3. INTRODUCTION
o A virosome is a drug or vaccine delivery mechanism consisting of unilamellar
phospholipid vesicle incorporating virus derived proteins to allow the virosomes
to fuse with target cells.
o Virosomes are not able to replicate but are pure fusion active vesicles.
o These are reconstituted viral envelops that can serve as vaccines and as vesicles
for cellular delivery of macromolecules.
o Influenza virus is the most common virus of choice.
o The success of virosomal drug delivery depends on the methods used to
prepare the encapsulated bioactive materials and incorporate them into the
virosomes, as are characterization and formulation of finished preparation.
o Virosomes protect pharmaceutically active substance from proteolytic
degradation and low pH within endosomes, allowing their contents to remain
intact when they reach the cytoplasm
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4. o In contrast to liposomes, virosomes contain functional viral envelope
glycoproteins: influenza virus hemagglutinin (HA) and neuraminidase (NA) are
intercalated within the phospholipid bilayer membrane
oVirosomal Ultrastructure and Modifications:
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5. Fusion activity of virosomal carriers
o Virosomes has the unique properties of fusion because of the existence of influenza
HA in their membrane. HA is responsible for the structural stability and virosomal
formulation homogeneity, also significantly contributes to the fusion activity of
virosomes.
o Virosomal HA promotes binding at the target cell surface followed by receptor-
mediated endocytosis.
o The acidic environment of the endosome responsible for stimulation of HA-mediated
membrane fusion, and the therapeutically active substance escapes from the
endosome into the cytoplasm of the target cell.
o Thus, virosomal HA significantly enhances cytosolic delivery.
o This is a major advantage of virosomes over liposomes and proteoliposomal carrier
systems, which provide less protection for therapeutic macromolecules from
different compartmental unadoptable micro-environments.
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7. Advantages of Virosomal Drug Delivery
ļ¼ Virosomal technology is approved by the FDA for use in humans, and has a high
safety profile.
ļ¼Virosomes are biodegradable, biocompatible, and non-toxic.
ļ¼No disease-transmission risk.
ļ¼Patent protected.
ļ¼No autoimmunogenity or anaphylaxis.
ļ¼Broadly applicable with almost all important drugs (anticancer drugs, proteins,
peptides, nucleic acids, antibiotics, fungicides).
ļ¼ Enables drug delivery into the cytoplasm of target cell.
ļ¼ Promotes fusion activity in the endolysosomal pathway.
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8. ļ¼Protects drugs against degradation.
ļ¼ Encapsulation of drug protects patient against side effects.
ļ¼Target-specific delivery of antigens and amplification of the immune response.
ļ¼Extended uptake, distribution and elimination of the drug in the body.
ļ¼Virosomes allow patient specific modular vaccine regimen.
ļ¼Up-scaling according to standard procedure.
ļ¼The fully functional fusion-activity of virosomes enables receptor mediated
uptake and natural intracellular of the antigen, which leads to stimulation of
both arms of the immune system such as humoral and cellular immune
responses.
ļ¼ The antigen is partially protected from extracellular degradation and the
resulting depot effect greatly facilitates immune potentiation.
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9. Mode of action:
Virosomes operate both as a carrier and as an
adjuvant, with multiple functions for the duration of
initiation of an immune response.
The carrier function comprises the affirmative effects
of embedding the antigen into a privileged structure,
the virosome particle.
The adjuvant task relates to immune stimulating
properties of the virosomes and their components on
the immune system.
Most importantly, virosomes accomplish something
in stimulating specific immunity without causing
nonspecific inflammation.
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10. 4/24/2014 10
Carrier function:
The integration of the antigen into the higher structure of the virosome particle
stabilizes the antigen, preserves the native status of B cell epitopes, and protects
the antigen from degradation.
The antigen displayed on the virosomal surface mimics the original pathogen or
target cell and thereby favors the generation of antibodies relevant for protection.
Moreover, the presentation of the antigen as a repetitive surface structure
enhances its recognition by antibody-producing B cells.
Finally, the size and surface structure of the virosome particles make them an
attractive target for uptake and processing by immune cells, which is a crucial
step in the initiation of an immune response.
