Pharmacokinetic study of dexamethasone disodium phosphate using intravitreal, subconjunctival, and intravenous delivery routes in rabbits.

Dexamethasone is a corticosteroid with proven efficacy for treating both anterior- and posterior-segment ocular diseases. Delivery of drugs to the back of the eye has always been a challenge, with dexamethasone being no exception. There are multiple delivery routes to the retina, with each exhibiting different pharmacokinetics, depending on the drug molecule and specific route of administration.

Enhancement of antibody and cellular immune responses to malaria DNA vaccines by in vivo electroporation.

We evaluated the effectiveness of in vivo electroporation (EP) for the enhancement of immune responses induced by DNA plasmids encoding the pre-erythrocytic Plasmodium yoelii antigens PyCSP and PyHEP17 administered intramuscularly and intradermally to mice. EP resulted in a 16- and 2-fold enhancement of antibody responses to PyCSP and PyHEP17, respectively. Immunization with 5 microg of DNA via EP was equivalent to 50 microg of DNA via conventional needle, thus reducing by 10-fold the required dose to produce a given effect.

Immunogenicity of hybrid DNA vaccines expressing hepatitis B core particles carrying human and simian immunodeficiency virus epitopes in mice and rhesus macaques.

An effective HIV vaccine will likely need to induce broad and potent CTL responses. Epitope-based vaccines offer significant potential for inducing multi-specific CTL, but often require conjugation to T helper epitopes or carrier moieties to induce significant responses. We tested hybrid DNA vaccines encoding one or more HIV or SIV CTL epitopes fused to a hepatitis B core antigen (HBcAg) carrier gene as a means to improve the immunogenicity of epitope-based DNA vaccines.

Effect of delivery parameters on immunization to ovalbumin following intracutaneous administration by a coated microneedle array patch system.

Immunization to the model antigen ovalbumin was investigated using a novel intracutaneous delivery system consisting of antigen-coated microneedle arrays. The influence of the following parameters on the resulting immune responses was investigated: depth of vaccine delivery, dose of vaccine delivered, density of microneedles on the array, and area of application. The immune response was found to be dose dependent, and mostly independent of depth of delivery, density of microneedles, or area of application.

Enhancement of DNA vaccine potency in rhesus macaques by electroporation.

The potency of an HIV DNA vaccine was enhanced in rhesus macaques by in vivo electroporation, as judged by increased onset, magnitude and duration of antibody and cell-mediated immune responses against both components of a combination Gag and Env vaccine. These data demonstrate the utility of the electroporation technology for use in large animals.

Enhancement of the effectiveness of electroporation-augmented cutaneous DNA vaccination by a particulate adjuvant.

DNA vaccines are attracting increased attention due to multiple advantages over conventional vaccines. Attempts to improve these vaccines focus on enhancing DNA delivery and employing novel immunoadjuvants. Electroporation (EP) has emerged as an effective method for delivering DNA vaccines, significantly enhancing humoral and cellular responses.

Increased gene expression and inflammatory cell infiltration caused by electroporation are both important for improving the efficacy of DNA vaccines.

One potential reason for the enhancement of immune responses to DNA vaccines following electroporation is increased gene expression. However, the inflammatory response and accompanying cellular infiltration stimulated by electroporation may also be essential for enhancing immune responses to DNA vaccines. These parameters were investigated in pigs, using different electroporation conditions to induce different levels of gene expression and inflammation.

Accelerated immune response to DNA vaccines.

DNA vaccines offer considerable promise for improvement over conventional vaccines. For the crucial step of delivering DNA vaccines intracellularly, electroporation (EP) has proven to be highly effective. This method has yielded powerful humoral and cellular responses in various species, including nonhuman primates.

Needle-free topical electroporation improves gene expression from plasmids administered in porcine skin.

Electroporation has been shown to increase the potency of DNA vaccines that have demonstrated significant potential in mice. However, there is a need to develop noninvasive or minimally invasive vaccination methods. In pigs, in vivo gene expression was assessed to compare intradermal needle injection to a needle-free dermal BioJect as a means of delivery of plasmids.

Electroporation improves the efficacy of DNA vaccines in large animals.

It is generally recognized that DNA vaccines are often less effective in large animals than in mice. One possible reason for this reduced effectiveness may be transfection efficiency and the low level of expression elicited by plasmid vectors in large animals. A possible way to improve plasmid gene expression in vivo is electroporation.