WELCOME YOU ALL.

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Ocular Drug Delivery System
DEPARTMENT OF PHARMACEUTICS, NIPS

DEPARTMENT OF PHARMACEUTICS, NIPS
Introduction The eye is a unique and precious organ. It is considered as the window of the soul. There are many eye ailments which affect this organ and one can loss the eye sight also. Therefore many ophthalmic drug delivery systems are available. These are classified as conventional and newer drug delivery systems. Most commonly available ophthalmic preparations are eye drops and ointments, used topically rather systemically. DEPARTMENT OF PHARMACEUTICS, NIPS

These dosage forms are easy to instill but suffer from the inherent drawback that the majority of the medication is immediately diluted in the tear film as soon as the eye drop solution is instilled into the cul-de-sac (a short road which is closed off at one end). And is rapidly drained away from the precorneal cavity by constant tear flow and lacrimo-nasal drainage. Therefore, the target tissue absorbs a very small fraction of the instilled dose. DEPARTMENT OF PHARMACEUTICS, NIPS

Limitations of topical and intravitreal route of administration have challenged scientists to find alternative mode of administration like periocular routes. Transporter targeted drug delivery has generated a great deal of interest in the field because of its potential to overcome many barriers associated with current therapy. Application of nanotechnology has been very promising in the treatment of a gamut of diseases. Several ocular drug delivery systems such as microemulsions, nanosuspensions, nanoparticles, liposomes, niosomes, dendrimers, implants, and hydrogels are emerged as novel drug delivery systems for the eye. DEPARTMENT OF PHARMACEUTICS, NIPS

Human eye has a spherical shape with a diameter of 23mm cornea , lens , viterous body not have blood suply Oxygen and nutrients are supplied by aqueous humour Cornea is formed by criss crosing layer of collagen and bounded by elastic laminae cul-de-sac cavity DEPARTMENT OF PHARMACEUTICS, NIPS

Anatomy and Routes of Delivery of the eye
Drug delivery to the eye can be broadly classified into anterior and posterior segments: The wall of the human eye (globe) is composed of concentric layer; The outer fibrous layer. A middle vascular layer : Uvea tract - choroid, cilliary body, and iris. A nervous layer-the retina. The eye is constantly cleansed and lubricated by the lacrimal appartus 1. lacrimal gland 2. lacrimal canal 3. lacrimal sac 4. nasolacrimal duct Figure 1 : Structure of the eye COMPOSITION OF TEAR Water-98.2% Organic Protein0.67% Solids-1.8% element Sugar-0.65% Nacl-0.66% Urea-0.03% DEPARTMENT OF PHARMACEUTICS, NIPS

Figure 2: Routes of delivery of the eye DEPARTMENT OF PHARMACEUTICS, NIPS

Periocular route has been considered as the most promising and efficient route for administering drugs to posterior eye segment. Periocular refers to the region surrounding the eye. It is a broad term which includes peribulbar, posterior juxtascleral, retrobulbar, subtenon and subconjunctival routes (Fig 2). Intravitreal injections have gained considerable momentum during the past two decades. DEPARTMENT OF PHARMACEUTICS, NIPS

Various routes and dosage forms used: Topical Administration : solutions – eye drops, ointments, suspensions Intravitreal Injections : solutions, suspensions, implants SubTenon Injections : solutions, suspensions, implants Subconjunctival Injections : solutions, suspensions, implants DEPARTMENT OF PHARMACEUTICS, NIPS

SOLUTION SUSPENTION EMULSION OINTMENT INSERT GELS
CLASSIFICATION OF OCDDS SOLUTION SUSPENTION EMULSION OINTMENT INSERT GELS LIPOSOMES NIOSOMES DISCOMES CONVENTIONAL VESICULAR OCULAR DELIVERY SYSTEMS IMPLANTS IONTOPHORESIS DENDRIMER MICROEMULSION NANOSUSPENSION MICRONEEDLE MUCOADHESIVE POLYMERS CONTROL RELEASE PARTICULATE MICROPARTICLES NANOPARTICLES DEPARTMENT OF PHARMACEUTICS, NIPS

