Targeted Drug Delivery Systems PDF

Summary

This document provides information about targeted drug delivery systems and covers topics such as liposomes, niosomes, nanoparticles, and monoclonal antibodies. It details the advantages, disadvantages, and applications of these systems.

Full Transcript

UNIT-4
TARGATED DRUG DELIVERY

Points to be covered in this topic
OINTRODUCTION
OAPPROACHES

’0ADVANTAGES

>ODISADVANTAGES

OLIPOSOMES

>ONIOSOMES

>ONANOPARTICLES

OMONOCLONAL ANTIBODIES
 TARGATED DRUG
DELIVERY
OINTRODUCTION:
In conventional drug delivery systems such as oral ingestion or
intravascular injection, The medication is distributed throughout the
body by means of systemicblood circulation.
For most therapeutic agents, only a small portion
of the medication reaches the affected organ or tissue,
Targeted drug delivery sue to deliver medication in the tissues of
interest while reducing the relative concentration of the medication
inthe remaining tissues.
For example, by avoiding the host's defence mechanisms and inhibiting
non-specific distribution in the liver and spleen, a system can reach the
intended site of action in higher concentrations.
Targeted delivery is believed to improve efficacy while reducing side
effects.

Targeted Drug Delivery System
Functdonalized Nanocarrlers Drug loaded Nanocarrlers

Targeted Cell

Drug Release

oj
o Potynes Gol Nanele Me

Dendrlme
Wonoprdes

ML

Nanoparticles /Nanocarriers
What is drug targeting?
The therapeutic response of adrug depends upon the interaction of drug
molecules with cell on cell membrane related biological events at
receptor sites in concentration dependent manner.
V Selective and effective localization of the pharmacologically-active moiety
at pre-identified target in therapeutic concentration,While restricting
its access to non-target normal cellular linings, Thus minimizing toxic
effects and maximizing the therapeutic index.
DAPPROACHES
The basic approaches for targeting the drug to specific site based
different research outcomes may be categorized broadly in to followings,
I. Controlling the distribution of drug by incorporating it in a carrier
system
II. Altering the structure of the drug at molecular level
III. Controlling the input of the drug into bioenvironment to ensure a
programmed anddesirable biodistribution
OADVANTAGES
" Drug administration protocols may be simplified.
Toxicity is reduced by delivering a drug to its target site, thereby reducing
harmful systemic effects.
Drug can be administered in a smaller dose to produce the desire effect.
Avoidance of hepatic first pass metabolism.
" Enhancement of the absorption of target molecules such as peptides and
particulates.
Dose is less compared to conventional drug delivery system.
" No peak and valley plasma concentration.
Selective targeting to infections cells that compare to normalcells.
ODISADVANTAGES
Rapid clearance of targeted systems.
Immune reactions against intravenous administered carrier systems.
Insufficient localization of targeted systems into tumour cells.
" Diffusion and redistribution of released drugs.
Requires highly sophisticated technology for the formulation.
Requires skill for manufacturing storage, administration.
Drug deposition at the target site may produce toxicity symptoms.
Difficult to maintain stability of dosage form. E.g.: Resealed erythrocytes
have to be storedat 4°C.

DLIPOSOMES
Liposome is derived from the Greek word, where lipo means "fatty"
constitution and soma means "structure". Liposome

Liposome are relatively small in size and it
Nutrient
ranges from 50nm to several micrometres in diameter. (Vitanin C)

These are spherical vesicle in which aqueous core is entirely
enclosed by one or more phospholipid bilayers.
It having the unique ability toentrap both lipophilic and hydrophilic
compounds.

