Advanced Oral Dosage Formulation Approaches PDF

Summary

This document discusses different approaches to oral drug delivery, focusing on modified release systems. It covers the principles, advantages, and challenges of controlled-release formulations. The document also includes content about polymers and their applications in drug delivery.

Full Transcript

Advanced Oral Dosage Formulation Approaches:
Solid oral dosage form design:
An ideal drug delivery system delivers the correct amount of drug to the site of action a the correct rate to maximise
the therapeutic response and minimise side effects
Modified release design:
Objective = modulate the rate of drug input in the intestinal tract to achieve a predefined plasma profile
Includes
- Delayed release
- Sustained release
- Programmed release
- Site specific/timed release
Modified Release Drug Delivery:
The manipulation/modification of drug release from a dosage form with the aim of delivering the API at desired
rates, predefined time points or at specific sites in the GIT
Advantages:
- Can control the rate and site of drug release to reach clinical objectives that otherwise cannot be achieved
- Offers sustained blood levels, improved efficacy and optimised performance
- Can help to reduce side effects
- Allows local treatment of GIT disorders
- More convenient, better patient compliance (Chronotherapy)
- Protects acid sensitive drugs from the harsh stomach environment
- Can design bimodal release drugs – part released immediately and part delayed or extended
Drug properties that influence MR dosage forms:
Solubility
- Good solubility allows for many formulation options
- Very low solubility drugs are inherently sustained release due to their slow dissolution
Permeability
- Drug must be sufficiently permeable (lipophilic – logP 1-5) to provide absorption rate faster than release
from dosage form
Transport mechanism
- Drugs absorbed via carrier mediated transport have too narrow an absorption window to allow delivery of
12-24hrs worth of medication in one administration
- Most carriers only act in one specific portion of the gut – the drug won’t be there for long enough
Dose
- Daily dose must not be too large to swallow (usually 500mg-1g)
Enzymatic inactivation
- If drugs are inactivated by enzymes faster than they are released then the presystemic drug loss will be mch
higher
- If absorbed from the colon, extended release formulations can increase bioavailability – some enzymes (e.g.
CYP3A4) are missing from the colon, so the drug is not degraded as much
Types of Modified Release:
1. Delayed Release:
- Drug is released at a time later than immediately after administration
- Lag time between taking the medicine and the drug being detectable in the blood
- The dosage from dissolves somewhere after the stomach – disintegrate rapidly once the desired area of the
GIT has been reached
- A membrane is designed to disintegrate or dissolve at a predetermined point
o Most common trigger is pH
- Most commonly release drugs in the small intestine but can also be used for colonic drug delivery
Problems:
- Gastrointestinal pH is not always predictable and reproducible in vivo
- Some patients have higher than normal stomach pH – risk of early release
- IBD patients have delayed gastric transit time – enteric release drug not released quickly enough – use IR
Polymers:
- Number of polymers used that dissolve at different pH ranges – polymer characteristics and mechanism of
drug release control rate of release
- Anionic polymethacrylates, methacrylic acid copolymers are widely used
- Cellulose based polymers of PVAP are also used
- Polymer’s release profile is controlled by the pH-dependent solubility of the polymeric acid functional groups
Enteric Coating:
- Gastro-resistant acidic polymer coatings which are insoluble at low pH but soluble at higher pH (5-7)
- pH sensitive solubility enteric coating are the most common delayed release design
- Protect acid labile drugs from harsh stomach environment
- Protect the stomach from drugs that can irritate the stomach lining
Example:
Aspirin 75mg enteric coated tablets:
- Aspirin harms GI mucosa by its local and systemic effects, can lead to erosion, ulceration and bleeding
- Causes direct topical injury to the epithelium and systemic effects due to prostaglandin depletion
- To overcome this – aspirin is formulated with an enteric coating
- Methyacrylic acid-ethyl acrylate copolymer (1:1) – soluble above pH 5.5
Patient advice for taking enteric coated drugs:
- Do not crush or chew the tablet
- Swallow the tablet whole
- Do not take any antacids or other drugs that may alter the pH of the stomach with the drug
2. Extended Release:
- Formulated to make the drug available over an extended period
- Reduced dosing frequency by at least two-fold compared to IR dosage form
- More convenient
- More consistent plasma concentrations
- Fewer adverse reactions
- Can control release rate by controlling diffusion, dissolution or osmosis
Diffusion Controlled Release:
Reservoir Systems:
- Drug molecules are present in a drug reservoir that is surrounded by a polymeric membrane that the drugs
must diffuse through
- Diffusion through this membrane controls the rate of release
- The dissolution medium must penetrate the membrane into the reservoir to dissolve the drug
- The dissolved drug can then diffuse out of the dosage form and is released
- The rate of diffusion depends on the molecular size of the drug and the porosity of the polymer membrane
- Non-porous systems:
o Release follows Fick’s Law
o Factors that influence the diffusion coefficient include: viscosity, density, drug solubility (particle size,
crystal form), diffusion medium (wetting agents, fasted/fed state)
o For fast diffusion the membrane should be a thin stagnant layer with low viscosity
o Using polymeric and lipid based excipients can increase polymer viscosity
- Porous Systems:
o The size and dimension of the pores is related to the size of the pore-forming agent
o Release of frug involves transport of drug through porous pathways
o Must consider porosity and tortuosity of path
- Insoluble polymers (e.g. ethylcellulose) are semi-permeable and allow drug release independent of pH
Matrix Systems – hydrophobic:
- Drug substance is homogeneously dispersed with rate controlling material in a matrix system
- Drug release occurs either by diffusion or by erosion of the polymer
- Hydrophobic systems:
o Rate control by water-insoluble inert matrix – drug is embedded in an inert polymer
o Generally, water enters matrix, dissolves drug and dissolved drug diffuses out of matrix
 o Minimal swelling – stay intact throughout GIT , little change in dimension
o Travel through GIT undigested and are excreted in faeces
o Rate of release controlled by pore size, number of pores and tortuosity of the matrix
o Can add pore-forming agents to facilitate drug release
o More limited material options – materials should be biocompatible
▪ Fatty acids and their glycerol esters
▪ Wax-like materials
▪ Silicon ribber
▪ Insoluble polymers such as ethyl cellulose, Eudragit and cellulose esters
o Fast release:
▪ Low mw and low viscosity polymers
▪ Formulations with low % polymer
o Slow release:
▪ Viscous polymers
▪ High mw polymers, high degree of cross-linking
▪ Formulations with high % polymer
▪ Incorporation of release modifiers
o Release of drug decreases with time due to depletion of drug closest to surface of matrix – difficult
to achieve zero order release from matrix
- Example:
o Adizem-SR prolonged release capsules
o BD dosing ethylcellulose non-erodible polymer

