Stanley Stewart Davis

Chitosan as a novel nasal delivery system for vaccines

A variety of different types of nasal vaccine systems has been described to include cholera toxin, microspheres, nanoparticles, liposomes, attenuated virus and cells and outer membrane proteins (proteosomes). The present review describes our work on the use of the cationic polysaccharide, chitosan as a delivery system for nasally administered vaccines. Several animal studies have been carried out on influenza, pertussis and diphtheria vaccines with good results. After nasal administration of the chitosan-antigen nasal vaccines it was generally found that the nasal formulation induced significant serum IgG responses similar to and secretory IgA levels superior to what was induced by a parenteral administration of the vaccine. Animals vaccinated via the nasal route with the various chitosan-antigen vaccines were also found to be protected against the appropriate challenge. So far the nasal chitosan vaccine delivery system has been tested for vaccination against influenza in human subjects. The results of the study showed that the nasal chitosan influenza vaccine was both effective and protective according to the CPMP requirements. The mechanism of action of the chitosan nasal vaccine delivery system is also discussed.

A mucosal vaccine against diphtheria: formulation of cross reacting material (CRM197) of diphtheria toxin with chitosan enhances local and systemic antibody and Th2 responses following nasal delivery

The development of new generation vaccines against diphtheria is dependent on the identification of antigens and routes of immunization that are capable of stimulating immune responses similar to, or greater than, those obtained with the parenterally-delivered toxoid vaccine, while reducing the adverse effects that have been associated with the traditional vaccine. In this study, we examined the cellular and humoral immune responses in mice generated after both parenteral and mucosal immunizations with cross-reacting material (CRM(197)) of diphtheria toxin. We found that both native and mildly formaldehyde-treated CRM(197) and conventional diphtheria toxoid (DT) induced mixed Th1/Th2 responses and similar levels of anti-DT serum IgG following parenteral immunization. In contrast, CRM(197) preparations were poorly immunogenic when administered intranasally in solution. However, formulation of the antigens with chitosan significantly enhanced their immunogenicity, inducing high levels of antigen-specific IgG, secretory IgA, toxin-neutralizing antibodies and T cell responses, predominately of Th2 subtype. Furthermore, intranasal immunization with CRM(197) and chitosan induced protective antibodies against the toxin in a guinea pig passive challenge model. We also found that priming parenterally with DT in alum and boosting intranasally with CRM(197) was a very effective method of immunization in mice, capable of inducing high levels of anti-DT IgG and neutralizing antibodies in the serum and secretory IgA in the respiratory tract. Our findings suggest that boosting intranasally with CRM(197) antigen may be very effective in adolescents or adults who have previously been parenterally immunized with a conventional diphtheria toxoid vaccine.

Nasal delivery of chitosan-DNA plasmid expressing epitopes of respiratory syncytial virus (RSV) induces protective CTL responses in BALB/c mice.

Respiratory syncytial virus (RSV), an important pathogen of the lower respiratory tract, is responsible for severe illness both in new born and young children and in elderly people. Due to complications associated with the use of the early developed vaccines, there is still a need for an effective vaccine against RSV. Most pathogens enter the body via mucosal surfaces and therefore vaccine delivery via routes such as the nasal, may well prove to be superior in inducing protective immune responses against respiratory viruses, since both local and systemic immunity can be induced by nasal immunisation. Previously we have shown that intradermal immunisation of a plasmid DNA encoding the CTL epitope from the M2 protein of RSV induced protective CTL responses. In the present study, the mucosal delivery of plasmid DNA formulated with chitosan has been investigated. Chitosan is a polysachharide consisting of copolymers of N-acetylglucosamine and glucosamine that is derived from chitin, a material found in the shells of crustacea. Intranasal immunisation with plasmid DNA formulated with chitosan induced peptide- and virus-specific CTL responses in BALB/c mice that were comparable to those induced via intradermal immunisation. Following RSV challenge of chitosan/DNA immunised mice, a significant reduction (P<0.001) in the virus load was observed in the lungs of immunised mice compared to that in the control group. These results indicate the potential of immunisation with chitosan-formulated epitope-based vaccines via the intranasal route.

