Chitosan hydrogels containing liposomes and cubosomes as particulate sustained release vaccine delivery systems

Sustained release depot systems have been widely investigated for their potential to improve the efficacy of subunit vaccines and reduce the requirement for boosting. The present study aimed to further enhance the immunogenicity of a sustained release vaccine by combining a depot formulation with a particulate antigen delivery system. Sustained release of the model subunit antigen, ovalbumin (OVA), was observed in vivo from chitosan thermogel-based formulations containing cationic, nanosized liposomes loaded with OVA and the immunopotentiator, Quil A (QA). Such formulations demonstrated the ability to induce cluster of differentiation (CD)8(+) and CD4(+) T-cell proliferation and interferon (IFN)-γ production, as well as the production of OVA-specific antibody. However, gel-incorporated liposomes showed evidence of instability and similar in vivo immune responses to liposomes in gel formulations were induced by gel-based systems loaded with soluble OVA and QA. The immunogenicity of chitosan thermogels containing cubosomes, a more stable lipidic particulate system, was therefore examined. Similarly, all gel-based formulations produced comparable effector immune responses in experimental mice, irrespective of whether the antigen and immunopotentiator were present in gels within cubosomes or in a soluble form. This work demonstrates the potential for sustained release thermogelling systems and highlights the importance of matching the physicochemical and immunological properties of the particulate system to that of the depot.     

Immunoglobulin immobilized liposomal constructs for transmucosal vaccination through nasal route

The aim of the present investigation was to evaluate the prospective of surface-engineered vesicular carriers for mucosal immunization via the nasal route. IgG antibody was immobilized on the surface of hepatitis B surface antigen (HBsAg) antigen–loaded liposomes. The developed formulations were characterized on the basis of physicochemical parameters, such as morphology, particle size, polydispersity index, entrapment efficiency, and zeta potential. Liposomal formulations were then evaluated for in-process antigen stability and storage stability. In vivo studies were conducted to visualize targeting potential, localization pattern, and immunogenicity. In addition, immune response was compared with alum-HBsAg vaccine injected intramuscularly. The serum anti-HBsAg titer, obtained from the postnasal administration of IgG-coupled liposomes, was significantly higher than plain liposomes. Moreover, IgG-coupled liposomes generated both humoral (i.e., systemic and mucosal) and cellular immune responses upon nasal administration, while the alum-adsorbed antigen displayed neither cellular (cytokine level) nor mucosal (IgA) response. The formulation also displayed enhanced transmucosal transport, improved in vitro stability, and effective immunoadjuvant property. To conclude, IgG antibody-coupled liposomes may serve as novel carriers to augment the secretory immune response of antigen encapsulated in the liposomes, apparently by escalating liposome uptake via M cells, thereby rationalizing their use as a carrier adjuvant for nasal subunit vaccines.     

Effect of Liposomal Formulations and Immunostimulating Peptidoglycan Monomer (PGM) on the Immune Reaction to Ovalbumin in Mice

The adjuvant activity of liposomes and immunostimulating peptidoglycan monomer (PGM) in different formulations has been studied in mice model using ovalbumin (OVA) as an antigen. PGM is a natural compound of bacterial origin with well-defined chemical structure: GlcNAc-MurNAc-l-Ala-d-isoGln-mesoDpm(εNH₂)-d-Ala-d-Ala. It is a non-toxic, non-pyrogenic, and water-soluble immunostimulator. The aim of this study was to investigate the influence of different liposomal formulations of OVA, with or without PGM, on the production of total IgG, as well as of IgG1 and IgG2a subclasses of OVA-specific antibodies (as indicators of Th2 and Th1 type of immune response, respectively). CBA mice were immunized s.c. with OVA mixed with liposomes, OVA with PGM mixed with liposomes, OVA encapsulated into liposomes and OVA with PGM encapsulated into liposomes. Control groups were OVA in saline, OVA with PGM in saline, and OVA in CFA/IFA adjuvant formulation. The entrapment efficacy of OVA was monitored by HPLC method. The adjuvant activity of the mixture of OVA and empty liposomes, the mixture of OVA, PGM, and liposomes and PGM encapsulated with OVA into liposomes on production of total anti-OVA IgG was demonstrated. The mixture of PGM and liposomes exhibited additive immunostimulating effect on the production of antigen-specific IgGs. The analysis of IgG subclasses revealed that encapsulation of OVA into liposomes favors the stimulation of IgG2a antibodies, indicating the switch toward the Th1 type of immune response. When encapsulated into liposomes or mixed with liposomes, PGM induced a switch from Th1 to Th2 type of immune response. It could be concluded that appropriate formulations of antigen, PGM, and liposomes differently affect the humoral immune response and direct the switch in the type of immune response (Th1/Th2).     

