nasal drug delivery
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What is “NASAL” Drug
Delivery system?
NASAL DRUG DELIVERY
INTRODUCTION:
Nasal drug delivery is receiving much attention from the pharmaceutical industry.
About 2% of the overall drug delivery is administered via the nasal route.
Topical decongestants or anti-inflammatory drugs used to treat a rhinitis or allergy related indications are well-known drug products.
The nasal route is an attractive alternative to invasive administrations, and provides a direct access to the systemic circulation.
MERITS OF NASAL DRUG DELIVERY SYSTEM: 1.A rapid onset of action is possible through nasal route, for the administration of systemically acting products. 2.Deposition of an active compound in the nasal cavity results in avoidance of its degradation through the ‘‘first-pass’’ metabolism.3.Avoids parentral administration 4.Rapid absorption, peaking generally within 15–30 minutes5.Apparent permeability to some peptides6.Ease of self-administration/good patient compliance7.lower doses and less side effects8.quicker onset of pharmacological activity .9.Rate of absorption comparable to IV medication.10.User-friendly, painless, non-invasive, needle-free administration mode.11.Useful for both local & systemic drug delivery.12.For CNS drugs, better site for rapid onset of action
Ex. Inhalation anesthesia, Morphine etc.
13.The nose is a very easy access point for medication delivery - even
easier to access than IM or IV sites.
DEMERITS OF NASAL DRUG DELIVERY SYSTEM:
1. Environmental conditions, infection, and inter-subject variability can lead
to inconsistent absorption.2. Short time span is available for absorption due to rapid clearance.3. Local metabolism in the nose and instability of compound (especially for
peptide drugs) occur.4. Once administered, removal of the therapeutic agent from the site of
absorption is difficult.5. The histological toxicity of absorption enhancers used in nasal drug delivery system
is not yet clearly established.6. Relatively inconvenient to patients when compared to oral delivery systems since
there is a possibility of nasal irritation.7. Nasal cavity provides smaller absorption surface area when compared to GIT.8. There is a risk of local side effects and irreversible damage of the cilia on the nasal
mucosa, both from the substance and from constituents added to the dosage form.9. Certain surfactants used as chemical enhancers may disrupt and even dissolve
membrane in high concentration.10.There could be a mechanical loss of the dosage form into the other parts of the
respiratory tract like lungs because of the improper technique of administration.
TRADITIONAL NASAL DISPENSING SYSTEMS
Traditional application systems consist of
1.Nasal drops, 2.Pipettes, 3.Squeeze bottles,4.Sprays
Nasal drops may be suitable for infants only.
In adults, drops into the nasal cavity mostly lead to a rapid clearance of the drug along the floor of the nasal cavity toward the throat.
Studies demonstrate a longer duration of sprayed products on the nasal mucosa than formulations administered as drops.
Compared to drops, sprays results in:Larger surface area of coverage.Smaller liquid particle size allowing thin layer to cover
mucosa.Less run-off out the nasal cavity.
SPRAY PUMP
DEVICES - Unidose- Multidose - Bidose
VARIOUS MULTIDOSE CONTAINERS THE UNIT-DOSE SYSTEM AND THE BI-DOSE SYSTEM
Nasal spray products contain therapeutically active ingredients (drug substances) dissolved or suspended in solutions or mixtures of excipients (e.g., preservatives, viscosity modifiers, emulsifiers, and buffering agents). These agents can be for local therapy (e.g., established treatments such as corticosteroids for rhinitis) or for systemic therapy [e.g., migraine therapies such as Imigran. Absorption of drugs from the nasal mucosa is also influenced by the contact time between drug and epithelial tissue.
(MAD)Mucosal Atomization Device
Atomization results in higher bioavailability than either spray or drops.
MAD - Mucosal Atomization device:
Device designed to allow emergency personnel to delivery nasal medications as an atomized spray.
Broad 30-micron spray ensure excellent mucosal coverage.
NASAL ANATOMY AND PHYSIOLOGY
The nose actively contributes to two major functions of the human system.