Eye Drops Eye ointments Eye Lotion Paper strips Ocuserts and Laciserts Hydro gel contact lenses Collagen shields Liposoomes Niosomes Discomes DEPARTMENT OF PHARMACEUTICS, NIPS

Drug Delivery to the Front of the Eye (Topical) Dose in the Eye Absorption via cornea into Aq. Humor Quick Loss Absorption via Conjunctiva Ocular tissues Drainage and removal by Naso-Lacrimal System, Blinking and tears Systemic Circulation DEPARTMENT OF PHARMACEUTICS, NIPS

Drug Delivery to Front and Back of the Eye DEPARTMENT OF PHARMACEUTICS, NIPS

Ocular Drug Design and Delivery: Challenges
For the therapeutic treatment of most ocular problems, topical administration is the preferred route. But it needs frequent dosing. For systemically administered drugs, only a very small fraction of the total dose reach the eye from the general circulatory system. Problems with Delivery of Drugs: Rapid drain out of the drug from the precorneal cavity by constant tear flow and lacrimo-nasal drainage. DEPARTMENT OF PHARMACEUTICS, NIPS

Blood-retinal barrier (BRB) prevents high concentrations of drugs passage from the blood stream. Most agents injected into the vitreous are cleared rapidly and are therefore ineffective. Effective dose often toxic. Subconjunctival and intravitreal injections carry a risk of infection. DEPARTMENT OF PHARMACEUTICS, NIPS

Enhancement in Bioavailability
Topical bioavailability can be improved by maximizing precorneal drug absorption and minimizing precorneal drug loss. 1. Viscosity improver: In order to prolong precorneal residence time and to improve bioavailability, attempts were made to increase the viscosity of the formulation. The viscosity enhancers used were hydrophilic polymers such as cellulose, polyalcohol and polyacrylic acid, Sodium carboxy methyl cellulose etc. DEPARTMENT OF PHARMACEUTICS, NIPS

2. Gels : Gel formation is an extreme case of viscosity enhancement through the use of viscosity enhancers. So the dosing frequency can be decreased to once a day. Cellulose acetate phthalate dispersion constituted a micro-reservoir system of high viscosity. 3. Penetration enhancers: They act by increasing corneal uptake by modifying the integrity of comeal epithelium. Chelating agents, preservatives, surfactants and bile salts were studied as possible penetration enhancers. But the effort was diminished due to the local toxicity associated with enhancers. DEPARTMENT OF PHARMACEUTICS, NIPS

4. Prodrugs: Prodrugs enhance corneal drug permeability through modification of the hydrophilic or lipophilicity of the drug. The method includes modification of chemical structure of the drug molecule, thus making it selective, site specific and a safe ocular drug delivery system. Drugs with increased penetrability through prodrug formulations are - epinehrine, phenylephrine, timolol, pilocarpine and albuterol. DEPARTMENT OF PHARMACEUTICS, NIPS

5. Cyclodextrins: Cyclodextrins act as carriers by keeping the hydrophobic drug molecules in solution and delivering them to the surface of the biological membrane, where the relatively lipophilic membrane has a much lower affinity for the hydrophilic cyclodextrin molecules. Optimum bioavailability can be achieved when just enough cyclodextrin (<15%) is added to the aqueous eye. DEPARTMENT OF PHARMACEUTICS, NIPS

6. Bioadhesive polymers: The bioadhesive polymers adhere to the mucin coat covering the conjunctiva and the corneal surfaces of the eye, thus prolonging the residence time of a drug in the conjunctival sac. These polymers can be neutral, synthetic or semi synthetic. Polyacrylic acid, polycarbophil and hyaluronic acid are commonly used synthetic polymers. DEPARTMENT OF PHARMACEUTICS, NIPS

NOVEL OCULAR DRUG DELIVERY SYSTEMS
One has to understand the physiological and biochemical factors involved in normal and pathological conditions for designing a successful ocular drug delivery system. An ideal therapy requires selectively targeting of active agent to various diseases like CNV (cytomegalovirus), diabetic retinopathy and solid tumors in the eye. Approaches made towards optimization of ocular delivery systems: 1) Improving ocular contact time (effective coating or adherence to corneal surface) 2) Enhancing corneal permeability (provide sustained and controlled drug delivery, overcome the side effects of pulsed dosing) 3) Enhancing site specificity (to prevent the loss to other ocular diseases, housing of delivery system in eye.) DEPARTMENT OF PHARMACEUTICS, NIPS