Design and development of multivesicular liposomal depot delivery system for controlled systemic delivery of acyclovir sodium

The aim of the present study was to design a depot delivery system of acyclovir sodium using multivesicular liposomes (MVLs) to overcome the limitations of conventional therapies and to investigate its in vivo effectiveness for sustained delivery. MVLs of acyclovir were prepared by the reverse phase evaporation method. The loading efficiency of the MVLs (45%–82%) was found to be 3 to 6 times higher than conventional multilamellar vesicles (MLVs). The in vitro release of acyclovir from MVL formulations was found to be in a sustained manner and only 70% of drug was released in 96 hours, whereas conventional MLVs released 80% of drug in 16 hours. Following intradermal administration to Wistar rats, the MVL formulations showed effective plasma concentration for 48 hours compared with MLVs and free drug solution (12–16 hours). C_max values of MVL formulations were significantly less (8.6–11.4 μg/mL) than MLV and free drug solution (12.5 μg/mL). The AUC_0–48 of the MVL formulations was 1.5- and 3-fold higher compared with conventional liposomes and free drug solution, respectively. Overall, formulations containing phosphatidyl glycerol as negatively charged lipid showed better results. The MVL delivery system as an intradermal depot offers the advantage of a very high loading and controlled release of acyclovir for an extended period of time. The increase in AUC and decrease in C_max reflects that the MVL formulations could reduce the toxic complications and limitations of conventional IV and oral therapies. Published: September 20, 2005     

Terbinafine hydrochloride loaded liposome film formulation for treatment of onychomycosis: in vitro and in vivo evaluation

Onychomycosis is a fungal infection of nail unit that is caused by dermatophytes. Oral Terbinafine hydrochloride (TBF-HCl) is being used for the treatment of onychomycosis since 24 years. The side effects caused by the systemic application and limitations of topical administration of this drug regarding the diffusion through nail lead to the development of a new formulation based on, TBF-HCl-loaded liposome. The newly obtained film formulations were prepared and characterized via several parameters, such as physical appearance, drug content, thickness, bioadhesive properties and tensile strength. In vitro and ex vivo permeation studies were performed to select an optimum film formulation for antifungal activity to show the efficiency of formulations regarding the treatment of onychomycosis. The in vitro release percentages of drug were found 71.6?±?3.28, 54.4?±?4.26, 56.1?±?7.48 and 46.0?±?2.43 for liposome loaded pullulan films (LI-P, LII-P) and liposome loaded Eudragit films (LI-E, LII-E), respectively. The accumulated drug in the nail plates were found 31.16?±?4.22, 24.81?±?5.35, 8.17?±?1.81 and 8.92?±?3.37 for LI-P, LII-P, LI-E and LII-E, respectively, which within therapeutic range for all film formulations. The accumulated drug in the nail plate was found within therapeutic range for all film formulations. The efficacy of the selected TBF-HCl-loaded liposome film formulation was compared with TBF-HCl-loaded liposome, ethosome, liposome poloxamer gel and ethosome chitosan gel formulations. It was found that TBF-HCl-loaded liposome film formulation had better antifungal activity on fungal nails which make this liposome film formulation promising for ungual therapy of fungal nail infection.     

