Tingyuan Yang

Immune responses to vaccines involving a combined antigen–nanoparticle mixture and nanoparticle-encapsulated antigen formulation

Many physicochemical characteristics significantly influence the adjuvant effect of micro/nanoparticles; one critical factor is the kinetics of antigen exposure to the immune system by particle-adjuvanted vaccines. Here, we investigated how various antigen-nanoparticle formulations impacted antigen exposure to the immune system and the resultant antigen-specific immune responses. We formulated antigen with poly(lactic-co-glycolic acid) (PLGA) nanoparticles by encapsulating antigen within nanoparticles or by simply mixing soluble antigen with the nanoparticles. Our results indicated that the combined formulation (composed of antigen encapsulated in nanoparticles and antigen mixed with nanoparticles) induced more powerful antigen-specific immune responses than each single-component formulation. Mice immunized with the combined vaccine formulation displayed enhanced induction of antigen-specific IgG antibodies with high avidity, increased cytokine secretion by splenocytes, and improved generation of memory T cell. Enhanced immune responses elicited by the combined vaccine formulation might be attributed to the antigen-depot effect at the injection site, effective provision of both adequate initial antigen exposure and long-term antigen persistence, and efficient induction of dendritic cell (DC) activation and follicular helper T cell differentiation in draining lymph nodes. Understanding the effect of antigen-nanoparticle formulations on the resultant immune responses might have significant implications for rational vaccine design.

pH-Responsive Poly(D,L-lactic-co-glycolic acid) Nanoparticles with Rapid Antigen Release Behavior Promote Immune Response.

In the quest to treat intracellular infectious diseases and virus infection, nanoparticles (NPs) have been considered to be efficient tools for inducing potent immune responses, specifically cellular immunity. Antigen processing and presenting by antigen presenting cells (APCs) could influence immune response, especially the priming of T-cell-mediated cellular immunity. Here, we fabricated pH-responsive poly(D,L-lactic-co-glycolic acid) (PLGA) NPs with rapid antigen intracellular release behavior in APCs. The NPs, which had thin shells and large inner space, contain ammonium bicarbonate (NH4HCO3), which could regulate release in endosomes and lysosomes, acting as an antigen release promoter in dendritic cells (DCs), and were coencapsulated with antigen (ovalbumin, OVA). Hydrogen ions (H(+)) in DC endosomes and lysosomes (pH ∼5.0 and 6.5) could react with NH4HCO3 to generate NH3 and CO2, which broke NPs and released antigens. After uptake by DCs, antigens encapsulated in pH-responsive PLGA NPs could escape from lysosomes into the cytoplasm and be cross-presented. Moreover, the NPs induced up-regulation of co-stimulatory molecules and stimulated cytokine production. Mouse immunization with pH-responsive PLGA NPs induced greater lymphocyte activation, more antigen-specific CD8(+) T cells, stronger cytotoxic capacity (IFN-γ and granzyme B), enhanced antigen-specific IgG antibodies, and higher serum IgG2a/IgG1, indicating cellular immunity. The NPs also improved generation of memory T cells to protect against reinfection. Thus, pH-responsive PLGA NPs, which induced strong cellular immune responses and offered antibody protection, could be potentially useful as effective vaccine delivery and adjuvant systems for the therapy of intracellular infectious diseases and virus infection.

POROUS QUATERNIZED CHITOSAN NANOPARTICLES CONTAINING PACLITAXEL NANOCRYSTALS IMPROVED THERAPEUTIC EFFICACY IN NON-SMALL-CELL LUNG CANCER AFTER ORAL ADMINISTRATION

Clinical application of paclitaxel (PTX) is limited because of its poor solubility in aqueous media. To overcome this hurdle, we devised an oral delivery system by encapsulating PTX into N-((2-hydroxy-3-trimethylammonium) propyl) chitosan chloride (HTCC) nanoparticles. These nanoparticles were small (~130 nm), had a narrow size distribution, and displayed high loading efficiency owing to the homogeneous distribution of PTX nanocrystals. The matrix hydrophilicity and porous structure of the obtained nanoparticles accelerated their degradation and improved drug release. In vitro and in vivo transport experiments had proved that the presence of positive charges enhanced the intestinal permeability of these nanoparticles. Further in vitro experiment of cytotoxicity showed that the PTX-loaded HTCC nanoparticle (HTCC-NP:PTX) was more effective than native PTX owing to enhanced cellular uptake. Drug distribution in tissues and in vivo imaging studies confirmed the preferred accumulation of HTCC-NP:PTX in subcutaneous tumor tissue. Subsequent tumor xenograft assays demonstrated the promising therapeutic effect of HTCC-NP:PTX on inhibition of tumor growth and induction of apoptosis in tumor cells. Additional investigation into side effects revealed that HTCC-NP:PTX caused lower Cremophor EL-associated toxicities compared with Taxol. These results strongly supported the notion that HTCC nanoparticle (HTCC-NP) is a promising candidate as an oral carrier of PTX for cancer therapy.