Microemulsions: Microemulsions are dispersions of water and oil facilitated by a combination of surfactant and co-surfactant in a manner to reduce interfacial tension. These systems are usually characterized by higher thermodynamic stability, small droplet size (100 nm) and clear appearance. An oil-in-water system consisting of pilocarpine using lecithin, propylene glycol, PEG 200 as surfactant/co-surfactants, and isopropyl myristate as the oil phase has been designed, which is non-irritating to the rabbit animal model. DEPARTMENT OF PHARMACEUTICS, NIPS

2. Nanosuspensions: This can be defined as sub-micron colloidal system which consists of poorly water soluble drug, suspended in an appropriate dispersion medium stabilized by surfactants. Nanosuspenisons usually consist of colloidal carriers like polymeric resins which are inert in nature. They help in enhancement of drug solubility and thus bioavailability. Unlike microemulsions, they are also popular because of their non irritant nature. DEPARTMENT OF PHARMACEUTICS, NIPS

3. Nanoparticles: “Nanoparticles are defined as particles with a diameter of less than 1 μm, comprising of various biodegradable or non biodegradable polymers, lipids, phospholipids or metals”. They can be classified as nanospheres or nanocapsules depending upon whether the drug has been uniformly dispersed or coated within polymeric material. Uptake and distribution of nanoparticles depend on the size of the nanoparticles. A solid lipid nanoparticulate system of tobramycin was developed for topical drug delivery. DEPARTMENT OF PHARMACEUTICS, NIPS

4. Liposomes: Liposomes are lipid vesicles containing aqueous core which have been widely exploited in ocular delivery for various drug molecules. Liposomes containing GCV (Ganciclovir) were formulated by a reversed phase evaporation method and in vivo pharmacokinetic evaluation was performed in a rabbit model. Ocular tissue distribution was higher in the sclera, cornea and vitreous humor from liposomal formulation. Acetazolamide was encapsulated in liposomal formulation for delivery via topical route. DEPARTMENT OF PHARMACEUTICS, NIPS

5. Niosomes: Niosomes are bilayered structural vesicles made up of non-ionic surfactant which are capable of encapsulating both lipophilic and hydrophilic compounds. In a recent approach to deliver cyclopentolate, niosomal formulation was developed. It released the drug independent of pH resulting in significant enhancement of ocular bioavailability A major advantage of this system was less systemic drainage because of the large size and large residence time in the cul-de-sac due to their disc shape. DEPARTMENT OF PHARMACEUTICS, NIPS

6. Dendrimers: “Dendrimers are macromolecular compounds made up of a series of branches around a central core. Their nanosize, ease of preparation, functionalization and possibility to attach multiple surface groups render them suitable alternative vehicle for ophthalmic drug delivery”. Major drawbacks associated with these systems are blurred vision and formation of a veil leading to vision loss. Dendrimers consisting of poly (amidoamine) (PAMAM) have been widely employed in drug delivery. DEPARTMENT OF PHARMACEUTICS, NIPS

7. Cyclodextrins: “Cyclodextrins (CDs) belong to a group of cyclic oligosaccharides capable of forming inclusion complexes with many guest molecules. Through CD complexation, aqueous solubility of hydrophobic drugs can be enhanced without changing their molecular structure and their intrinsic ability to permeate biological membranes”. These complexes have been proven to increase corneal permeation of drugs like dexamethasone, cyclosporine and so on. DEPARTMENT OF PHARMACEUTICS, NIPS

8. Contact Lenses: Traditionally used soaked contact lenses provide a drug release for a few hours. Current challenges in this mode of drug delivery are to sustain release for longer period and also to incorporate sufficient drug amounts in the lens matrix. Recently, surfactant loaded polyhydroxy ethyl methacrylate (p-HEMA) gel has shown sustained release of cyclosporine-A. The bioavailability of the formulation was found better than the topical eye drops. DEPARTMENT OF PHARMACEUTICS, NIPS