The hydrophobic or

lipophilic molecules are
inserted into the bilayer
membrane,
Whereas hydrophilic
molecules can be entrapped Liposome Liposome
(hydrophobic load) (hydrophilic load)
in the aqueouscentre.
 Advantages:
Suitable for delivery of hydrophobic (e.g. amphoterícin B) hydrophilic
(e.g. cytrabine) and amphipathic agents.
Liposome increases efficacy and therapeutic indexof drug (actinomycin
D)
Liposome increase stability viaencapsulation
Suitable for targeted drug delivery
V Suitable to give localized action in particular tissue
Suitable to administer via various routes

Liposomes help to reduce the exposure of sensitive tissue to toxic drug.
Disadvantages:
Once administrated, liposome cannot be removed.
Possibility of dumping, due to faulty administration.
Leakage of encapsulated drug during storage.
Low solubility
/ Productioncost is high.
* Applications:
> Cancer chemotherapy:
Liposome are successfully used to entrap anticancer drugs.
Thisincreases circulation life time, protect from metabolic degradation.
º Liposome as carrier of drug in oral treatment:
Steroids used for arthritis can be incorporated into large MLVs.
Alteration in blood glucose levels in diabetic animals was obtained by
oral administration ofliposome encapsulated insulin.
Liposome for topical application:
Drug like triamcinolone, methotrexate, benzocaine, corticosteroids etc.
Can be successfullyincorporated as topical liposome.
º Liposome for pulmonary delivery:
V Inhalation devises like nebulizers are used to produce an aerosol of
droplets containingliposome.
ONIOSOMES
Niosomes areone of the novel drug delivery system of encapsulating the
meicament in a vesicular system.
The vesicle composed of a bilayer of non-ionic surfactants and hence
the name niosomes.
Non aqucous,
The niosomes are very small. surfactant
non-ionic bilayer
and microscopic in size (in
nanometric scale).
Although being structurally
similar to liposomes, they Aqueous
Compartment
have several advantages over
them. Structure of Niosome

Hydrophilc drug
Hydrophob1c drug
Amptiphiic drug

Advantages:
The vesicles may act as a depot, releasing the drug in a controlled
manner,

They are osmotically active and stable,
They improve the therapeutic perfornnance of the drug molecules by
delayed clearance from the circulation,
Protecting the drug from biological environment,
 They improveoral bioavailability of poorlyabsorbed drugs.
Niosomal dispersion in an aqueous phase can be emulsified in a non
aqueous phase to regulate the delivery rate of drug and administer normal
vesicle in external non-aqueous phase.

* Disadvantages
V Physical instability of the noisome vesicles is major disadvantage of the
noisome drug delivery system.
Aggregation: Aggregation of the noisome vesicles can be another
disadvantage to be considered.
Fusion: Fusion of the niosomal vesicles to form loose aggregates
Leaking of entrapped drug: affect the intended properties of the
niosomnes.

Hydrolysis of encapsulated drugs which limiting the shelf life of the
dispersion.
* Applications
Anti-neoplastic Treatment:
Niosomes can alter the metabolism, prolong circulation and half-life of the
drug, thus decreasing the side effects of the drugs.
Use in Studying Immune Response:
/ Due to their immunological selectivity, low toxicity and greater stability.
Niosomes as Carriers for Haemoglobin:
The niosomal vesicle is permeable to oxygen and hence can act as a
carrier for haemoglobin in anaemic patients.
 ONANOPARTICLES
Asite specific drug delivery system consisting of poly metacryclic
nanoparticles.
" The main goal in designing nanoparticles as a delivery system is to
control size of particle, surface characteristics and discharge of
pharmacologically active agents.
" In order to achieve the site-specific
action of the drug at the

therapeutically optimal rate and
dose regimen.
Advantages:
Increases the stability of any volatile pharmaceutical agents.
They offer a significant improvement over traditional oral and
intravenous methods of administration in terms of efficiency and
effectiveness.
Delivers a higher concentration of pharmaceutical agent.
The choice of polymer and the ability to modify drug release from
polymeric nanoparticles have made them ideal candidates for cancer
therapy, delivery of vaccines, contraceptives and delivery of targeted
antibiotics.