Design and Evaluation of Self-Emulsifying Drug Delivery Systems (SEDDS) of Nimodipine

The ability of self-emulsifying drug delivery systems (SEDDS) to improve solubility, dissolution rate and bioavailability of a poorly water-soluble calcium channel blocker, nimodipine (NM) was evaluated in the present investigation. Solubility of NM in various oils, surfactants and cosurfactants was determined. The influence of the ratio of oil to surfactant + cosurfactant, pH of aqueous phase on mean globule size of resulting emulsions was studied by means of photon correlation spectroscopy. The NM loaded SEDDS selected for the in vitro and in vivo studies exhibited globule size less than 180 nm. In vitro dissolution studies indicated that NM loaded SEDDS could release complete amount of NM irrespective of the pH of the dissolution media. Pharmacokinetics of NM suspension, NM oily solution, NM micellar solution and NM SEDDS were evaluated and compared in rabbits. Relative bioavailability of NM in SEDDS was significantly higher than all the other formulations. NM loaded SEDDS were subjected to various conditions of storage as per ICH guidelines for 3 months. NM SEDDS successfully withstood the stability testing.     

Delivery of protein antigens to the immune system by fusion-active virosomes: a comparison with liposomes and ISCOMs

The induction of effective cellular and humoral immune responses against protein antigens is of major importance in vaccination strategies against infectious diseases and cancer. Immunization with protein alone in general does not result in efficient induction of cytotoxic T lymphocyte (CTL) and antibody responses. Numerous other immunization strategies have been explored. In this review we will discuss a number of lipid-based antigen delivery systems suitable for the induction of CTL responses. These systems comprise reconstituted virus envelopes (virosomes), liposomes, and immune-stimulating complexes (ISCOMs). We will concentrate on delivery of the protein antigen ovalbumin (OVA) since extensive studies with this antigen have been performed for all of the systems discussed, allowing direct comparison of antigen delivery efficiency. Stimulation of CTL activity requires processing of the antigen in the cytosol of antigen-presenting cells (APCs) and presentation of antigenic peptides on surface major histocompatibility class I complexes (MHC class I). In vitro, the ability of antigen delivery systems to induce MHC class I presentation indeed correlates with their capacity to deliver antigen to the cytosol of cells. This capacity appears to be less important for the induction of cytotoxic T lymphocytes in vivo. Instead, other properties of the antigen delivery system like activation of APCs and induction of T helper cells play a more prominent role. Fusion-active virosomes appear to be a very potent system for induction of CTL activity, most likely since virosomes combine efficient delivery of antigen with general stimulation of the immune system.     

Nanostructured cubosomes in an in situ nasal gel system: an alternative approach for the controlled delivery of donepezil HCl to brain

Abstract

The purpose of this research was to develop cubosomal mucoadhesive in situ nasal gel to enhance the donepezil HCl delivery to the brain. Glycerol mono-oleate (GMO) and surfactant poloxamer 407 were used to prepare cubosomes. The developed formulations were characterized for particle size (PS), poly dispersity index (PDI), zeta potential (ZP), entrapment efficiency (EE), transmission electron microscopy (TEM), in vitro drug release and in vivo bio-distribution study in blood and brain tissue. Central composite design was used for the optimization purpose and the selected formulation (containing GMO 2?g and poloxamer 1.5%) was prepared in presence of gellan gum and konjac gum as gelling agent and mucoadhesive agent respectively. The optimal cubosomal dispersion and optimal cubosomal mucoadhesive in situ nasal gel were subjected to in vivo bio-distribution studies in rat model. It showed significantly higher transnasal permeation and better distribution to the brain, when compared to the drug solution. Thus, the formulated cubosomal mucoadhesive in situ gel could be considered as a promising carrier for brain targeting of CNS acting drugs through the transnasal route.     