11. ADJUANT FUNCTION:
The adjuvant function of virosome relies on the presence of influenza derived
envelope proteins, in particular the predominant HA.
Pre-existing antibodies against influenza bind to virosome and tag them efficiently
for rapid uptake and processing by antigen presenting cells.
Also pre-existing influenza ā specific helper T cells are activated by those APC
displaying the processed fragments of the influenza proteins.
Activated helper cells rapidly proliferate and secrete cytokines to support and
enhance the induction of effect of immune cells.
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13. METHOD OF PREPARATION
1. Selection of virosomes:
Virosome are reconstituted viral envelope that can be derived from different virus.
Influenza virus envelope is the most commonly used to produce virosome but virosomes
can be made from Sendai virus, Epstein burr- virus, HIV, Sindbis, Semlikiforest, virus
Friend murine leukemia virus, herpes simplex virus.
2. Selection of antigen:
Antigen is selected as per requirement. Antigen such a parasite, carcinogenic cell,
bacterium or whole cell is used. As antigen such as cell component DNA, RNA or plasmid
can also used as antigen. This antigen is coupled to lipid anchor, so antigen will ready to
load on virosomes
3. Reconstitution of virosome:
Virosome solubilised with detergent (octaglucoside, triton x-100, nonidert p-40). Due to
solubilization with detergent, internal viral protein and genetic material will sediment.
Then detergent is removed by different method such as dialysis and hydrobhobic resins
from supernatant. 4/24/2014 13
14. Then using ultracentrifugation process viral matrix protein and nucleiocapsid is removed.
Viral phospholipid (82%) and viral protein is recovered. Now antigen which is already
coupled to lipid anchor is mixed with polymer or surfactant solution and this solution is
processed with virosome carrier so that antigen bound virosome is obtained.
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15. CHARACTERIZATION OF VIROSOMES
I. Protein detection : Virosome preparation should generally result in a relatively uniform
protein-to-lipid ratio. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-
PAGE) can confirm the presence of HA protein in the virosomes.
II. Structure and size : Negative-stain electron microscopy can generally be used to
determine the ultra structure and size of virosomes. The staining solutions should
preferably be of neutral pH, to avoid acid-induced conformational changes of HA.18
III. Fusion activity : Generally virosomes exhibit pH- dependent membrane fusion activity
similar to native influenza virus. Virosomal fusion with biological or artificial target
membranes can be assessed in vitro with an excimer assay using pyrene-labeled lipids,
where the decrease of surface density of the pyrene-phosphatidylcholine-label on fusion
with an unlabeled membrane corresponds to a reduction of excimer fluorescence.
Fusion activity also can be indirectly monitored by determining hemolytic activity, which
corresponds closely to fusion activity and exhibits pH dependence identical with that of
fusion.
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16. ā¢ Surface charge: free flow electrophoresis
ā¢ Electrical surface potential and surface pH: zeta potential measurements and pH
sensitive probes
ā¢ lamellarity: small angle x-ray scattering, freeze fracture electron microscopy, 13p-
nmr
ā¢ Phase behavior: freeze fracture electron microscopy, differential scanning
colorimetry
ā¢ Percent of free drug: mini column centrifugation, gel exclusion, ion exchange
chromatography, protamine aggregation, radiolabel ling
ā¢ Drug release: diffusion cell/ dialysis
ā¢ Pyrogenicity: rabbit fever response test or limulus ambeocyte lysate (lal) test
ā¢ Animal toxicity: monitoring survival rates, histology and pathology
ā¢ Chemical analysis of surface: static secondary ion mass spectrometry, spectrometer
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17. APPLICATIONS
1) Cancer treatment : Virosome have been also used in oncology field to carry
peptide corresponding to tumour associated antigen as in case of peptide
from parathyroid hormone related protein or from recombinant proteins such
as her -2 neu Fab combined the anti Fab ā doxovirosome combined the anti
proliferate properties of the monoclonal antibodies and cyototoxic effect of
doxorubicin in vivo.
