gastro retentive drug delivery system advantages and approaches
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Transcript of gastro retentive drug delivery system advantages and approaches
GASTRO RETENTIVE DRUG DELIVERY SYSTEM ADVANTAGES AND APPROACHESM.SRINIVASM.PHARMACY, II SEMISTER(PHARMACEUTICS)VAAGESWARI COLLEGE OF PHARMACY
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CONTENTS
•INTRODUCTION•APPROPRIATE CANDIDATE DRUGS FOR
GRDDS•ADVANTAGES•LIMITATIONS•APPROACHES•CONCLUSION•REFERENCES
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INTRODUCTION•Oral drug delivery is widely used in
pharmaceutical field to treat the diseases.•Some drugs are absorbed at specific site
only ,these require release at that specific site.
•Gastro retentive drug delivery(GRDDS) is one of the site specific drug delivery for the delivery of the drugs at stomach.
•It is obtained by retaining dosage form into stomach and drug is being released at controlled manner at specific site
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APPROPRIATE CANDIDATE DRUGS FOR GRDDS• Drugs acting locally in the stomach. E.g. Antacids and drugs for H. Pylori viz.,
Misoprostol.• Drugs that are primarily absorbed in the
stomach. E.g. Amoxicillin• Drugs that is poorly soluble at alkaline pH. E.g. Furosamide, Diazepam, Verapamil, etc.• Drugs with a narrow absorption window. E.g. Cyclosporine, , Levodopa, Methotrexate
etc.
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•Drugs which are absorbed rapidly from the GI tract.
E.g. Metronidazole, tetracycline.•Drugs that degrade in the colon. E.g. Ranitidine, Metformin.•Drugs that disturb normal colonic
microbes E.g. antibiotics against Helicobacter
pylori.
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ADVANTAGES
•Enhanced bioavailability•Sustained drug delivery/reduced frequency
of Dosing•Targeted therapy for local ailments in the
upper GIT•Reduced fluctuations of drug concentration•Improved selectivity in receptor activation•Reduced counter-activity of the body
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ADVANTAGES
•Extended effective concentration.•Minimized adverse activity at the colon.
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LIMITATIONS
•The drug substances that are unstable in the acidic environment of the stomach are not suitable candidates to be incorporated in the systems.
•These systems require a high level of fluid in the stomach for drug delivery to float and work efficiently.
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•Not suitable for drugs that have solubility or stability problem in GIT.
•Drugs which are irritant to gastric mucosa are also not suitable.
•These systems do not offer significant advantages over the conventional dosage forms for drugs, which are absorbed throughout GIT.
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APPROACHES FOR PROLONGING THE GASTRIC RESIDENCE TIME
• High-density systems.
(HDS)
• Floating systems. (FS)
• Swelling and
expanding systems.
(SS)
• Mucoadhesive &
Bioadhesive systems.
(AS)
FS
HDS
A S
SS
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CLASSIFICATIONCLASSIFICATION11
HIGH DENSITY SYSTEM• Gastric contents have a density close to water
( 1.004 g cm−3). When the patient take high-density pellets , they sink to the bottom of the stomach where they become entrapped in the folds of the antrum and withstand the peristaltic waves of the stomach wall.
• A density close to 2.5 g cm−3 seems necessary for significant prolongation of gastric residence time.
• Barium sulphate , zinc oxide, iron powder, and titanium dioxide are examples for excipients used.
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FLOATING DRUG DELIVERY
These have a bulk density lower than the gastric content. They remain buoyant in the stomach for a prolonged period of time, with the potential for continuous release of drug. They Include:
Hydrodynamically balanced systems (HBS)Gas-generating systems Volatile liquid/ vacuum containing systemsRaft-forming systems Low-density systems
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GAS GENERATING SYSTEMS
• Carbonates or bicarbonates, which react with gastric acid or any other acid (e.g., citric or tartaric) present in the formulation to produce CO2 , are usually incorporated in the dosage form, thus reducing the density of the system and making it float on the media.
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MATRIX TABLETS
• Single layer matrix tablet is prepared by incorporating bicarbonates in matrix forming hydrocolloid gelling agent like HPMC, chitosin, alginate or other polymers and drug.
• Bilayer tablet can also be prepared by gas generating matrix in one layer and second layer with drug for its SR effect.
• Triple layer tablet also prepared having first swellable floating layer with bicarbonates, second sustained release layer of drug and third rapid dissolving layer of bismuth salt.
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INFLATABLE GASTROINTESTINAL DELIVERY • System is incorporated with an inflatable
chamber which contains liquid ether -gasifies at body temperature to cause the chamber to inflate in stomach.