Preparation of uniform-sized exenatide-loaded PLGA microspheres as long-effective release system with high encapsulation efficiency and bio-stability

Exenatide-loaded poly(d,l-lactic-co-glycolic acid) (PLGA) microspheres hold great potential as a drug delivery system to treat type 2 diabetes mellitus (T2DM) because they can overcome the shortcoming of exenatides short half-life and realize sustained efficacy. However, conventional preparation methods often lead to microspheres with a broad size distribution, which in turn would cause poor preparation repeatability, drug efficacy and so forth. In this study, we used Shirasu Porous Glass (SPG) premix membrane emulsification technique characterized with high trans-membrane flux and size controllability to prepare uniform-sized PLGA microspheres. By optimizing trans-membrane pressure and PVA concentration in external aqueous phase, uniform-sized PLGA microspheres with large size (around 20μm) were successfully obtained. To achieve high encapsulation efficiency (EE) and improve in vitro release behavior, we have carefully examined the process parameters. Our results show that using ultrasonication to form primary emulsion, microspheres with high EE were easily obtained, but the rate of in vitro release was very slow. Instead, high EE and appropriate in vitro release were achieved when homogenization with optimized time and speed were employed. Besides, we also systematically investigated the effect of formulations on loading efficiency (LE) as well as the relationship between the resultant size of the microspheres and pore size of the membrane. Finally, through RP-HPLC and CD spectra analysis, we have demonstrated that the bio-stability of exenatide in microspheres was preserved during the preparation process.

M-cell targeted polymeric lipid nanoparticles containing a toll-like receptor agonist to boost oral immunity

Oral delivery of antigens is patient-friendly and efficient way of treating intestinal infections. However, the efficacy of oral vaccines is limited by degradation in the gastrointestinal (GI) tract and poor absorption by enterocytes and antigen-presenting cells (APC). Here we report ulex europaeus agglutinin-1 (UEA-1) conjugated poly (D,L-lactide-co-glycolide) (PLGA)-lipid nanoparticles (NP) containing a Toll-like receptor (TLR)-agonist monophosphoryl lipid A (MPL) as an oral vaccine delivery system. The uniform-sized PLGA-lipid NPs (simplified as lipid NPs) were produced by the premix membrane emulsification method. They can protect the entrapped model antigen ovalbumin (OVA) from exposure to the GI tract and release the OVA in a controlled manner. With UEA-1 and MPL modification, the UEA-MPL/lipid NPs can be effectively transported by M-cells and captured by mucosal dendritic cells (DCs). After in vivo vaccination, the OVA-UEA-MPL/lipid NPs stimulated the most effective mucosal IgA and serum IgG antibodies during the oral formulations. These results suggest that this MPL containing M-cell targeted lipid NP can potentially be used as a universally robust oral vaccine delivery system.

Mechanistic studies for monodisperse exenatide-loaded PLGA microspheres prepared by different methods based on SPG membrane emulsification

Poly(DL-lactic-co-glycolic acid) (PLGA) microspheres have been widely prepared by many methods, including solvent evaporation, solvent extraction and the co-solvent method. However, very few studies have compared the properties of microspheres fabricated by these methods. This is partly because the broad size distribution of the resultant particles severely complicates the analysis and affects the reliability of the comparison. To this end, uniform-sized PLGA microspheres have been prepared by Shirasu porous glass premix membrane emulsification and used to encapsulate exenatide, a drug for treating Type 2 diabetes. Based on this technique, the influences on the properties of microspheres fabricated by the aforementioned three methods were intensively investigated, including in vitro release, degradation and pharmacology. We found that these microspheres presented totally different release behaviors in vitro and in vivo, but exhibited a similar trend of PLGA degradation. Moreover, the internal structural evolution visually demonstrated these release behaviors. We selected for further examination the microsphere prepared by solvent evaporation because of its constant release rate, and explored its pharmacodynamics, histology, etc., in more detail. This microsphere when injected once showed equivalent efficacy to that of twice-daily injections of exenatide with no inflammatory response.

