Microneedles with intrinsic immunoadjuvant properties: microfabrication, protein stability, and modulated release.

PURPOSE: Intradermal immunization using microneedles requires compatible immunoadjuvant system. To address this challenge, we investigated microneedles coated with polyphosphazene polyelectrolyte, which served both as microfabrication material and an immunoadjuvant compound. METHODS: Coated microneedles were fabricated by depositing formulations containing Poly[di(carboxylatophenoxy)phosphazene], PCPP, on metal shafts, and their physico-chemical characterization was conducted. RESULTS: Microfabrication of PCPP-coated microneedles exhibited strong dependence on protein-PCPP interactions in solutions and allowed for high efficiency of protein encapsulation. 70°C thermal inactivation studies demonstrated a remarkable increase in functional stability of protein in coated microneedles compared to solution formulation. A potential for modulation of protein release from coated microneedles has been demonstrated through ionic complexation of PCPP with small ions. CONCLUSIONS: Microneedles containing PCPP coatings provide improved protein stability, modulated release, and protein-friendly microfabrication process.

PCPP-formulated H5N1 influenza vaccine displays improved stability and dose-sparing effect in lethal challenge studies.

The potential impact of an influenza pandemic can be mitigated through the realization of a successful vaccination program. The implementation of antigen stabilization and dose-sparing technologies is an important step in improving availability of vaccines at the time of a pandemic outbreak. We investigated poly[di(carboxylatophenoxy)phosphazene] (PCPP) as a potential stabilizing and immunostimulating agent for H5N1 influenza vaccine. Physicochemical characterization of PCPP-formulated H5N1 influenza vaccine revealed macromolecular complexation in the system, whereas single radial immunodiffusion assay verified antigenicity of the formulation in vitro. PCPP-enhanced formulation displayed a fourfold increase in the half-life at 40°C compared with a nonadjuvanted vaccine. Lethal challenge studies in ferrets demonstrated 100% protection for low-antigen dose PCPP-adjuvanted formulations (1 µg of hemagglutinin) and at least a 10-fold antigen-sparing effect. Therefore, PCPP demonstrated an ability to improve thermal stability of H5N1 influenza vaccine in solutions and provide for a substantial dose-sparing effect in vivo.

Effect of environmental factors on hydrolytic degradation of water-soluble polyphosphazene polyelectrolyte in aqueous solutions.

Degradation of a water-soluble polyphosphazene, poly[di(carboxylatophenoxy)phosphazene], disodium salt (PCPP) has been studied in aqueous solutions at elevated temperature. This synthetic polyelectrolyte is of interest as vaccine adjuvant and its degradability constitutes an important component of its safety and formulation stability profiles. The degradation process is manifested by a gradual reduction in the molecular weight of the polymer and cleavage of side groups, which is consistent with previously reported data on hydrolytical breakdown of water-soluble polyphosphazenes. The kinetics of hydrolytical degradation exhibits distinct pH dependence and the process is faster in solutions with lower pH. Remarkably, a number of hydrogen bond forming additives, such as polyethylene glycol and Tween displayed a dramatic accelerating effect on the degradation of PCPP, whereas inorganic salts, such as sodium chloride and potassium chloride, showed a trend for its retardation. The results can be potentially explained on the basis of acid promoted hydrolysis mechanism and macromolecular interactions in the system.

Protein stabilization in aqueous solutions of polyphosphazene polyelectrolyte and non-ionic surfactants.

Applications of polyelectrolytes as pharmaceutical excipients or biologically active agents generated an increased interest in formulations, in which ionic macromolecules share the same milieu with protein drugs or vaccine antigens. Macromolecular interactions, which often take place in such systems, can potentially impact formulation activity and stability. The present article reports that poly[di(carboxylatophenoxy)phosphazene], disodium salt (PCPP), which has been previously shown to be a potent vaccine adjuvant, also displays a strong protein stabilizing effect in aqueous solutions that can be significantly amplified in the presence of nonionic surfactants. The phenomenon is studied in the context of macromolecular interactions in the system and is linked to the formation of PCPP-protein and PCPP-protein-surfactant complexes.

Poly[di(carboxylatophenoxy)phosphazene] is a potent adjuvant for intradermal immunization.

Intradermal immunization using microfabricated needles represents a potentially powerful technology, which can enhance immune responses and provide antigen sparing. Solid vaccine formulations, which can be coated onto microneedle patches suitable for simple administration, can also potentially offer improved shelf-life. However the approach is not fully compatible with many vaccine adjuvants including alum, the most common adjuvant used in the vaccine market globally. Here, we introduce a polyphosphazene immuno adjuvant as a biologically potent and synergistic constituent of microneedle-based intradermal immunization technology. Poly[di(carboxylatophenoxy)phosphazene], PCPP, functions both as a vaccine adjuvant and as a key microfabrication material. When used as part of an intradermal delivery system for hepatitis B surface antigen, PCPP demonstrates superior activity in pigs compared to intramascular administration and significant antigen sparing potential. It also accelerates the microneedle fabrication process and reduces its dependence on the use of surfactants. In this way, PCPP-coated microneedles may enable effective intradermal vaccination from an adjuvanted patch delivery system.