2) Gene delivery : Haemagglutinin the membrane fusion protein of influenza virus
is known to mediate a low pH dependent fusion reaction between the viral
envelope and the limiting membrane of endosomal cell compartment following
cellular uptake of virus particle by receptor mediated endocytosis.
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18. 3) Virosomes associated with plasmid DNA, antisense oligonucleotides given
by IV,IM,IA,IT, topical and oral used in gene and antisense therapy desiring
high yield DNA incorporation, fusogenic (cationic,virosome,phsensitive),
and targeted.
4) Malaria therapy : Virosome represent an innovative drug delivery system
for various biologically active molecules, but especially nucleic acid or genes
and for numerous indications. The surface of virosomes can be suitably
modified to facilitate targeted drug delivery.
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19. General Applications:
ā¢ Blood substitutes for hemoglobin
ā¢ Immunoadjuvat, immunomodulator, immunodiagnosis
ā¢ Artificial blood surrogates
ā¢ Pharmaceutical pigments or dyes
ā¢ In tumor therapy a carrier of small cytotoxic molecules
ā¢ Vehicle for macromolecules as cytokines or genes
ā¢ As biological response modifiers
ā¢ Virosomal drugs
ā¢ Virosomes as drug/protein drug delivery vehicles
ā¢ As radiopharmaceutical and radio diagnosis carriers 4/24/2014 19
20. ā¢ As gene therapy genetic targeted intracellular material delivery
ā¢ Enzyme replacement therapy and lysosomal storage disorders.
ā¢ In cosmetics and dermatology
ā¢ Enhanced drug solubilization
ā¢ In antifungal (lung therapy), antiviral and anti microbial therapy
ā¢ Altered pharmacokinetics and biodistribution
ā¢ Masking action
ā¢ Drug overdose treatment
ā¢ Separation and extraction technique
ā¢ In fabrication of microcapsulated dosage form
ā¢ Enzyme immobilization 4/24/2014 20
21. MARKETED PRODUCTS
S. No. Virosomal preparations Application
A Virosomes antigen based products
1 1 Hepatitis A virus envelope proteins
(EpaxalW)
Hepatitis a
2 Influenza virus (InflexalW V) Influenza
B Virosomal antigen preparations
under clinical trials
1 Diphtheria/tetanus toxoid virus envelope proteins Diphtheria, Tetanus
2 Peptidomimetic of loop I from domain III of Plasmodium falciparum AMA-1 Malaria
3 PEV6 Breast cancer
C Virosomal antigen preparations under pre clinical trials
1 Doxorubicin Cancer
2 Doxorubicin Ovarian carcinoma
3 L-myc antisense ODNs Cancer
4 DNA-encoded TAA Prostate Carcinoma
5 DNA-encoded mumps antigen Mumps
6 Melan A/Mart-1 peptides Melanoma
7 RSV F protein RSV
8 Hepatitis C peptides Hepatitis C
9 VSV G protein Vesicular stomatitis
10 NDV envelope proteins Newcastle disease
11 HIV proteins AIDs
12 PEV4 RSV
13 PEV7 Candida
14 PEV 8 Universal influenza 4/24/2014 21
22. REFERENCES
ā¢ Sowmya G, Mandanapu C. Virosomal Drug Delivery System: A Novel Vaccination Technology.
American J PharmTech Res. 2013; 3(3): 35-54
ā¢ Rajat S, Mohd Y. Virosomes: A Novel Carrier for Drug Delivery. Int J PharmTech Res. 2010;
2(4): 2327-2339
ā¢ Kapoor D, Vyas RB, Lad C, Patel M. A multipurpose and novel carrier for drug delivery and
targetting - virosomes. J Drug Delivery & Therapeutics.2013; 3(5):143-147
ā¢ Sylvain Fleury. Virosomes: Enveloped VLP-based vaccines for eliciting mucosal response as
front line defense against HIV-1 and RSV entry and infection
ā¢ Christian Moser. Virosome technology. Pevion Biotech.
ā¢ Priyanka R, Gaurav S. Virosomes: A novel vaccination technology. Int J Ph Sci Res. 2012;
3(10): 3591-3597
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