Stability of lysozyme in aqueous extremolyte solutions during heat shock and accelerated thermal conditions.

The purpose of this study was to investigate the stability of lysozyme in aqueous solutions in the presence of various extremolytes (betaine, hydroxyectoine, trehalose, ectoine, and firoin) under different stress conditions. The stability of lysozyme was determined by Nile red Fluorescence Spectroscopy and a bioactivity assay. During heat shock (10 min at 70°C), betaine, trehalose, ectoin and firoin protected lysozyme against inactivation while hydroxyectoine, did not have a significant effect. During accelerated thermal conditions (4 weeks at 55°C), firoin also acted as a stabilizer. In contrast, betaine, hydroxyectoine, trehalose and ectoine destabilized lysozyme under this condition. These findings surprisingly indicate that some extremolytes can stabilize a protein under certain stress conditions but destabilize the same protein under other stress conditions. Therefore it is suggested that for the screening extremolytes to be used for protein stabilization, an appropriate storage conditions should also be taken into account.

Hepatitis B surface antigen nanoparticles coated with chitosan and trimethyl chitosan: Impact of formulation on physicochemical and immunological characteristics.

Mucosal immunization offers various advantages over parenteral vaccination, but typically requires potent delivery systems and/or adjuvants to result in protective immunity. Here we report on the preparation of trimethylated chitosan (TMC) and chitosan (CHT) nanoparticles (NPs) loaded with hepatitis B surface antigen (HB), by a simple and scalable method. TMC:HB and CHT:HB NPs were prepared by direct coating of antigen by polymer. The impact of buffer, pH and tonicity of the dispersion medium on NPs' polydispersity, zeta potential and association percentage of polymer with antigen was evaluated. Moreover, biological properties of both NPs were addressed in vitro by studying their effect on cell viability, transepithelial electrical resistance (TEER) and dendritic cell (DC) maturation. Finally, immunogenicity was assessed by evaluating IgG, IgG1, IgG2a, IgA titers and sIgA after both mucosal (nasal) as well intramuscular (i.m.) vaccination in a murine model. TMC:HB and CHT:HB NPs, prepared in acetate buffer pH 6.7 of three different tonicities, had comparable size, polydispersity, zeta potential and association percentage. TMC:HB NPs, but not CHT:HB NPs, had a mild negative effect on cell viability and TEER, and a considerable positive effect on DC maturation. After nasal and i.m. immunization, TMC:HB NPs in hypotonic medium and CHT:HB NPs in all media induced higher serum and nasal antibody titers compared with HB solution (P<0.001). After i.m. injection, both TMC:HB and CHT:HB NPs induced higher IgG and IgG2a titers compared with alum adsorbed HB (P<0.001). For CHT:HB NPs, the tonicity of the dispersion medium did not affect the mucosal and systemic immune responses. In conclusion, TMC NPs and CHT NPs are similarly potent mucosal immunoadjuvants for HB. Moreover, both polymers are potent immunoadjuvants for i.m. administered isotonic HB, resulting in higher IgG2a/IgG1 ratios compared with alum adjuvanted HB.

Towards tailored vaccine delivery: needs, challenges and perspectives.

The ideal vaccine is a simple and stable formulation which can be conveniently administered and provides life-long immunity against a given pathogen. The development of such a vaccine, which should trigger broad and strong B-cell and T-cell responses against antigens of the pathogen in question, is highly dependent on tailored vaccine delivery approaches. This review addresses vaccine delivery in its broadest scope. We discuss the needs and challenges in the area of vaccine delivery, including restrictions posed by specific target populations, potentials of dedicated stable formulations and devices, and the use of adjuvants. Moreover, we address the current status and perspectives of vaccine delivery via several routes of administration, including non- or minimally invasive routes. Finally we suggest possible directions for future vaccine delivery research and development.

Dried influenza vaccines: over the counter vaccines.