•The first function is the sense of smell (olfaction)
•The second is respiration or breathing. The nasal septum divides the nasal cavity into left and right halves.
The nasal septum is never a straight vertical separation of the two cavities.
The respiratory tract, which includes the
nasal mucosa hypopharynx large airways & small airways
provides a relatively large mucosal surface area for drug absorption.
The most efficient area for drug administration is the lateral walls of the nasal cavity, which consist of highly vascularized tissue, the mucosa.
1. The anterior one-third of the nasal cavity viewed in cross-section reveals a central septum dividing the two cavities. This region, including the proximal portion of the inferior and middle turbinates, is nonciliated . 2. In the posterior two-thirds of the nasal cavity, clearance of deposited particles occurs by slow spreading of the mucus layer into the ciliated regions along the inferior and middle meatuses, followed by a more rapid mucociliary clearance into the nasopharynx from where they are swallowed. 3. Approximately 1 L of mucus is transported from the anterior part to the posterior part of the nose per day. It takes approximately 20–30 min for the whole mucus layer to be renewed.
a – nasal vestibule d – middle turbinate
b – palate e – superior turbinate (olfactory mucosa)
c – inferior turbinate f – nasopharynx
Site of drug
spray &
absorption
POSSIBLE DRUG ABSORPTION PATHWAYSPOSSIBLE DRUG ABSORPTION PATHWAYS
Pathways for nasal
absorption
Absorption through the olfactory
neurons
- transneuronal absorption. Olfactory
epithelium is considered as a portal
for substances to enter CNS
Nose brain pathway
The olfactory mucosa (smelling area in nose) is in direct contact with the brain and CSF.
Medications absorbed across the olfactory mucosa directly enter the CSF.
This area is termed the nose brain pathway and offers a rapid, direct route for drug delivery to the brain.
Olfactory mucosa, nerve
Highly vascular nasal mucosa
BrainCSF
Lipophilicity
“Lipid Loving”
Cellular membranes are composed of layers of lipid material.
Drugs that are lipophilic are easily and rapidly absorbed across the mucous membranes. Blood stream
Cell Membrane
Non-lipophilic molecules
Lipophilic molecules
Absorption
through the
supporting cells
& the
surrounding
capillary bed
- venous
drainage
•Cytochrome P 450 dependent onooxygenases, Lactate dehydrogenase, Oxidoreductase, Hydrolases, Esterase, lactic dehydogenase, malic enzymes, lysosomal proteinases, steroid hydroxylases., etc.,
•Cytochrome P450 dependent mono oxygenases has been reported to catalyse the metabolism of xenobiotics, nasal decongestants, nocotine, cocaine, phenacetin, nitrosamine progesterone etc.,
•Insulin zinc free was hydrolysed slowly by leusine aminopeptidase,
•PG of E series was inactivated 15 hydroxyprostaglandin dehydrogenase
•Progesterone and testosterone were metabolized by several steroid hydroxylases in the nasal mucosa of rats
Nasal enzymes
•Nasal secretion of adult : 5.5-6.5
•Infants and children: 5-6.7
•It becomes alkaline in conditions such as acute rhinitis, acute sinusitis.