Liposomal-based lidocaine formulation for the improvement of infiltrative buccal anaesthesia

This study describes the encapsulation of the local anaesthetic lidocaine (LDC) in large unilamellar liposomes (LUV) prepared in a scalable procedure, with hydrogenated soybean phosphatidylcholine, cholesterol and mannitol. Structural properties of the liposomes were assessed by dynamic light scattering, nanoparticle tracking analysis and transmission electron microscopy. A modified, two-compartment Franz-cell system was used to evaluate the release kinetics of LDC from the liposomes. The in vivo anaesthetic effect of liposomal LDC 2% (LUV_LDC) was compared to LDC 2% solution without (LDC_PLAIN) or with the vasoconstrictor epinephrine (1:100 000) (LDC_VASO), in rat infraorbital nerve blockade model. The structural characterization revealed liposomes with spherical shape, average size distribution of 250?nm and low polydispersity even after LDC incorporation. Zeta potential laid around –30?mV and the number of suspended liposomal particles was in the range of 10¹² vesicles/mL. Also the addition of cryoprotectant (mannitol) did not provoke structural changes in liposomes properties. In vitro release profile of LDC from LUV fits well with a biexponential model, in which the LDC encapsulated (EE%?=?24%) was responsible for an increase of 67% in the release time in relation to LDC_PLAIN (p?<?0.05). Also, the liposomal formulation prolonged the sensorial nervous blockade duration (～70?min), in comparison with LDC_PLAIN (45?min), but less than LDC_VASO (130?min). In this context, this study showed that the liposomal formulations prepared by scalable procedure were suitable to promote longer and safer buccal anaesthesia, avoiding side effects of the use of vasoconstrictors.     

Oral delivery of antigens in liposomes with some lipid compositions modulates oral tolerance to the antigens

Several liposomes containing ovalbumin (OVA), a model antigen, with different lipid compositions were prepared in order to evaluate their ability to induce oral tolerance. Oral administration of these liposomal OVAs induced suppression of the proliferative responses of popliteal lymph node cells from the treated mice to OVA, suggesting that these treated mice were tolerized. The efficiency of the induction of oral tolerance was affected by the liposome composition. OVA entrapment in these liposomes could modulate the tolerizing dose of OVA itself. These results suggest that some liposomes can be suitable antigen-delivery systems for modulated and/or effective induction of oral tolerance.     

Effect of liposomal formulations and immunostimulating peptidoglycan monomer (PGM) on the immune reaction to ovalbumin in mice

The adjuvant activity of liposomes and immunostimulating peptidoglycan monomer (PGM) in different formulations has been studied in mice model using ovalbumin (OVA) as an antigen. PGM is a natural compound of bacterial origin with well-defined chemical structure: GlcNAc-MurNAc-L-Ala-D-isoGln-mesoDpm(epsilonNH2)-D-Ala-D-Ala. It is a non-toxic, non-pyrogenic, and water-soluble immunostimulator. The aim of this study was to investigate the influence of different liposomal formulations of OVA, with or without PGM, on the production of total IgG, as well as of IgG1 and IgG2a subclasses of OVA-specific antibodies (as indicators of Th2 and Th1 type of immune response, respectively). CBA mice were immunized s.c. with OVA mixed with liposomes, OVA with PGM mixed with liposomes, OVA encapsulated into liposomes and OVA with PGM encapsulated into liposomes. Control groups were OVA in saline, OVA with PGM in saline, and OVA in CFA/IFA adjuvant formulation. The entrapment efficacy of OVA was monitored by HPLC method. The adjuvant activity of the mixture of OVA and empty liposomes, the mixture of OVA, PGM, and liposomes and PGM encapsulated with OVA into liposomes on production of total anti-OVA IgG was demonstrated. The mixture of PGM and liposomes exhibited additive immunostimulating effect on the production of antigen-specific IgGs. The analysis of IgG subclasses revealed that encapsulation of OVA into liposomes favors the stimulation of IgG2a antibodies, indicating the switch toward the Th1 type of immune response. When encapsulated into liposomes or mixed with liposomes, PGM induced a switch from Th1 to Th2 type of immune response. It could be concluded that appropriate formulations of antigen, PGM, and liposomes differently affect the humoral immune response and direct the switch in the type of immune response (Th1/Th2).     

