Novel dry powder preparations of whole inactivated influenza virus for nasal vaccination.

The purpose of these studies was to enhance mucosal and systemic antibody production in response to increased local residence time of a whole inactivated influenza virus administered as a dry powder nasal vaccine formulation. Spray-freeze-drying (SFD) particles suitable for nasal delivery were characterized for physico-chemical properties and stability. Mucoadhesive compounds (MA) were characterized for their effects on nasal residence time of vaccine powders in rats compared with published in vitro data and elicited immune responses. SFD particles (D(50) = 26.9 microm) were spherical with a specific surface area of 1.25 m(2)/g. Thermal analysis indicated SFD powders were amorphous and demonstrated improved stability with respect to liquid formulations under various storage conditions. In vitro physico-chemical studies and in vivo scintigraphic imaging experiments indicated sodium alginate (SA) and carboxymethylcellulose-high molecular weight (CMC-HMW) powder formulations most significantly increased residence time in Brown Norway rats. Intramuscular delivery provided equivalent serum antibody titers to intranasal (IN) powder without MA, in the presence of CMC-HMW, SA, and hydroxypropyl methylcellulose (HPMC-HMW) after initial dosing and all formulations except IN powder with chitosan after boosting. IN liquid provided equivalent serum antibody titers to all IN powders after the initial vaccination and significantly greater serum antibody titers than IN powder with chitosan after boosting. Trends were consistent between residence time studies and immune response; however, no statistically significant differences between powder and liquid formulations were observed. It was concluded that enhanced serum and mucosal antibody responses were elicited by a dry powder nasal vaccine, specifically, administered in the presence of sodium alginate.

Spray-dried chitinosans. Part I: preparation and characterization.

PURPOSE: Physicochemical and micromeritic characterization of chitinosans. METHODS: Chitinosans subjected to N-deacetylation and depolymerization were characterized for degree of N-deacetylation (DD), molecular weight (MW), pK(a), particle size determination and morphology, tap/bulk density measurements, surface area determinations, and determination of flow properties. RESULTS: The chitinosan DDs and MWs were dependent on the processing conditions and ranged from 66 to 89% and 2-522 kDa, respectively. Chitinosan particle sizes and shapes were dependent on drying conditions (range 8-465 microm). Spray-dried chitinosans were spherical and had smaller particle sizes than the non-spray-dried materials which were irregularly shaped particles. Higher density values were obtained for processed materials than those for the raw material. Lower specific surface areas were observed for non-spray-dried chitinosans (0.28-1.59 m(2)/g) than for spray-dried chitinosans (0.74-3.01 m(2)/g). Weight variation of chitinosan tablets indicated that spray-dried chitinosans possessed improved flow characteristics as compared with tray-dried chitinosans. CONCLUSIONS: The effect of drying method employed in chitinosan manufacture, i.e. spray versus tray drying, on the physicochemical and micromeritic properties of the resultant chitinosans were evaluated. Although the drying methods did not significantly influence the physicochemical properties, they affected the micromeritic properties of the resultant chitinosans.