•Lysozyme in the nasal secretion helps as antibacterial and its activity is diminished in alkaline pH
Nasal pH
FormulationDevelopme
nt
Formulation Development
Dosage formDosage form
Formulation considerationsFormulation considerations
Factors affecting drug absorptionFactors affecting drug absorption
Physiological
Pharmaceutical
Dosage
forms
Liquid drop
Liquid spray/nebulizers
Suspension spray/nebulizers
Gel
Sustained release
Aerosol
Factors
affecting drug
absorption
Drug concentration
Vehicle of drug delivery
Mucosal contact time
pH of the absorption site
Size of the drug molecule
Relative lipid solubility
Degree of drug’s ionization
Physiological
effects
- Drug metabolism in the respiratory tract & reduction of systemic effect
- Mucociliary transport causing increased or decreased drug residence
time
- Protein binding
- Local or systemic effects of propellants, preservatives, or carriers
- Local toxic effects of the drug
Ex., edema, cell injury, or altered tissue defenses
1. Effect of particle size
2. Effect of molecular size
3. Effect of solution pH
5. Effect of drug concentration
4. Effect of drug lipophilicity
1. Effect of particle size
- Large particles (> 7 microns) will be lost in the gastrointestinal
tract
- Intermediate particles (3 to 7 microns) reach the actual site of
action
- Small particles (< 3 microns) will be lost in exhaled breathe
2. Effect of molecular size
- A good systemic bioavailability can be achieved for molecules with a
molecular weight of up to 1000 Daltons when no absorption enhancer
is used
- Higher the molecular size, lower the nasal absorption
3. Effect of solution pH
- Nasal absorption is pH dependent
- Absorption is lower as the pH increases beyond the dissociation constant
- Absorption is higher at a pH lower than the dissociation constant (pKa) of
the molecule
4. Effect of drug lipophilicity
- Polar (water soluble) drugs tend to remain on the tissues of the upper
airway
- Lipid soluble drugs are absorbed more rapidly than water soluble drugs
- Non-polar (lipid soluble) drugs are more likely to reach distal airways
5. Effect of drug concentration
- The absorption follows first-order kinetics
- Absorption depends on the initial concentration of the drug
For an effective administration of therapeutic drugs through the nasal mucosa, the following must be taken into consideration:
1.The method and technique of administration.2.The site of drug deposition3.Droplet size4.Spray characteristics5.The rate of clearance through the ciliary cavity 6.The pathological condition of the nose7.The speed of mucus flow8.The presence of infection and atmospheric conditions [e.g., relative humidity (RH)] will affect the efficacy of nasal absorption.
In Vivo Animal Models
1.Several animal models have been described for studying drug absorption through the nasal mucosa. 2.The most convenient model is the anesthesized rat model developed by Hirai et al. 3.For most non-peptide drugs, the results obtained in rats can accurately reflect the absorption profiles in humans. 4.Some experimental modifications are possible, with a similar surgical operation, and can be chosen for special purposes.
DETERMINATION OF NASAL ABSORPTION BY INVIVO METHODS:
RAT MODEL:
It has the following steps
1.Rat is anesthetised by IP injection of sodium pentobarbital.
2.Then an incision is made in the neck, the trachea is cannulated with a poly ethylene tube another tube is inserted through oesophagus towards the posterior part of the nasal cavity.
3.The passage of the nasopalatine tract is sealed surgically to prevent to prevent the drainage of drug solution from the nasal cavity in to the mouth. The drug solution is delivered to the nasal cavity through either nostril or the oesophageal tubing.
4.The blood samples are then collected from the femoral vein and analysed for absorbed drug.
RABBIT MODEL:
It has the following steps
1.A rabbit weighing 3 kg is anaesthetised by an IM injection of a combination of ketamine and xylazine.
2.The drug solution is delivered by nasal spray in to each nostril while the rabbits head is held in an upright position.
3.The rabbit is permitted to breath normally through nostrils and body temperature maintained at 37oC by a heating pad.
4.The blood samples are collected in the marginal ear vein. Ex: Progesterone and its hydroxyl derivatives.
In vivo–in situ model
1.Following the same surgical operation as in the in vivo model, the drug remaining in the nasal cavity can be recovered at a predetermined time and analyzed in this simple model.
2.This method is useful for evaluating both the absorption and the degradation of peptides.
3.Other than the rat & rabbit model, dogs, monkeys, and sheep are also used for in vivo studies.
4.In such large animals, the formulation can be administered while the animal is under anesthesia—or, in some cases, under conscious conditions—and care should be taken for physical loss of the formulation because of drainage.
Interspecies differences in nasal drug absorption
In Vitro Cell Culture Models
Various in vitro systems are currently available, which include the excised nasal epithelium from different animal species, primary cell cultures, and cell lines,of the human nasal epithelium.
