H. Oya Alpar

Mucosal or Parenteral Administration of Microsphere-Associated Bacillus anthracis Protective Antigen Protects against Anthrax Infection in Mice

ABSTRACT Existing licensed anthrax vaccines are administered parenterally and require multiple doses to induce protective immunity. This requires trained personnel and is not the optimum route for stimulating a mucosal immune response. Microencapsulation of vaccine antigens offers a number of advantages over traditional vaccine formulations, including stability without refrigeration and the potential for utilizing less invasive routes of administration. Recombinant protective antigen (rPA), the dominant antigen for protection against anthrax infection, was encapsulated in poly-l-lactide 100-kDa microspheres. Alternatively, rPA was loosely attached to the surfaces of microspheres by lyophilization. All of the microspheric formulations were administered to A/J mice with a two-dose schedule by either the intramuscular route, the intranasal route, or a combination of these two routes, and immunogenicity and protective efficacy were assessed. An intramuscular priming immunization followed by either an intramuscular or intranasal boost gave optimum anti-rPA immunoglobulin G titers. Despite differences in rPA-specific antibody titers, all immunized mice survived an injected challenge consisting of 103 median lethal doses of Bacillus anthracis STI spores. Immunization with microencapsulated and microsphere-associated formulations of rPA also protected against aerosol challenge with 30 median lethal doses of STI spores. These results show that rPA can be encapsulated and surface bound to polymeric microspheres without impairing its immunogenicity and also that mucosal or parenteral administration of microspheric formulations of rPA efficiently protects mice against both injected and aerosol challenges with B. anthracis spores. Microspheric formulations of rPA could represent the next generation of anthrax vaccines, which could require fewer doses because they are more potent, are less reactogenic than currently available human anthrax vaccines, and could be self-administered without injection.

Intra nasal administration of poly-lactic acid microsphere co-encapsulated Yersinia pestis subunits confers protection from pneumonic plague in the mouse

Equivocal doses of soluble, or high molecular weight poly (lactic acid) microsphere co-encapsulated, F1 and V subunit antigens of Yersinia pestis were used to immunize mice intra-nasally. Animals were dosed on day 1 and 7 with 2.724 micrograms V plus 0.956 micrograms F1. Co-encapsulated antigens induced superior systemic and mucosal immunity in comparison with free F1 and V. All of the mice immunized with soluble antigens died shortly after an aerosol challenge consisting of 1 x 10(5) colony-forming units of plague bacteria. In contrast, 66% of the co-encapsulated subunit vaccinees survived this lethal challenge. Humoral immunity to plague was improved further, resulting in 80% protection from challenge, if a relatively high dose (10 micrograms) of cholera toxin B subunit was added to the microsphere suspension prior to intra-nasal delivery. Significantly, by adding 10 micrograms cholera toxin B subunit to the free antigen solution, a 100% post-challenge survival rate was attained. We conclude that in this animal model of pneumonic plague, intra-nasal administration of microgram quantities of Yersinia pestis subunits confers protective immunity, provided the vaccines are microencapsulated or admixed with a strong mucosal adjuvant, such as the cholera toxin B subunit.

Analysis of local and systemic immunological responses after intra-tracheal, intra-nasal and intra-muscular administration of microsphere co-encapsulated Yersinia pestis sub-unit vaccines

Intra-tracheal, intra-nasal and intra-muscular immunisation with admixed Y. pestis sub-units (3 micrograms V, 0.47 microgram F1) or equivalent doses of poly-L-lactide microsphere co-encapsulated antigens was done. Systemic and mucosal responses to F1 and V differed according to immunisation route, and encapsulated status of the sub-units. Irrespective of immunisation site, particulated sub-units stimulated statistically superior primary systemic reactions, with intra-tracheal and nasal microsphere immunisations eliciting superior serum anti-V IgG titres in comparison to intra-muscular injection of free vaccines (p < 0.001 beyond day 8). Pulmonary and nasal delivery of microspheres induced primary serum anti-V IgG titres which were greater (p < 0.039) or equal to (p > 0.056) those after intra-muscular injection of spheres. In terms of serum anti-F1 titres, mice responded best to intra-muscular, and comparatively poorly to intra-nasal immunisations. Intra-tracheal administration of microspheres induced strongest responses in the respiratory tract, dominated by the IgG rather than IgA isotype. An intra-nasal booster immunisation on day 63 potentiated strong local and circulating anti-V IgG titres in microsphere vaccinees. Priming and boosting with free vaccines induced significantly depressed secondary serum anti-F1 titres relative to microsphere immunisations (p < 0.024 at days 78 and 120). In contrast to other priming sites, intra-tracheal instillation of encapsulated vaccines facilitated the induction of IgG antibody to both F1 and V in day 146 broncho-alveolal washings. With the exception of primary responses to F1 in mice immunised intra-tracheally with microspheres, IgG1 was the dominant subclass of anti-F1/V IgG in serum. We conclude that introduction of biodegradable microspheres containing the F1 and V sub-units into to the upper or lower respiratory tract engenders immune responses of a magnitude comparable with that induced by parenteral immunisation, and may present a means of protecting individuals from plague.