N-trimethyl chitosan chloride-coated liposomes for the oral delivery of curcumin

The aims of this study were to design the formulation of curcumin (CUR) liposomes coated with N-trimethyl chitosan chloride (TMC) and to evaluate in vitro release characteristics and in vivo pharmacokinetics and bioavailability of TMC-coated CUR liposomes in rats. The structure of synthesized TMC was examined by infrared spectroscopy, with the presence of trimethyl groups, and by proton nuclear magnetic resonance spectroscopy, indicating the high degree of substitution quaternization (65.6%). Liposomes, composed of soybean phosphotidylcholine, cholestrol, and D-α-tocopheryl polyethylene glycol 1000 succinate, were prepared by a thin-film dispersion method. Characteristics of the CUR liposomes, including entrapment efficiency (86.67%), drug-loading efficiency (2.33%), morphology, particle size (221.4?nm for uncoated liposomes and 657.7?nm for TMC-coated liposomes), and zeta potential (–9.63 mV for uncoated liposomes and +15.64 mV for TMC-coated liposomes) were investigated. Uncoated CUR liposomes and TMC-coated CUR liposomes showed a similar in vitro release profile. Nearly 50% of CUR was released from liposomes, whereas 80% of CUR was released from CUR propylene glycol solution. CUR incorporated into TMC-coated liposomes exhibited different pharmacokinetic parameters and enhanced bioavailability (C_max?=?46.13 μg/L, t_1/2?=?12.05 hours, AUC?=?416.58 μg/L·h), compared with CUR encapsulated by uncoated liposomes (C_max?=?32.12 μg/L, t_1/2?=?9.79 hours, AUC?=?263.77 μg/L·h) and CUR suspension (C_max?=?35.46 μg/L, t_1/2?=?3.85 hours, AUC?=?244.77 μg/L·h). In conclusion, oral delivery of coated CUR liposomes is a promising strategy for poorly water-soluble CUR.     

Miconazole nitrate bearing ultraflexible liposomes for the treatment of fungal infection

Miconazole nitrate is a widely used antifungal agent, but its use in topical formulations is not efficacious because deep seated fungal infections are difficult to treat with conventional topical formulation. Miconazole nitrate loaded ultraflexible liposomes have been prepared and their topical performance has been compared with conventional liposomes containing miconazole nitrate. Various ultraflexible liposomal formulations were prepared and extensively characterized for vesicular shape, size, entrapment efficiency, degree of deformability and in-vitro skin permeation through rat skin. Higher rate of drug transfer across the skin with ultraflexible liposomal formulations of miconazole nitrate suggests that the drug in its lipo-solubilized state might have gained facilitated entry into the tough barrier consisting of subcutaneous. In-vivo study showed better antifungal activity as compared to traditional liposomes and plain drug solution. This was confirmed through fluoroscence microscopy. It is concluded that prepared ultraflexible liposomes can facilitate improved and localized drug action in the skin, thus providing a better option to deal with deep seated skin problems.     

Interleukin-2/liposomes potentiate immune responses to a soluble protein cancer vaccine in mice

A critical element in improving the potency of cancer vaccines, especially pure protein or peptide antigens, is to develop procedures that can strongly but safely increase their ability to induce immune responses. Here, we describe that encapsulation of a pure protein antigen and interleukin-2 (IL-2) together into liposomes significantly improves immune responses and tumor protection. Groups of C57Bl/6 mice were immunized weekly ×4 with –0.1 mg of ovalbumin (OVA) injected subcutaneously in PBS or encapsulated in liposomes with or without human recombinant IL-2. Control groups included mice immunized to irradiated E.G7-OVA cells (that express ovalbumin), or to PBS. Sera were collected and pooled by immunization group at baseline and at weeks 2 and 4 to measure antibody responses to OVA by ELISA. Splenocytes obtained at week 4 were tested for anti-OVA cellular responses by ELISPOT. Mice were then challenged to a lethal dose of E.G7-OVA cells to measure tumor-protective immunity. IL-2 liposomes caused no detectable toxicity. Antibody, CD8⁺ T cell, and tumor-protective immune responses were markedly enhanced in mice immunized to OVA + IL-2 in liposomes compared to mice immunized to OVA, either alone or encapsulated into liposomes without IL-2. These results indicate that IL-2 liposomes enhance antibody, cellular, and tumor-protective immune responses to immunization with a soluble protein. This may provide a simple, safe, and effective way to enhance the immunogenicity of vaccines that consist of pure protein antigens. Supported by grant CA096804 (DJ)     