9. Intraocular Implants: Implants have been widely employed to extend the release in ocular fluids and tissues particularly in the posterior segment. Implants can be broadly classified into two categories based on their degradation property: (a) biodegradable and (b) non-biodegradable. With implants, the delivery rate could be modulated by varying polymer composition. Implants can be in the form of solid, semi-solid or particulate based delivery systems. DEPARTMENT OF PHARMACEUTICS, NIPS

10. Hydrogel Systems: The progress has been made in gel technology to the development of droppable gel. They are liquid upon instillation and undergo phase transition in the ocular cul-de-sac to form visco-elastic gel and this provides a response to environmental changes. Three methods have been employed to cause phase transition in the eye surface. These are change in pH, change in temperature and ion activation. DEPARTMENT OF PHARMACEUTICS, NIPS

pH: In this method gelling of the solution is triggered by a change in the pH. CAP latex cross linked polyacrylic acid and derivatives such as carbomers are used. They are low viscosity polymeric dispersion in water which undergoes spontaneous coagulation and gelation after instillation in the conjunctival cul-de-sac. Temperature: In this method gelling of the solution is triggered by change in the temperature. Sustained drug delivery can be achieved by the use of a polymer that changes from solution to gel at the temperature of the eye. III. Ionic strength: In this method gelling of the solution instilled is triggered by the change in the ionic strength. Example is Gelrite. Gelrite is a polysaccharide, low acetyl gellan gum, which forms a clear gel in the presence of mono or divalent cations. The concentration of sodium in human tears is 2.6 g/l is particularly suitable to cause gelation of the material when topically installed into the conjunctival sac. DEPARTMENT OF PHARMACEUTICS, NIPS

11. Iontophoresis: Ocular iontophoresis has gained significant interest recently due to its non-invasive nature of delivery to both anterior and posterior segment. It requires a mild electric current which is applied to enhance ionized drug penetration into tissue. This mode of delivery can overcome the potential side effects associated with intraocular injections and implants mentioned earlier. Examples of antibiotics successfully employed are gentamicin, tobramycin and ciprofloxacin by this system. DEPARTMENT OF PHARMACEUTICS, NIPS

12. Microneedle: Recently, researchers have attempted microneedle to deliver drug to posterior segment as an alternative to topical route. An evaluation of coated solid metal microneedle to deliver the drug was carried out both in-vitro and in-vivo. Microneedle had shown excellent in-vitro penetration into sclera and rapid dissolution of coating solution after insertion. In-vivo drug level was found to be significantly higher than the level observed following topical drug administration. This mode of drug delivery was also successful in the delivery of pilocarpine. DEPARTMENT OF PHARMACEUTICS, NIPS

13. Gene Delivery: Recently, various strategies have been adopted to deliver nucleic acids to a specific site within the eye. Designing delivery system for antisense ODNs (oligodeoxynucleotides), aptamers or siRNAs is a challenging task for researchers in ocular delivery field because of high molecular weight, size, surface charge, solubility of the active drug and intrinsic complexities associated with the structure of ocular tissues like retina and cornea. Recently, FDA has approved Vitravene®, an ODNs for the treatment of CMV in AIDS patients and Macugen® (pegaptanib sodium injection) which is an aptamer for the treatent of “wet” AMD. DEPARTMENT OF PHARMACEUTICS, NIPS

EVALUATION OF OCDDS 1. Thickness of film 2. Content uniformity 3. Uniformity of Weight 4. Percentage moisture absorption 5. Percentage moisture loss 6. In-vitro drug release 7. In-vivo drug release 8. Accelerated stability studies. DEPARTMENT OF PHARMACEUTICS, NIPS

Any Questions? DEPARTMENT OF PHARMACEUTICS, NIPS

The eyes are the mirror of the soul… Sight is the sense which is more valuable than all the rest Take care of your eyes with gentleness. DEPARTMENT OF PHARMACEUTICS, NIPS

RAGHAVENDRA KUMAR GUNDA
DEPARTMENT OF PHARMACEUTICS, NIPS

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