Excised nasal mucosae from different animal species (rabbits, dogs, sheep, pigs, cattle, and humans) are used for studying nasal transport and metabolism.
An experimental set-up using an Ussing chamber is frequently used for evaluating the permeability of a drug through the excised mucosa.
Excised nasal mucosae
EXVIVO NASAL PERFUSION MODEL
1.During perfusion studies, a funnel is provided underneath the nose to lead the drug solution, which is flowing out of nasal cavity in the drug reservoir(37oC) and circulated through the nasal cavity of the rat by means of a peristaltic pump.
2.The perfusion solution passes out from the nostril and through the funnel and flows in to the drug reservoir solution again. Drug solutions of 3–20mL are continuously circulated through the nasal cavity of anesthesized rats.
3.The reservoir is stirred constantly and the amount of drug absorbed is determined by measuring the drug concentration remaining in the solution after a period of perfusion.
1.The obtained disappearance kinetics can be used for predicting the in vivo rate of drug absorption.
2.The method is also applicable to the assessment of the damaging effects of absorption enhancers on the nasal mucosa.
Applicatio
nsDelivery of non-peptide
pharmaceuticals
Delivery of diagnostic drugs
Delivery of peptide-based
pharmaceuticals
1. Delivery of non-peptide pharmaceuticals
Drugs with extensive pre-systemic metabolism, such as
1) Adrenal corticosteroids 2) Sex hormones: 17ß-estradiol, progesterone, no-rethindrone, and testosterone. 3) Vitamins: vitamin B 4) Cardiovascular drugs: hydralazine, Angiotensin II antagonist, nitroglycerine, isosobide dinitrate, propanolol, and colifilium tosylate. 5) Autonomic nervous system:
a. Sympathomimetics: Ephedrine, epinephrine, phenylephrine, b. Xylometazoline, dopamine and dobutamine. c. Parasympathomimetics: nicotine, metacholine d. Parasympatholytics: scopolamine, atropine, ipatropium e. Prostaglandins
can be rapidly absorbed through the nasal mucosa with a systemic
bioavailability of approximately 100%
2. Delivery of peptide-based
pharmaceuticals
Peptides & proteins have a generally low oral
bioavailability because of their physico-chemical
instability and susceptibility to hepato-
gastrointestinal first-pass elimination
Eg. Insulin, Calcitonin, Pituitary hormones etc.
Nasal route is proving to be the best route for
such biotechnological products
Basic concepts for achievingimproved nasal peptide andprotein delivery.
3. Delivery of diagnostic drugs
Diagnostic agents such as
Phenolsulfonphthalein – kidney function
Secretin – pancreatic disorders
Pentagastrin – secretory function of gastric
acid
Delivery of Vaccines through Nasal Route:
Nasal delivery of vaccines has been reported to not only produce systemic immune response, but also local immune response in the nasal lining, providing additional barrier of protection
Delivering the vaccine to the nasal cavity itself stimulates the production of local secretory IgA antibodies as well as IgG, providing an additional first line of defense, which helps to eliminate the pathogen before it becomes established
Recently, for the diseases like anthrax and influenza are treated by using the nasal vaccines prepared by using the recombinant Bacillus anthracis protective antigen (rPA) and chitosan respectively
Conclusions Multiple drugs can be given IN
Rapid Immediate access Can be given to almost anyone
○ Exception = Nasal mucosal abnormalities.
“Atomization” is the best method Cheap, easy to use device Disposable/single use (MAD) Appropriate drug concentrations
IN is a true “needleless” system! Reduce Level III bloodborne exposures
○ HIV○ Hepatitis B, C
REFERENCES:
1. Encyclopedia of pharmaceutical technology. 3rd Edition . Vol 1.
Page :1201 by JAMES SWARBRICK.
2. Text book of Novel Drug Delivery System by Chien, 2nd Edition.
3. Shaji J and Marathe S.W. NASAL DRUG DELIVERY SYSTEM:
OPPORTUNITIES & CHALLENGES INDIAN DRUGS Vol. 45 No. 5
May 2008 Pg no (345 – 353)
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