolymerPrecipitation
RECOVERY OF POLYMERIC
MICROPARTICLES
Temperature increase
Active
Ingredient
Addition into an aqueous
phase (+o/w stabilizer)
SOLVENT EVAPORATIONS
Step 1:
Formation of a solution/dispersion of
the drug into an organic polymer
phase.
Step 2:
Emulsification of the
polymer phase into an aqueous phase
containing a suitable stabilizer, thus,
forming a o/w emulsion.
Step 3:
Removal of the organic
solvent from the dispersed phase by
extraction or evaporation leading to
polymer precipitation and formation
of the microspheres.
+ Volatile organic solvent
Organic Polymeric Phase
Formation of Oil-in-Water
Emulsion
Solvent Evaporation
Particle Formation by
PolymerPrecipitation
RECOVERY OF POLYMERIC
MICROPARTICLES
Temperature increase
Active
Ingredient
Addition into an aqueous
phase (+o/w stabilizer)
SOLVENT EVAPORATIONS
Step 1:
Formation of a solution/dispersion of
the drug into an organic polymer
phase.
Step 2:
Emulsification of the
polymer phase into an aqueous phase
containing a suitable stabilizer, thus,
forming a o/w emulsion.
Step 3:
Removal of the organic
solvent from the dispersed phase by
extraction or evaporation leading to
polymer precipitation and formation
of the microspheres.
SPRAY DRYING & CONGEALING ( COOLING)
Spray drying : spray = aqueous solution / Hot air
Spray congealing : spray = hot melt/cold air
Spray drying : spray = aqueous solution / Hot air
Spray congealing : spray = hot melt/cold air
Drug
Addition of the alcoholic solution
of the initiator (e.g., AIBN)
8 hrs Reaction time
Monomer(s) (e.g. acrylamide, methacrylic acid)
+ Cross-linker (e.g. methylenebisacrylamide)
Alcohol
T (reaction) = 60 °C
Nitrogen Atmosphere
Preparation of the
Polymerization Mixture
Initiation of
Polymerization
Monodisoerse Latex
Formation by Polymer
Precipitation
RECOVERY OF POLYMERIC
MICROPARTICLES
Monodisperse microgels in the micron or
submicron size range.
Precipitation polymerization starts from
a homogeneous monomer solution in
which the synthesized polymer is
insoluble.
The particle size of the resulting
microspheres depends on the
polymerization conditions, including the
monomer/co monomer composition, the
amount of initiator and the total
monomer concentration.
POLYMERIZATION:
Addition of the alcoholic solution
of the initiator (e.g., AIBN)
8 hrs Reaction time
Monomer(s) (e.g. acrylamide, methacrylic acid)
+ Cross-linker (e.g. methylenebisacrylamide)
Alcohol
T (reaction) = 60 °C
Nitrogen Atmosphere
Preparation of the
Polymerization Mixture
Initiation of
Polymerization
Monodisoerse Latex
Formation by Polymer
Precipitation
RECOVERY OF POLYMERIC
MICROPARTICLES
Monodisperse microgels in the micron or
submicron size range.
Precipitation polymerization starts from
a homogeneous monomer solution in
which the synthesized polymer is
insoluble.
The particle size of the resulting
microspheres depends on the
polymerization conditions, including the
monomer/co monomer composition, the
amount of initiator and the total
monomer concentration.
POLYMERIZATION:
EXTRUSION:
•This method was first patented in 1957.
•The advantage of extrusion is that it completely surrounds the core
material with wall material.
•The process involves forcing a core material dispersed in a molten
carbohydrate mass through a series of dies, into a bath of dehydrating
liquid.
•When contact with the liquid is made, the carbohydrate case hardens to
entrap the core material.
•The extruded filaments are separated from the liquid bath, dried using an
anti-caking agent such as calcium tripolyphosphate and sized .
•This process is particularly useful for heat labile substances such as
flavours, vitamin C and colours.
•This method was first patented in 1957.
•The advantage of extrusion is that it completely surrounds the core
material with wall material.
•The process involves forcing a core material dispersed in a molten
carbohydrate mass through a series of dies, into a bath of dehydrating
liquid.
•When contact with the liquid is made, the carbohydrate case hardens to
entrap the core material.
•The extruded filaments are separated from the liquid bath, dried using an
anti-caking agent such as calcium tripolyphosphate and sized .
•This process is particularly useful for heat labile substances such as
flavours, vitamin C and colours.
SINGLE EMULSION TECHNIQUE :
DOUBLE EMULSION TECHNIQUES :
NOZZLE VIBRATION TECHNOLOGY :
SAS METHOD :
APPLICATION OF MICROENCAPSULATION TECHNIQUES:
CONCLUSION:
•The microencapsulation technique offers a variety of opportunities such as
protection and masking, reduced dissolution rate, facilitation of handling,
and spatial targeting of the active ingredient.
This approach facilitates accurate delivery of small quantities of potent
drugs, reduced drug concentrations at sites other than the target organ or
tissue and protection of labile compounds before and after administration
and prior to appearance at the site of action.
• In future by combining various other approaches,microencapsulation
technique will find the vital place in novel drug delivery system.
•The microencapsulation technique offers a variety of opportunities such as
protection and masking, reduced dissolution rate, facilitation of handling,
and spatial targeting of the active ingredient.
This approach facilitates accurate delivery of small quantities of potent
drugs, reduced drug concentrations at sites other than the target organ or
tissue and protection of labile compounds before and after administration
and prior to appearance at the site of action.
• In future by combining various other approaches,microencapsulation
technique will find the vital place in novel drug delivery system.
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