<Emphasis Type="Italic">In vivo</Emphasis> Quinolinic Acid Increases Synaptosomal Glutamate Release in Rats: Reversal by Guanosine

Glutamate, the main excitatory neurotransmitter in the mammalian central nervous system (CNS), plays important role in brain physiological and pathological events. Quinolinic acid (QA) is a glutamatergic agent that induces seizures and is involved in the etiology of epilepsy. Guanine-based purines (GBPs) (guanosine and GMP) have been shown to exert neuroprotective effects against glutamatergic excitotoxic events. In this study, the influence of QA and GBPs on synaptosomal glutamate release and uptake in rats was investigated. We had previously demonstrated that QA “in vitro” stimulates synaptosomal L-[³H]glutamate release. In this work, we show that i.c.v. QA administration induced seizures in rats and was able to stimulate synaptosomal L-[³H]glutamate release. This in vivo neurochemical effect was prevented by i.p. guanosine only when this nucleoside prevented QA-induced seizures. I.c.v. QA did not affect synaptosomal L-[³H]glutamate uptake. These data provided new evidence on the role of QA and GBPs on glutamatergic system in rat brain.     

Vault nanocapsules as adjuvants favor cell-mediated over antibody-mediated immune responses following immunization of mice

Background

Modifications of adjuvants that induce cell-mediated over antibody-mediated immunity is desired for development of vaccines. Nanocapsules have been found to be viable adjuvants and are amenable to engineering for desired immune responses. We previously showed that natural nanocapsules called vaults can be genetically engineered to elicit Th1 immunity and protection from a mucosal bacterial infection. The purpose of our study was to characterize immunity produced in response to OVA within vault nanoparticles and compare it to another nanocarrier.

Methodology and Principal Findings

We characterized immunity resulting from immunization with the model antigen, ovalbumin (OVA) encased in vault nanocapsules and liposomes. We measured OVA responsive CD8⁺ and CD4⁺ memory T cell responses, cytokine production and antibody titers in vitro and in vivo. We found that immunization with OVA contain in vaults induced a greater number of anti-OVA CD8⁺ memory T cells and production of IFNγ plus CD4⁺ memory T cells. Also, modification of the vault body could change the immune response compared to OVA encased in liposomes.

Conclusions/Significance

These experiments show that vault nanocapsules induced strong anti-OVA CD8⁺ and CD4⁺ T cell memory responses and modest antibody production, which markedly differed from the immune response induced by liposomes. We also found that the vault nanocapsule could be modified to change antibody isotypes in vivo. Thus it is possible to create a vault nanocapsule vaccine that can result in the unique combination of immunogen-responsive CD8⁺ and CD4⁺ T cell immunity coupled with an IgG1 response for future development of vault nanocapsule-based vaccines against antigens for human pathogens and cancer.     

Characterization and evaluation of stabilized particulate formulations as therapeutic oral vaccines for allergy

Abstract

Allergic conditions affect more than a quarter of the population in developed countries, but currently available treatments focus more on symptom relief than treating the underlying atopic condition. α-Galactosylceramide (α-GalCer) is a potent immunomodulating compound that has been shown to have a regulatory effect when delivered systemically in nanoparticles. Parenteral delivery is not preferred for chronic conditions, such as allergy, and therefore, the aim of this study was to determine whether a regulatory response could be induced through oral administration in a model of atopy through incorporation of α-GalCer into stable particulate formulations (cationic liposomes, polymerized liposomes and poly(lactic-co-glycolic acid) nanoparticles (PLGA NPs)). The formulations showed only minor changes in particle size, polydispersity index and retention of the model antigen ovalbumin (OVA) during incubation in simulated gastrointestinal (GI) conditions. Oral delivery of α-GalCer in cationic liposomes could induce immunostimulating effects systemically, as seen through increases in serum IgG antibody levels, whereas delivery of α-GalCer in polymerized liposomes and PLGA NPs induced local cytokine changes in the mesenteric lymph nodes (MLNs). The generated responses did not exhibit tolerogenic traits which could be useful for immunoregulation, but the responses generated varied between formulations and suggests that further characterization and optimization could lead to the desired immune response.     