Since last year influenza pandemic has struck again after 40 years, this is the right moment to discuss the different available formulation options for influenza vaccine. Looking back to the last 4 decades, most vaccines are still formulated as liquid solution. These vaccines have shown a poor stability profile and are limited in their potential route of administration. An ideal solution to these problems can be to convert vaccines into a dry and stable powder formulation. Recently, drying and delivery technologies have shown promising results regarding the vaccine stability. Therefore, in future we can envisage a stable dry influenza vaccine. Also with regard to the route of administration developments are accelerating and the potential of non-invasive administration has been demonstrated.

Preservation of the immunogenicity of dry-powder influenza H5N1 whole inactivated virus vaccine at elevated storage temperatures.

Stockpiling of pre-pandemic influenza vaccines guarantees immediate vaccine availability to counteract an emerging pandemic. Generally, influenza vaccines need to be stored and handled refrigerated to prevent thermal degradation of the antigenic component. Requirement of a cold-chain, however, complicates stockpiling and the logistics of vaccine distribution. We, therefore, investigated the effect of elevated storage temperatures on the immunogenicity of a pre-pandemic influenza A H5N1 whole inactivated virus vaccine. Either suspended in liquid or kept as a freeze-dried powder, vaccines could be stored for 1 year at ambient temperature (20 degrees C) with minimal loss of immunogenicity in mice. Elevation of the storage temperature to 40 degrees C, however, resulted in a significant loss of immunogenic potency within 3 months if vaccines were stored in liquid suspension. In sharp contrast, freeze-dried powder formulations were stable at 40 degrees C for at least 3 months. The presence of inulin or trehalose sugar excipients during freeze-drying of the vaccine proved to be critical to maintain its immunogenic potency during storage, and to preserve the characteristic Th1-type response to whole inactivated virus vaccine. These results indicate that whole inactivated virus vaccines may be stored and handled at room temperature in moderate climate zones for over a year with minimal decline and, if converted to dry-powder, even in hot climate zones for at least 3 months. The increased stability of dry-powder vaccine at 40 degrees C may also point to an extended shelf-life when stored at 4 degrees C. Use of the more stable dry-powder formulation could simplify stockpiling and thereby facilitating successful pandemic intervention.

Intranasal delivery of influenza subunit vaccine formulated with GEM particles as an adjuvant.

Nasal administration of influenza vaccine has the potential to facilitate influenza control and prevention. However, when administered intranasally (i.n.), commercially available inactivated vaccines only generate systemic and mucosal immune responses if strong adjuvants are used, which are often associated with safety problems. We describe the successful use of a safe adjuvant Gram-positive enhancer matrix (GEM) particles derived from the food-grade bacterium Lactococcus lactis for i.n. vaccination with subunit influenza vaccine in mice. It is shown that simple admixing of the vaccine with the GEM particles results in a strongly enhanced immune response. Already after one booster, the i.n. delivered GEM subunit vaccine resulted in hemagglutination inhibition titers in serum at a level equal to the conventional intramuscular (i.m.) route. Moreover, i.n. immunization with GEM subunit vaccine elicited superior mucosal and Th1 skewed immune responses compared to those induced by i.m. and i.n. administered subunit vaccine alone. In conclusion, GEM particles act as a potent adjuvant for i.n. influenza immunization.

Intracellular delivery of the p38 mitogen-activated protein kinase inhibitor SB202190 [4-(4-fluorophenyl)-2-(4-hydroxyphenyl)-5-(4-pyridyl)1H-imidazole] in renal tubular cells: a novel strategy to treat renal fibrosis.