• Inflatable chamber is loaded with a drug reservoir which can be a drug, impregnated polymeric then encapsulated
in a gelatin capsule.
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INTRAGASTRIC OSMOTICALLY CONTROLLED DDS Comprised of both an osmotic pressure controlled
drug delivery device and an inflatable floating support in a biodegradable capsule.
In stomach, the capsule quickly disintegrates and release the intragastric osmotically controlled drug delivery device .
Inflatable support forms a deformable hollow polymeric bag containing liquid that gasifies at body temperature to inflate the bag.
Consists of 2 compartments:• Drug reservoir • Osmotically active compartment.
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INTRA-GASTRIC FLOATING GASTROINTESTINAL DRUG DELIVERY SYSTEMS•System can be float by flotation chamber,
which may be vacuum or filled with air or a harmless gas
•Drug reservoir is encapsulated inside a microporous compartment
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HYDRODYNAMICALLY BALANCED SYSYTEMS
Prepared by incorporating a high level(20-75%w/w) gel-
forming hydrocolloids. E.g.:- Hydoxyethylcellulose,
hydroxypropylcellulose, HPMC & Sod. CMC into the
formulation and then compressing these granules into a
tablets or capsules.
It maintains the bulk density less than 1.
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RAFT FORMING
•This system is used for delivery of antacids and drug delivery for treatment of gastrointestinal infections and disorders.
•The mechanism involved in this system includes the formation of a viscous cohesive gel in contact with gastric fluids, forming a continuous layer called raft.
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HOLLOW MICROSPHERES
•Polymers used commonly: Polycarbonates, Cellulose acetate, Calcium alginate, Eudragit S, agar and methoxylated pectin etc.
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ALGINATE BEADS SUPERPOROUS HYDROGELS
• Prepared by dropping sodium alginate solution into aqueous solution of calcium chloride, causing the precipitation of calcium alginate
• Freeze dry in liquid nitrogen at -40oc for 24h.
• Beads-spherical and 2.5
mm in diameter.
• Swellable agents have pore size ranging between 10nm to 10µm.
• Superporous hydrogels will swell more than the swelling ratio 100,This is achieved by co-formulation of a hydrophilic particulate material, and Ac-Di-Sol (crosscarmellose).
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EXPANDABLE SYSTEMS1.UNFOLDED SYSTEMS 2.SWELLABLE SYSTEMS
The swelling is usually results from osmotic absorption of water.
The device gradually decreases in volume and rigidity as a result depletion of drug and expanding agent and/or bioerosion of polymer layer, enabling its elimination.
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MUCOADHESIVE SYSTEMS • The basis of mucoadhesion is that a dosage form can stick
to the mucosal surface by different mechanisms. • Examples for Materials commonly used for bioadhesion
are poly(acrylic acid) (Carbopol®, polycarbophil), chitosin, Gantrez® (Polymethyl vinyl ether/maleic anhydride copolymers), cholestyramine, tragacanth, sodium alginate
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MAGNETIC SYSTEM
•Based upon the principle that dosage form
contains a small internal magnet ,and a
magnet placed on the abdomen over the
position of stomach can enhance the GRT.
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Marketed Products of GRDDSBrand name Delivery system Drug (dose) Company
nameValrelease® Floating capsule Diazepam (15mg) Hoffmann-LaRoche,
USA
Madopar® HBS(Prolopa® HBS)
Floating, CR capsule Benserazide (25mg) and L-dopa (100mg)
Roche Products, USA
Liquid Gaviscon® Effervescent Floating liquid alginate preparations
Al hydroxide (95 mg), MgCarbonate (358 mg)
GlaxoSmithkline,India
Topalkan® Floating liquid alginatePreparation
Al – Mg antacid Pierre Fabre Drug,France
Conviron® Colloidal gel forming FDDS
Ferrous sulphate Ranbaxy, India
Cytotech® Bilayer floating capsule Misoprostol (100μg/200μg) Pharmacia, USA
Cifran OD® Gas-generating floating form
Ciprofloxacin (1gm) Ranbaxy, India
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CONCLUSION• Gastro retentive drug delivery systems have
emerged as a current approache of controlled delivery of drugs that exhibit an absorption window.
• All these drug delivery systems have their own advantages and drawbacks.
• To design a successful GRDDS, it is necessary to take into consideration the physicochemical properties of the drug, physiological events in the GIT, formulation strategies, and correct combination of drug and excipients.
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REFERENCE
•N K Jain. Gastroretentive drug delivery systems: Garima Chawla, Piyush Gupta and Aravind K. Bansal, editors. Progress in controlled and novel drug delivery systems.New delhi.
•S.P.vyas, roop K.khar controlled drug delivery concepts and advances page no.196-217.
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