Immunological responses to nasal delivery of free and encapsulated tetanus toxoid : studies on the effect of vehicle volume

In light of growing interest in the intranasal route as a non-invasive mode of immunisation, we have investigated the relationship between the volume of liquid instilled into the nasal passages and the development of subsequent immunological responses. Groups of six mice were intranasally immunised with soluble or microsphere encapsulated tetanus toxoid on days 1, 14 and 28 of the experiment. Microsphere suspensions and tetanus toxoid solutions were nasally instilled in two different volumes of buffer (10 or 50 microl). Nasal instillation of microspheres in 10 microl of buffer generated statistically depressed (P<0.001) tertiary serum anti-toxoid IgG responses in comparison to animals immunised with 10 or 50 microl of soluble vaccine, or 50 microl of microsphere suspension. Relative to other treatments, nasal inoculation of encapsulated toxoid suspended in 50 microl generated statistically (P<0.05) superior levels of specific IgG and IgA antibodies in day 49 lung wash samples. When radiolabelled microspheres were nasally instilled into mouse nares in 50-microl volumes of buffer, a significant portion of the dose (48%) entered the lungs (P<0.001), whereas more particles remained in the nasal passages when a smaller (10 microl) volume of suspension was given (P<0.001). These biodistribution and immunological data indicate that to generate optimal bronchopulmonary and systemic responses in concert following nasal administration, microparticulated vaccines should be administered with a delivery device that targets the formulation to distal regions of the nasal passages and the lower respiratory tract.

Transfection by particle bombardment: delivery of plasmid DNA into mammalian cells using gene gun.

BACKGROUND Recently, particle bombardment has become increasingly popular as a transfection method, because of a reduced dependency on target cell characteristics. In this study, we evaluated in vitro gene transfer by particle bombardment. METHODS gWIZ luciferase and gWIZ green fluorescent protein (GFP) plasmids were used as reporter genes. Mammalian cell lines HEK 293, MCF7 and NIH/3T3 were used in the transfection experiments. Transfection was performed by bombardment of the cells with gene-coated gold particles using the Helios Gene Gun. The technology was assessed by analyzing gene expression and cell damage. Cell damage was evaluated by MTT assay. RESULTS This technology resulted in efficient in vitro transfection, even in the cells which are difficult to transfect. The gene expression was dependent on the gene guns helium pressure, the sizes of the gold particles, the amount of the particles and DNA loading, while cell viability was mostly dependent on helium pressure and amount of the gold particles. CONCLUSIONS This technology was useful to transfection of cells. Optimal transfection conditions were determined to be between 75 and 100 psi of helium pressure, 1.0 to 1.6 mum gold particle size and 0.5 mg of gold particle amount with a loading ratio of 4 microg DNA/mg gold particles. GENERAL SIGNIFICANCE These findings will be useful in the design of gene gun device, and bring further improvements to the in vitro and in vivo transfection studies including gene therapy and vaccination.

Preparation of polyethyleneimine incorporated poly(d,l-lactide-co-glycolide) nanoparticles by spontaneous emulsion diffusion method for small interfering RNA delivery

Gene therapy based on small interfering RNA (siRNA) has emerged as an exciting new therapeutic approach. However, insufficient cellular uptake and poor stability have limited its usefulness. Polyethyleneimine (PEI) has been extensively studied as a vector for nucleic acids and incorporation of PEI into poly(d,l-lactide-co-glycolide) (PLGA) particles has been shown to be useful in the development of gene delivery. PEI was incorporated into the PLGA particles by spontaneous modified emulsification diffusion method. Incorporation of PEI into PLGA particles with the PLGA to PEI weight ratio 29:1 was found to produce spherical and positively charged nanoparticles where type of polymer, type and concentration of surfactant could affect their physical properties. Particle size of around 100nm was obtained when 5% (m/v) PVA was used as a stabiliser. PLGA-PEI nanoparticles were able to completely bind siRNA at N/P ratio 20:1 and to provide protection for siRNA against nuclease degradation. In vitro cell culture studies subsequently revealed that PLGA-PEI nanoparticles with adsorbed siRNA could efficiently silence the targeted gene in mammalian cells, better than PEI alone, with acceptable cell viability. PLGA-PEI nanoparticles have been found to be superior to its cationising parent compound; PEI polymer.

