Enhancement of subunit vaccine delivery with zinc-carnosine coordination polymer through the addition of mannan.

Vaccines represent a pivotal health advancement for preventing infection. However, because carrier systems with repeated administration can invoke carrier-targeted immune responses that diminish subsequent immune responses (e.g., PEG antibodies), there is a continual need to develop novel vaccine platforms. Zinc carnosine microparticles (ZnCar MPs), which are composed of a one-dimensional coordination polymer formed between carnosine and the metal ion zinc, have exhibited efficacy in inducing an immune response against influenza. However, ZnCar MPs' limited suspendability hinders clinical application. In this study, we address this issue by mixing mannan, a polysaccharide derived from yeast, with ZnCar MPs. We show that the addition of mannan increases the suspendability of this promising vaccine formulation. Additionally, since mannan is an adjuvant, we illustrate that the addition of mannan increases the antibody response and T cell response when mixed with ZnCar MPs. Mice vaccinated with mannan + OVA/ZnCar MPs had elevated serum IgG and IgG1 levels in comparison to vaccination without mannan. Moreover, in the mannan + OVA/ZnCar MPs vaccinated group, mucosal washes demonstrated increased IgG, IgG1, and IgG2c titers, and antigen recall assays showed enhanced IFN-γ production in response to MHC-I and MHC-II immunodominant peptide restimulation, compared to the vaccination without mannan. These findings suggest that the use of mannan mixed with ZnCar MPs holds potential for subunit vaccination and its improved suspendability further promotes clinical translation.

Zinc Carnosine Metal-Organic Coordination Polymer as a Potent Broadly Active Influenza Vaccine Platform with In Vitro Shelf-Stability.

Current seasonal influenza vaccines are limited in that they need to be reformulated every year in order to account for the constant mutation of the virus. Hemagglutinin (HA) immunogens have been developed using a computationally optimized broadly reactive antigen (COBRA) methodology, which are able to elicit an antibody response that neutralizes antigenically distinct influenza strains; however, subunit proteins are not immunogenic enough on their own to generate a substantial immune response. Due to this, different delivery strategies and adjuvants can be used to improve immunogenicity. Recently, we reported a new coordination polymer composed of the dipeptide carnosine and zinc (ZnCar) that is able to deliver protein antigens along with CpG to generate a potent immune response. In the present work, ZnCar was used to deliver the COBRA HA immunogen Y2 and the adjuvant CpG. We incorporated Y2 into ZnCar using two different methods to assess which would be the most immunogenic. Mice vaccinated with Y2 and CpG complexed with ZnCar showed an improved humoral and cellular response when compared to mice vaccinated with soluble Y2 and CpG. Further, we demonstrate in vitro that when Y2 and CpG are coordinated with ZnCar, they are protected from degradation at 40 °C for 3 months or 24 °C for 6 months. Overall, ZnCar shows promise as a delivery vehicle for subunit vaccines, given its superior immunogenicity and in vitro storage stability.

Metal-Organic Coordination Polymer for Delivery of a Subunit Broadly Acting Influenza Vaccine.

A zinc-carnosine (ZnCar) metal-organic coordination polymer was fabricated in biologically relevant N-(2-hydroxyethyl)piperazine-N'-ethanesulfonic acid (HEPES) buffer for use as a vaccine platform. In vitro, ZnCar exhibited significantly less cytotoxicity than a well-established zeolitic imidazolate framework (ZIF-8). Adsorption of CpG on the ZnCar surface resulted in enhanced innate immune activation compared to soluble CpG. The model antigen ovalbumin (OVA) was encapsulated in ZnCar and exhibited acid-sensitive release in vitro. When injected intramuscularly on days 0 and 21 in C57BL/6 mice, OVA-specific serum total IgG and IgG1 were significantly greater in all groups with ZnCar and antigen compared to soluble controls. Th1-skewed IgG2c antibodies were significantly greater in OVA and CpG groups delivered with ZnCar for all time points, regardless of whether the antigen and adjuvant were co-formulated in one material or co-delivered in separate materials. When broadly acting Computationally Optimized Broadly Reactive Antigen (COBRA) P1 influenza hemagglutinin (HA) was ligated to ZnCar via its His-tag, significantly greater antibody levels were observed at all time points compared to soluble antigen and CpG. ZnCar-formulated antigen elicited increased peptide presentation to B3Z T cells in vitro and production of IL-2 after ex vivo antigen recall of splenocytes isolated from vaccinated mice. Overall, this work displays the formation of a zinc-carnosine metal-organic coordination polymer that can be applied as a platform for recombinant protein-based vaccines.