Disadvantages:
Smallsize &large surface area can lead to particle aggregation.
V Physical handling of nano particles is difficult in liquid and dry forms.
Limited drug loading.
V Toxicmetabolites may form. Etc.
 Application
Internalization: Internalization within mammalian cells can be achieved
by surface functionalized carbon nanotubes
Vaccine delivery: Conjugation with peptides may be used as vaccine
delivery structures.
º Gene delivery: carbon nanotubes has been modelled in such a way so
that they can be convenienty utilized as small molecule transporters in
transporting DNA, indicatingpotential use as a gene delivery tool.
> Transport of peptides, nucleic acids and other drug molecules
Incorporation of carboxylic or ammonium groups to carbon nanotubes
enhances their solubility.
> Cancer therapy: This technology is being evaluated for cancer therapy.
> Diagnostic purposes: Inwhole blood immunoassays e.g. coupling of gold
nanoshells to antibodies to detect immunoglobulins in plasma and whole
blood. etc.
DMONOCLONAL ANTIBODIES
An antibody is a protein used by immun
system to identify and neutralize foreign
objects like bacteria and viruses.
Each antibody recognizes a specific antigen
unique to its target.
The high specificity of antibodies makes them an excellent tool for
detecting andquantifying a broad array of targets, from drugs to serum
proteins to microorganisms.
With in-vitro assays, antibodies can be used to precipitate soluble
antigens, agglutinate (clump) cells,opsonize.
 How monoclonal antibodies work
Kill bacteria with
the assistance of
complement,
and neutralize

drugs,
and viruses.
toxins,
Y
Monoclonal antibodies once attached,
bind to their target they make it harmiess

Advantages
Though expensive, monoclonal antibodies are cheaper to develop than
conventional drugs because it is based on tested technology.
Side effects can be treated and reduced by using mice-human hybrid cells
or by using fractions of antibodies.
They bind tospecific diseased or damaged cells needing trea
They treat a wide range of conditions.

Disadvantages
Time consuming project - anywhere between 6 -9 months.
Very expensive and needs considerable effort to produce them.
Small peptide and fragment antigens may not be good antigens
monoclonal antibody may not recognize the original antigen.
Hybridoma culture may be subject to contamination.
VSystem is only well developed for limited animal and not for other
animals.

More than 99% of the cells do not survive during the fusion process
reducing the range of useful antibodies that can be produced against a..
antigen
Itis possibility of generatingimmunogenicity
* Application
º DiagnosticApplications:
Monoclonal antibodies have revolutionized the laboratory diagnosis of
various diseases.
For this purpose, MAbs may be employed as diagnostic reagents for
biochemical analysis or as tools for diagnostic imaging of diseases.
(A) MAbs in Biochemical Analysis:
/ Diagnostictests based on the use of MAbsas reagentsare routinely used
in radioimmunoassay (RIA) and enzyme-linked immunosorbent assays
(ELISA) in the laboratory.
V These assays measure the circulating concentrations of hormones
(insulin, human chorionic gonadotropin, growth hormone, progesterone,
thyroxine, triiodothyronine, thyroid stimulating hormone, gastr
renin),and several other tissue
(B) MAbs in Diagnostic Imaging:
Radiolabeled-MAbs are used in the diagnostic imaging of diseases, and
this technique is referred to as immunoscintigraphy.
The radioisotopes commonly used for labelling MAb are iodine-13
andtechnetium-99.
2. Therapeutic Applications:
(A) Cardiovascular diseases:
Myocardial infarction:
The cardiac protein myosin gets exposed wherever myocardial necros1s
(death of cardiac cells) occurs. Antimyosin MAb labelled wt..
radioisotope indium chloride (111 In) is used for detecting nyosin and
thus the site of myocardial infarction.
Imaging of radiolabeled MAb, is usually done after 24-48 hours of
intravenous administration.

Deep vein thrombosis (DVT):
DVT refers to the formation of blood clots (thrombus) within the blood
veins, primarily in the lower extremities.
For the detection of DVT, radioisotope labelled MAb directed against
fibrinor platelets can be used.
The imaging is usually done after 4 hours of injection. Fibrin specific
MAbs are successfully used for the detection of clots in thigh, pelvis, calf
and knee regions.