Therapeutic possibilities of drugs encapsulated in erythrocytes

Abstract The use of erythrocytes as carriers for drugs has been reviewed. Methods for encapsulating drugs into erythrocytes has been discussed with experimental detail. Rigorous loading conditions used in the past have resulted in the formation of vesicles with poor survival times in vivo. More recent loading conditions such as preswelling or dialysis techniques have largely overcome survival problems in vivo. Under clinical conditions erythrocytes have been loaded with drugs by employing standard blood bags as an encapsulating vessel. Electrical and antibiotic loading methods have also been discussed. The limited use of drug- and enzyme-loaded erythrocytes under clinical conditions have shown that resealed erythrocytes can be safely infused into humans. In animal experiments the successful use of encapsulated materials largely depended on the integrity of the cells in vivo. Mild loading conditions have given excellent results in experiments involving the depletion of endogenous substrates by encapsulated enzymes and in where experiments where the circulating cells have acted as a slow release system for drugs. Reference has been made to other slow delivery systems such as liposomes or synthetic micro-vesicles and nano-particles. The possibility of fusing erythrocytes with other cells with the subsequent transfer of encapsulated material by Sendai virus or polyethylene glycol is also discussed (39 references).

Transcutaneous immunisation assisted by low-frequency ultrasound

Low-frequency ultrasound application is known to increase the skins permeability to large molecules such as vaccines, and to enable transcutaneous immunisation. Sodium dodecyl sulphate (SDS) - a skin irritant - is often included in the coupling medium at 1% (w/v), as this has been found to enhance skin permeability. In this paper we show, for the first time, the feasibility of low-frequency ultrasound-assisted transcutaneous immunisation in the absence of SDS. Antibody titres were strongly influenced by experimental conditions. SDS presence in the coupling medium increased antibody titres, though a lower concentration of 0.5% (w/v) generated much higher titres than the commonly used 1% (w/v), despite causing less skin damage. A lower ultrasound duty cycle of 10% generated higher antibody titres than a duty cycle of 20%, also despite causing lower skin damage. Such lack of correlation between skin damage and immune responses indicates that enhancement of skin permeability to topically applied antigen (as indicated by changes in skin integrity) was not the main mechanism of low-frequency ultrasound-assisted skin immunisation.

The prolongation of the in vitro dissolution of a soluble drug (phenethicillin potassium) by microencapsulation with ethyl cellulose

Microcapsules of phenethicillin potassium as a model water‐soluble drug, coated with ethyl cellulose, have been prepared (core: wall ratios 1:1, 1:2 and 1:3) in which the taste has been masked, the odour almost eliminated and the release retarded. Sieve analysis showed that with decreasing core: wall ratios there was a trend towards increasing amounts of larger sized microcapsules. At constant core: wall ratios in vitro release of drug was generally greatest from the larger microcapsules. This result correlated with the surface areas of the microcapsules which became less as the asymmetry of the microcapsules diminished with decrease in microcapsule size. There was a linear relation between the amount of ethyl cellulose and the time for 60% release of drug, and the release pattern was analogous to that from insoluble porous matrices. Scanning electron micrographs showed the microcapsules to be irregularly shaped with circular surface pores, and they did not alter in shape or size during dissolution. Tableting of 1:1 core: wall ratio microcapsules significantly further retarded the dissolution.

Physicochemical and biological characterisation of an antisense oligonucleotide targeted against the bcl-2 mRNA complexed with cationic-hydrophilic copolymers.

The aim of this study was to evaluate the use of cationic-hydrophilic copolymers for self-assembly with antisense oligonucleotides targeted to the bcl-2 mRNA in order to improve their biocompatibility and modulation of their pharmacokinetics for greater therapeutic usefulness. Examination of the ability of poly(trimethylammonioethyl methacrylate chloride)-poly[N-(2-hydroxypropyl)methacrylamide] (pHPMA-b-pTMAEM) block copolymers to condense the oligonucleotide by fluorescence and electrophoresis techniques showed that complexes were formed more efficiently than with copolymers containing poly(ethylene glycol) blocks grafted onto the backbone of poly(L-lysine) (pLL-g-pEG). In addition, the copolymer pTMAEM-b-pHPMA produced oligonucleotide complexes with the most favourable physicochemical properties appropriate for in vivo applications. The complexes were small (approximately 36 nm in diameter), with low surface charge as measured by zeta potential, relatively stable to physiological salt conditions and could be formed at a DNA concentration of 500 microg/ml. Complex formation with the copolymer pTMAEM-b-pHPMA or pLL-g-pEG reduced the urinary clearance of the oligonucleotide after intravenous injection into mice. However after 30 min, the oligonucleotide complexes were cleared from the bloodstream. These results indicate that for the systemic delivery of oligonucleotides the polymer-derived complexes are not stable enough for prolonged circulation. Instead, these complexes may be more suitable for localised in vivo applications.