Comparison of PLA Microparticles and Alum as Adjuvants for H5N1 Influenza Split Vaccine: Adjuvanticity Evaluation and Preliminary Action Mode Analysis

PurposeTo compare the adjuvanticity of polymeric particles (new-generation adjuvant) and alum (the traditional and FDA-approved adjuvant) for H5N1 influenza split vaccine, and to investigate respective action mode.MethodsVaccine formulations were prepared by incubating lyophilized poly(lactic acid) (PLA) microparticles or alum within antigen solution. Antigen-specific immune responses in mice were evaluated using ELISA, ELISpot, and flow cytometry assay. Adjuvants’ action modes were investigated by determining antigen persistence at injection sites, local inflammation response, antigen transport into draining lymph node, and activation of DCs in secondary lymphoid organs (SLOs).ResultsAlum promoted antigen-specific humoral immune response. PLA microparticles augmented both humoral immune response and cell-mediated-immunity which might enhance cross-protection of influenza vaccine. With regard to action mode, alum adjuvant functions by improving antigen persistence at injection sites, inducing severe local inflammation, slightly improving antigen transport into draining lymph nodes, and improving the expression of MHC II on DCs in SLOs. PLA microparticles function by slightly improving antigen transport into draining lymph nodes, and promoting the expression of both MHC molecules and co-stimulatory molecules on DCs in SLOs.ConclusionsConsidering the adjuvanticity and side effects (local inflammation) of both adjuvants, we conclude that PLA microparticles are promising alternative adjuvant for H5N1 influenza split vaccine.

Microspheres and Microcapsules for Protein Delivery: Strategies of Drug Activity Retention

With the recent progress in biotechnology and genetic engineering, a variety of proteins have formed a very important class of therapeutic agents. However, most proteins have short half-lives in vivo requiring multiple treatments to provide efficacy. In order to overcome this limitation, sustained release systems as hydrophilic microspheres and hydrophobic microcapsules have received extensive attention in recent years. As therapeutic proteins delivery systems, it is necessary to maintain protein bioactivity during microspheres or microcapsules formation as much as possible. This paper reviews different influencing factors that are closely involved in protein denaturation during the preparation of hydrophilic polymer microspheres and hydrophobic polymer microcapsules. The various strategies usually employed for overcoming these obstacles are described in detail. Both processing and formulation parameters can be modified for improving protein stability. The maximum or full protein stability retention within the microspheres or microcapsules might be achieved by individual or combined optimized strategies. In addition, the common techniques for proteins stability determination are also briefly reviewed.

Cellulose-graft-poly(L-lactic acid) nanoparticles for efficient delivery of anti-cancer drugs

Cellulose based carriers have the potential for sustained release of drugs, which can protect drugs and deliver them to the target site. Herein, BA-loaded cellulose-graft-poly(l-lactic acid) nanoparticles (CE-g-PLLA/BA NPs) were fabricated by employing cellulose (CE) and poly(l-lactic acid) (PLLA) as materials and betulinic acid (BA) as a model drug. Both drug-free and BA-loaded nanoparticles were spherical in shape with a uniform size of 100-170 nm. The release of BA from CE-g-PLLA/BA NPs was relatively slow. In vitro cytotoxicity studies with A549 and LLC cell lines suggested that CE-g-PLLA/BA NPs were slightly superior to BA in antitumor activity and CE-g-PLLA NPs were non-toxic. The antitumor effect of the CE-g-PLLA/BA NPs in a mouse tumor xenograft model exhibited much better tumor inhibition efficacy and fewer side effects than that of BA, strongly supporting their use as efficient carriers for anti-cancer therapy.

Pathogen-Mimicking Polymeric Nanoparticles based on Dopamine Polymerization as Vaccines Adjuvants Induce Robust Humoral and Cellular Immune Responses.

Aiming to enhance the immunogenicity of subunit vaccines, a novel antigen delivery and adjuvant system based on dopamine polymerization on the surface of poly(D,L-lactic-glycolic-acid) nanoparticles (NPs) with multiple mechanisms of immunity enhancement is developed. The mussel-inspired biomimetic polydopamine (pD) not only serves as a coating to NPs but also functionalizes NP surfaces. The method is facile and mild including simple incubation of the preformed NPs in the weak alkaline dopamine solution, and incorporation of hepatitis B surface antigen and TLR9 agonist unmethylated cytosine-guanine (CpG) motif with the pD surface. The as-constructed NPs possess pathogen-mimicking manners owing to their size, shape, and surface molecular immune-activating properties given by CpG. The biocompatibility and biosafety of these pathogen-mimicking NPs are confirmed using bone marrow-derived dendritic cells. Pathogen-mimicking NPs hold great potential as vaccine delivery and adjuvant system due to their ability to: 1) enhance cytokine secretion and immune cell recruitment at the injection site; 2) significantly activate and maturate dendritic cells; 3) induce stronger humoral and cellular immune responses in vivo. Furthermore, this simple and versatile dopamine polymerization method can be applicable to endow NPs with characteristics to mimic pathogen structure and function, and manipulate NPs for the generation of efficacious vaccine adjuvants.