Bioadhesive starch microspheres and absorption enhancing agents act synergistically to enhance the nasal absorption of polypeptides

This paper investigates the effect of starch microspheres on the absorption enhancing efficiency of various enhancer systems in formulations with insulin after application in the nasal cavity of sheep. The enhancers studied were lysophosphatidylcholine, glycodeoxycholate and sodium taurodihydroxyfusidate, a bile salt derivative. The enhancers were selected on the basis of their perceived or proven mechanism of action and worked predominantly by interacting with the lipid membrane. The bioadhesive starch microspheres were shown to increase synergistically the effect of the absorption enhancers on the transport of the insulin across the nasal membrane. Dependent on the potency of the enhancer system the increment in absorption enhancement was shown to be from 1.4 times to 5 times that obtained for the absorption enhancer in solution.

Intranasal insulin. Clinical pharmacokinetics.

SummaryInsulin administered nasally has considerable potential for the treatment of both insulin-dependent (IDDM) and non—insulin-dependent (NIDDM) diabetes. For patients with NIDDM it is possible to prevent preprandial hyperglycaemia and postprandial hypoglycaemia by employing a suitable and properly timed intranasal insulin dose. The low bioavailability of simple formulations of insulin can be greatly improved by using absorption enhancers or novel delivery systems such as bioadhesive microspheres. The need for nontoxic and nonirritant systems is stressed.

Polymeric lamellar substrate particles for intranasal vaccination

In recent years, several strategies have been under investigation to achieve safe and effective immunisation, in terms of new antigens, adjuvants and routes of vaccination. The latter include mucosal sites such as oral, rectal, vaginal and nasal. Biodegradable microparticles produced from polymers such as poly(D,L-lactide) (PLA) and poly(D,L-lactide-co-glycolide) (PLGA) containing encapsulated vaccine antigens have been extensively studied for immunisation. These microparticles allow controlled release of vaccines with the aim to develop as single dose vaccines. However there are concerns regarding the integrity and immunogenicity of the antigen during the encapsulation process when the antigen is exposed to organic solvents, high shear stresses and the exposure of antigen to low pH which is caused by polymer degradation. Polymeric lamellar substrate particles (PLSP) produced by simple precipitation of PLA, form a novel polymeric system for the adsorption of antigens. This procedure avoids pH changes, exposure to organic solvents and hence allows the integrity of the antigen to be retained. The aim of this article is to discuss the factors affecting the characteristics of PLSP and adsorption of antigens onto PLSP and consider their potential as adjuvants for the nasal delivery of protein, peptide or viral vaccines.

The effect of blood sampling site and physicochemical characteristics of drugs on bioavailability after nasal administration in the sheep model.

AbstractPurpose. Investigate the effect of blood sampling site and physicochemical characteristics of drugs on the pharmacokinetic (PK) parameters obtained after intravenous and nasal administration in sheep and compare results with computer simulations.nMethods. Three drugs, insulin, morphine, and nicotine, were administered nasally and by intravenous (IV) injection to sheep, and serial blood samples collected concurrently from the carotid artery (insulin, morphine) or cephalic vein (nicotine) and jugular vein. Plasma drug concentrations were measured, and pharmacokinetic and statistical analyses performed, to evaluate sampling site differences.nResults. After nasal insulin, bioavailabilities calculated from the two blood sampling site data were comparable. In contrast, apparent bioavailabilities following nasal morphine or nicotine were significantly higher when sampling was from the jugular vein. These results were supported by computer simulations. These observations are attributed to the greater effects of noninstantaneous mixing of drugs for jugular vein sampling following nasal dosing, compared to the other sampling sites, which is significant for drugs that are rapidly and well absorbed and that have a high volume of distribution (Vd).nConclusion. The results clearly show that the characteristics of the drug and the blood sampling site can have a significant effect on the pharmacokinetic results obtained after nasal administration in sheep.