Microparticles formulated from a family of novel silylated polysaccharides demonstrate inherent immunostimulatory properties and tunable hydrolytic degradability.

Acid-degradable polymers are well-suited for use as drug delivery vehicles because numerous physiological sites (e.g., intracellular endocytic pathway) are acidic. Here we report the synthesis of acid-sensitive silylated polysaccharides derived from either dextran or inulin with various alkyl substitutions on the silicon center: trimethylsilyl dextran (TMS-DEX), ethyldimethylsilyl dextran (EDMS-DEX), triethylsilyl dextran (TES-DEX), and trimethylsilyl inulin (TMS-IN). The silylated dextran (Silyl-DEX) and silylated inulin (Silyl-IN) polymers were fabricated into microparticles (MPs) via emulsification followed by solvent evaporation. These MPs were relatively stable at extracellular pH 7.4 and displayed a wide range of pH 2.0 and 5.0 degradation half-lives (fifteen minutes to greater than nine days) that were dependent on the extent of silylation (40 to 98%) and steric crowding on the silicon center (trimethyl to ethyldimethyl to triethyl). Silyl-DEX and Silyl-IN MPs exhibited cytocompatibility when cultured in vitro with RAW 264.7 macrophages. TES-DEX and TMS-IN MPs, composed of highly hydrophobic moieties and the parent immunostimulatory inulin, respectively, elicited substantial in vitro production of tumor necrosis factor alpha, a cytokine associated with an innate immune response. In vivo immunization with a model ovalbumin antigen encapsulated in silylated polysaccharide MPs, without a separate adjuvant, resulted in a dual humoral and cellular response that was superior to an alum-adjuvanted formulation. Overall, we present Silyl-DEX and Silyl-IN as members of the acid-degradable polymer family for potential use in subunit vaccines and other drug delivery applications.

A Novel Sterol Isolated from a Plant Used by Mayan Traditional Healers Is Effective in Treatment of Visceral Leishmaniasis Caused by Leishmania donovani.

Visceral leishmaniasis (VL), caused by the protozoan parasite Leishmania donovani, is a global health problem affecting millions of people worldwide. Treatment of VL largely depends on therapeutic drugs such as pentavalent antimonials, amphotericin B, and others, which have major drawbacks due to drug resistance, toxicity, and high cost. In this study, for the first time, we have successfully demonstrated the synthesis and antileishmanial activity of the novel sterol pentalinonsterol (PEN), which occurs naturally in the root of a Mexican medicinal plant, Pentalinon andrieuxii. In the experimental BALB/c mouse model of VL induced by infection with L. donovani, intravenous treatment with liposome-encapsulated PEN (2.5 mg/kg) led to a significant reduction in parasite burden in the liver and spleen. Furthermore, infected mice treated with liposomal PEN showed a strong host-protective TH1 immune response characterized by IFN-γ production and formation of matured hepatic granulomas. These results indicate that PEN could be developed as a novel drug against VL.

Microfabricated devices for enhanced bioadhesive drug delivery: attachment to and small-molecule release through a cell monolayer under flow.

The development of a novel microfabricated device for oral drug delivery that overcomes many of the common barriers present in the gastrointestinal tract is reported. Specifically, the attachment of targeting ligands, subsequent device binding, and small molecule release from the microdevices in flow are investigated. A diffusion chamber that permits the simultaneous study of particle binding and small-molecule release under physiologically relevant shear conditions is developed. It is observed that once the particles bind to the cell surface, they remain attached. A small fraction of the devices detach in flow; however, most of these devices readily reattach to the cell layer in a new location. This steady-state density of microdevices is most likely the result of larger order microdevice clusters releasing their loose interactions with nearby microdevices, shifting slightly downstream, and subsequently reattaching to the cell monolayer. The release of a model small molecule from microdevices over time is roughly linear and approximately ten times greater than that observed with the small molecule alone. Overall, the preparation and characterization of an oral drug-delivery microdevice system capable of both targeting and asymmetric release in flow is reported.