Modification of Delivery System Enhances MHC Nonrestricted Immunogenicity of V3 Loop Region of HIV-1 gp120

A successful peptide vaccine for AIDS is desired to elicit T-helper and cytotoxic T lymphocyte responses besides neutralizing antibodies. The V3 loop peptide of HIV-1 has been shown to contain the principal neutralizing domain, one of the most immunodominant regions, having both B-cell and T-cell determinants. In this study, the tip of the V3 loop region was mutated from GPGR to GPGQ based on the sequence of Indian isolates (CKRKIHIGPGQAFYT). To further enhance the immunogenicity of this epitope, two delivery systems of immune stimulating complexes (ISCOMs) and liposomes were used to incorporate the peptide. Mice of differing haplotypes, H-2^b, H-2^d, H-2^k and H-2^S, showed no MHC restriction when immunized with these formulations. The IgG levels as assessed by ELISA were found to be significantly higher (P<0.05 to P< 0.001) for even five-fold lower doses of the peptide in ISCOMs and liposomes as compared to the conventional alum-based preparation. The major subtype elicited was IgG2a/IgG2b, suggestive of a Th1-like response for all the formulations. Thus, it would appear that the same peptide incorporated in ISCOMs and liposomes selects a Th1 response and may therefore be important not only for neutralization but also for virus clearance.     

Polymer coated liposomes for use in the oral cavity – a study of the in vitro toxicity,effect on cell permeability and interaction with mucin

In this study we investigated the in vitro toxicity, impact on cell permeability and mucoadhesive potential of polymer-coated liposomes intended for use in the oral cavity. A TR146 cell line was used as a model. The overall aim was to end up with a selection of safe polymer coated liposomes with promising mucoadhesive properties for drug delivery to the oral cavity. The following polymers were tested: chitosan, low-methoxylated pectin (LM-pectin), high-methoxylated pectin (HM-pectin), amidated pectin (AM-pectin), Eudragit, poly(N-isopropylacrylamide-co-methacrylic acid) (p(NIPAAM-co-MAA)), hydrophobically modified hydroxyethyl cellulose (HM-HEC), and hydrophobically modified ethyl hydroxyethyl cellulose (HM-EHEC). With chitosan as an exception, all the systems exhibited no significant effect on cell viability and permeability at the considered concentrations. Additionally, all the formulations showed to a varying degree an interaction with mucin (BSM type I-S); the positively charged formulations exhibited the strongest interaction, while the negatively and neutrally charged formulations displayed a moderate or low interaction. The ability to interact with mucin makes all the liposomal formulations promising for oromucosal administration. Although the chitosan-coated liposomes affected the cell viability, this formulation also influenced the cell permeability, which makes it an interesting candidate for systemic drug delivery from the oral cavity.     

Liposomes as adjuvant for combination vaccines

In the present study tetanus toxoid (TT) loaded liposomes and diphtheria toxoid (DT) loaded liposomes were prepared by reverse phase evaporation method and after combining these two vaccines the potential advantages were investigated. Prepared systems were characterized for the size, shape and entrapment efficiency. SDS-PAGE analysis of TT and DT was also performed. The selected liposomal formulations were administered subcutaneously to Balb/c mice and their immune responses were determined using ELISA after 15, 30, 45 days. After boosting the maximum immune response was observed after 45 days and was found to be 0.831 and 0.749 for TT loaded liposome and DT loaded liposomes respectively. When the mice were immunized subcutaneously with the physical mixture of TT loaded liposomes and DT loaded liposomes the immune response for the combination vaccine was found to be 1.44 and 0.741 for the TT and DT respectively. The result showed that the immune response of TT increased when it was combined with DT in liposomes. This confirms adjuvantcity of DT vis-a-vis immunogenicity. Thus, carrier mediated cocktail vaccination holds promise for clinical applications.