Dissolution Controlled Release:
Hydrophobic reservoir systems also dissolution-controlled release – release is controlled by the erosion of the
polymer not by the permeation of the drug
Matrix Systems – Hydrophilic:
- Dissolution = dissolution of the polymer in the matrix, release of drug from degradable device
- Degradation either by
o Bioerosion: gradual dissolution of polymer by physiological fluids
o Biodegradation: breakdown of polymer by chemical or enzymatic processes
o Surface erosion: surface exposed to degradation medium is eroded, erosion works in layer-by-layer
o Bul erosion: entire polymer undergoes chemical/enzymatic erosion
- Hydrophilic systems:
o Rate controlling excipients are water-soluble, swellable polymers
o Polymer usually powder/granules and is manufactured by direct/roller compression into tablets
o Polymers available:
▪ Cellulose derivatives such as HPMC
▪ Synthetic polymers of varying degrees of cross-linking e.g. polyethylene oxide
▪ Natural polymers such as xanthan gum and alginate
o Viscosity and solubility of polymers relates to degree and type of substitution and molecular weight
of the polymer
o On exposure to fluid the polymer starts to swell producing a gel matrix which allows the drug to be
released through erosion or dissolution of the gel
- Widely used for extended delivery
o Can accommodate low and high drug concentrations
o Can accommodate drugs with wide range of physicochemical properties
o Cost-effective and generally easier to scale up
o Manufactured using conventional processes and equipment
- Mechanisms controlling release:
1. Hydration of polymer
2. Swelling behaviour of polymer influences
3. Diffusion as gel layer hydrates and forms
 4. Bioerosion of gel as dissolution proceeds
- Controlling release (Bioerosion)
o Must consider dissolution rate of polymer
o Degree of swelling (viscosity) of polymer
o Combining different polymers can create different release profiles
o Drug physicochemical properties need to be considered e.g. solubility
o Release profile can be influenced by processing/manufacturing factors e.g. granulation vs direct
compression
o Dissolution medium can influence rate of dissolution – pH, electrolytes
- Bioerosion polymers:
o Cellulose esters, HPMC,
- Biodegradation polymers:
o Natural polymers: chitosan, hyaluronic acid
▪ Mostly undergo enzymatic degradation, can cause immunogenic response, batch to batch
variability
o Synthetic polymers
▪ Mostly undergo chemical degradation, biologically inert, less variation, more predictable
kinetics
- Example:
o MacroBID – nitrofurantoin BD dosing – Carbopol and PVP
o Drug released in the intestine