During renal injury, activation of p38 mitogen-activated protein kinase (MAPK) in proximal tubular cells plays an important role in the inflammatory events that eventually lead to renal fibrosis. We hypothesized that local inhibition of p38 within these cells may be an interesting approach for the treatment of renal fibrosis. To effectuate this, we developed a renal-specific conjugate of the p38 inhibitor SB202190 [4-(4-fluorophenyl)-2-(4-hydroxyphenyl)-5-(4-pyridyl)1H-imidazole] and the carrier lysozyme. First, we demonstrated that SB202190 inhibited the expression of albumin-induced proinflammatory (monocyte chemoattractant protein-1) and transforming growth factor (TGF)-beta1-induced profibrotic (procollagen-Ialpha1) genes over 50% in renal tubular cells (normal rat kidney-52E). Next, we conjugated SB202190 via a carbamate linkage to lysozyme. However, this conjugate rapidly released the drug upon incubation in serum. Therefore, we applied a new platinum(II)-based linker approach, the so-called universal linkage system (ULS), which forms a coordinative bond with SB202190. The SB202190-ULS-lysozyme remained stable in serum but released the drug in kidney homogenates. SB202190-ULS-lysozyme accumulated efficiently in renal tubular cells and provided a local drug reservoir during a period of 3 days after a single intravenous injection. Treatment with SB202190-ULS-lysozyme inhibited TGF-beta1-induced gene expression for procollagen-Ialpha1 by 64% in HK-2 cells. Lastly, we evaluated the efficacy of a single dose of the conjugate in the unilateral renal ischemia-reperfusion rat model. A reduction of intrarenal p38 phosphorylation and alpha-smooth muscle actin protein expression was observed 4 days after the ischemia-reperfusion injury. In conclusion, we have developed a novel strategy for local delivery of the p38 MAPK inhibitor SB202190, which may be of use in the treatment of renal fibrosis.

Bioanalysis and pharmacokinetics of the p38 MAPkinase inhibitor SB202190 in rats.

We have developed a sensitive and reproducible high performance liquid chromatography (HPLC)-UV method for the quantification of the p38 MAPkinase inhibitor SB202190 in serum, kidney homogenates and urine samples. Liquid-liquid extraction of SB202190 from the samples was performed using diethylether after adding a derivative of SB202190 as internal standard (I.S.). Chromatography was carried out using a C8 reversed-phase column with an isocratic mobile phase consisting of acetonitrile-water-trifluoroacetic acid (30:70:0.1, v/v/v; pH 2.0). Both drug and I.S. were measured at 350 nm and eluted at 5.0 and 10.6 min, respectively. Peak-height ratios of the drug and the I.S. were used for the quantification of SB202190 from the different matrixes. The limit of quantitation of SB202190 in serum, kidney and urine were 0.25 microg/ml, 1 microg/g and 1 microg/ml, respectively. The average recoveries were 74, 75 and 92% in serum, kidney and urine, respectively. The intra- and inter-day precision (% CV) and accuracy (% bias) were below 15% for all concentrations. The method was successfully applied for a pharmacokinetic study of SB202190 in rats.

Evaluation of the stability of extemporaneously prepared ophthalmic formulation of mitomycin C.

Mitomycin C (MMC) is a cytostatic agent topically used in conjunctival neoplasms, secondary to glaucoma filtering, pterygium, and strabismus surgery to increase the success rate. The topical formulation of MMC for ocular use is always extemporaneously prepared. Our study evaluated the stability of extemporaneously prepared formulations of MMC at different concentrations (150, 300, & 600 microg/mL) kept at different temperatures (25 degrees , 4 degrees , and -70 degrees C) and at different pH range (6, 7, and 8). Aliquots from the above formulations were subjected for quantification of MMC on days 0, 7, 14, 21, and 28 using high-performance liquid chromatography. MMC stored at 25 degrees C for 6 months was also subjected to flow cytometry and compared to freshly prepared MMC. The results indicated that the degradation of MMC is very high in acidic pH at room temperature. Increasing the pH to 7 or 8 and keeping MMC at low temperatures significantly decreased the degradation of MMC. Interestingly, the flow cytometry data revealed that the 6-month-old MMC showed an antiproliferative effect compared to that of freshly prepared MMC. To conclude, the extemporaneously prepared MMC at pH between 7 and 8 and stored in the refrigerator can increase the duration of its stability. However, the antiproliferative study using flow cytometry revealed that degraded MMC retained its activity even after degradation.