Osmosis Controlled Release:
Osmosis = movement of water through a semi-permeable membrane from an area of high concentration to low
concentration
- Release is independent of pH and other physiological parameters
- Rate of drug release can be modified by changing viscosity of solution formed inside the system
- Osmotic pump system required sufficient exposure to water to build up osmotic pressure – dependent of
fluid volume in the gut
Osmotic Pump System:
- Drug is in water soluble tablet core that is coated with a semi-permeable membrane
- Membrane allows water in, water dissolves the components of the core and pressure builds which pumps
the drug solution out through a hole present in the coating
- The hole must be small enough to prevent diffusion but large enough to minimise hydrostatic pressure –
typically 0.6-1mm
- The hole/orifice can be made through laser drilling, indentation or use of leachable substances
Elementary osmotic pumps
- First used: drug core, semi-permeable membrane, laser drilled orifice
- If the drug gets stick in one part of GIT the high pressure and high drug concentrations can cause irritation
Controlled-porosity osmotic pumps
- Drug core surrounded by microporous membrane
- When exposed to water, micropores are created in the membrane, the drug is released at many different
points throughout the membrane
- Minimises side effects
Push-Pull osmotic pumps
- Same as elementary with an additional push layer
- Push layer is osmotically active and also causes a build up of osmotic pressure forcing the dtug out of the
orifice
- Same high pressure problem as elementary pumps
Formulation factors influencing release:
- Drug solubility
o Release rate is directly proportional to solubility of drug
o Highly soluble or poorly soluble drugs are not good candidates
 o May be necessary to modify the apparent solubility of the drug
- Osmotic pressure:
o Dependent on the number of molecules of solute in the solution
o Release is controlled by maintaining a constant osmotic pressure which is achieved by maintaining a
saturated solution in the core
o If there is not sufficient osmotic pressure, an osmagent can be added e.g. water soluble amino acids
- Delivery orifice:
o Too small – hydrostatic pressure may develop, deforming or bursting the device
o Too large – release is diffusion controlled not osmotic pressure controlled
- Coating membrane
o Release influenced by thickness of membrane
o Can influence the water permeability of the membrane to modify release
o Most common used polymer is cellulose acetate, other cellulose derivatives also used
Safety/Compliance:
- Avoid if there is pre-existing GI injury, resulting in GI narrowing
- Large dosage forms – may be difficult to swallow
- Patients should be warned about excretion of undigested capsule shells
- Not suitable for drugs with narrow absorption windows
- If the dosage form is too large it may be retained in the stomach
Example:
- Cardura XL
- Push-pull osmotic pump, once daily dosing

Sublingual Drug Delivery:
- Drug is placed under the tongue where it dissolves and is absorbed into blood stream – not intended to be
swallowed or chewed, should not be absorbed from GIT
Advantages:
- Avoids FPM, destruction by gastric juices or complexation with food
- Fast absorption and entry into systemic circulation
- Potency is predictable
- Administration is convenient, accessible, well accepted and the patient doesn’t need to be able to swallow
- Sublingual mucosa is more permeable than buccal mucosa
- Acceptable bioavailability of many drugs
Disadvantages:
- Cannot be used for controlled release – the area is constantly washed by a considerable amount of saliva
- Too difficult to get the device to stay in place
Requirements:
Drug should
- Be tasteless
- Dissolve rapidly
- Produce therapeutic effects with small amounts of drugs
Excipients:
- Increase rate of disintegration
- Enhance solubility (complexing agents)
- Enhance epithelium permeation (solvents, triglycerides)
- Taste masking agents, flavourings
Types of dosage forms:
- Tablets
- Sprays
- Drops
- Films
Example:
- Nitrolingual pump spray- GTN sublingual spray
Buccal Drug Delivery:
Administration of drug through the buccal mucosal membrane lining of the mouth
Advantages:
- Can be used for local and systemic delivery
- Good patient compliance – avoids discomfort and pain
- Better retention than sublingual – less saliva washing and smooth muscle is relatively immobile
- High accessibility, low enzymatic activity, rapid onset, low risk of toxicity
Disadvantages:
- Lack of dosage form retention – can be improved with bio-adhesive polymers
- Absorption lower and slower than sublingual
Types of dosage form:
- Tablets
- Patches
- Films
- Semi-solids
- Powders

Oro-dispersible Tablets:
Tablets that dissolve/disintegrate on contact with saliva but are absorbed later in the GIT
- Used mainly in paediatric and geriatric patients
- Superdisintegrants added to give burst of disintegration when in contact with saliva – drug is released in
mouth e.g. Crospovidone
- Disintegrates in just seconds
Advantages:
- Quicker absorption
- Potential increased bioavailability
- Easier administration – swallowing
Criteria for ODT:
- Low dose of API (