Surface Modification of Porous Polyethylene Implants with an Albumin-Based Nanocarrier-Release System.

BACKGROUND: Porous polyethylene (PPE) implants are used for the reconstruction of tissue defects but have a risk of rejection in case of insufficient ingrowth into the host tissue. Various growth factors can promote implant ingrowth, yet a long-term gradient is a prerequisite for the mediation of these effects. As modification of the implant surface with nanocarriers may facilitate a long-term gradient by sustained factor release, implants modified with crosslinked albumin nanocarriers were evaluated in vivo. METHODS: Nanocarriers from murine serum albumin (MSA) were prepared by an inverse miniemulsion technique encapsulating either a low- or high-molar mass fluorescent cargo. PPE implants were subsequently coated with these nanocarriers. In control cohorts, the implant was coated with the homologue non-encapsulated cargo substance by dip coating. Implants were consequently analyzed in vivo using repetitive fluorescence microscopy utilizing the dorsal skinfold chamber in mice for ten days post implantation. RESULTS: Implant-modification with MSA nanocarriers significantly prolonged the presence of the encapsulated small molecules while macromolecules were detectable during the investigated timeframe regardless of the form of application. CONCLUSIONS: Surface modification of PPE implants with MSA nanocarriers results in the alternation of release kinetics especially when small molecular substances are used and therefore allows a prolonged factor release for the promotion of implant integration.

Nanovaccine impact on dendritic cells: transcriptome analysis enables new insights into antigen and adjuvant effects.

Aim: For vaccines the combination between an antigen and adjuvants are both crucially important to trigger an effective immune response in dendritic cells. Innovative adjuvants like resiquimod or muramyldipeptide have their target protein inside the cell. Materials & methods: Up/downregulation and proteome expression was investigated for the adjuvant combination resiquimod and muramyldipeptide in a soluble form versus encapsulated into a nanocarrier. Results: We found that 1225 genes were upregulated after nanocarrier treatment while 478 genes were downregulated. Most prominent were interferon-stimulated genes with more than 25-times higher expression after nanocarrier treatment, for example RSAD2 and ISG15, which were recently found to have antiviral or antitumor effects. Conclusion: Encapsulation gives a more effective upregulation of vaccine-related genes.

Delivering all in one: Antigen-nanocapsule loaded with dual adjuvant yields superadditive effects by DC-directed T cell stimulation.

Therapeutic vaccination is and remains a major challenge, particularly in cancer treatment. In this process, the effective activation of dendritic cells by a combination of distinctly acting adjuvants and an antigen is crucial for success. While most common vaccine formulations lack the efficiency to trigger sufficient T cell responses in a therapeutic tumor treatment, nanovaccines offer unique properties to tackle that challenge. Here, we report the stepwise development of a nanocapsule for vaccination approaches, comprising a shell consisting of antigen and loaded with a superadditive adjuvant combination. In a first initial step, we identified the combination of resiquimod (R848) and muramyl dipeptide (MDP) to have a superadditive stimulatory potential. Particulated in Spermine-modified dextran-nanoparticles, the dual-adjuvant maintains its superadditive character and stimulates murine dendritic cells (DC) stronger than the soluble equivalents. The second step was to evaluate a protein-based nanocapsule as suitable antigen source for the induction of antigen-specific T cell responses. Therefore, the DC-mediated antigen-specific T cell proliferation upon treatment with nanocapsules, whose shell consists of ovalbumin (OVA), was assessed. At least, the superadditive adjuvant combination was encapsulated into OVA-nanocapsules to create the final nanovaccine. Its immunostimulatory potential for DC was extensively tested by measuring the expression of co-stimulatory surface markers, the secretion of pro-inflammatory cytokines and the capability to mediate OVA-specific T cell responses. The developed nanovaccine triggers strong superadditive dendritic cell stimulation and potent antigen-specific CD4+ and CD8+ T cell proliferation. Combined with a high modifiability, an excellent biocompatibility, low cytotoxicity and an enormous loading capacity, the introduced antigen-nanocapsule provides an enormous potential for the effective delivery of superadditive adjuvant combinations, particularly when they target intracellular receptors.

Fully degradable protein nanocarriers by orthogonal photoclick tetrazole-ene chemistry for the encapsulation and release.

The encapsulation of sensitive drugs into nanocarriers retaining their bioactivity and achieving selective release is a challenging topic in current drug delivery design. Established protocols rely on metal-catalyzed or unspecific reactions to build the (mostly synthetic) vehicles which may inhibit the drug's function. Triggered by light, the mild tetrazole-ene cycloaddition enables us to prepare protein nanocarriers (PNCs) preserving at the same time the bioactivity of the sensitive antitumor and antiviral cargo Resiquimod (R848). This catalyst-free reaction was designed to take place at the interface of aqueous nanodroplets in miniemulsion to produce core-shell PNCs with over 90% encapsulation efficiency and no unwanted drug release over storage for several months. Albumins used herein are major constituents of blood and thus ideal biodegradable natural polymers for the production of such nanocarriers. These protein carriers were taken up by dendritic cells and the intracellular drug release by enzymatic degradation of the protein shell material was proven. Together with the thorough colloidal analysis of the PNCs, their stability in human blood plasma and the detailed protein corona composition, these results underline the high potential of such naturally derived drug delivery vehicles.

Polymeric hepatitis C virus non-structural protein 5A nanocapsules induce intrahepatic antigen-specific immune responses.

Targeting antigen combined with adjuvants to hepatic antigen-presenting cells (APCs) is essential for the induction of intrahepatic T cellular immunity controlling and resolving viral infections of the liver. Intravenous injection of antigen-loaded nanoparticles is a promising approach for the delivery of antigens to liver APCs. Accordingly, polymeric nanocapsules (NCs) synthesized exclusively of hepatitis C virus non-structural protein 5A (NS5A) and the adjuvant monophosphoryl lipid A (MPLA) adsorbed to the nanocapsule surface were developed. Aim of the present study was the evaluation of the in vitro and in vivo behavior of MPLA-functionalized NS5A-NCs regarding the interaction with liver dendritic cells (DCs) and the potential to induce intrahepatic immune responses in a mouse model. Maturation of DCs was significantly increased by application of NS5A+MPLA-NCs compared to non-functionalized NS5A-NCs promoting a vigorous expression of CD40, CD80, CD86 and a strong secretion of the Th1-related cytokine IL-12. NS5A-NCs were preferentially deposited in DCs and Kupffer cells residing in the liver after intravenous administration. Immunization with NS5A-NCs induced intrahepatic antigen-specific CD4(+) T cellular immune responses determined by the secretion of IFNγ and IL-2. Furthermore, supplementation with MPLA induced significant levels of NS5A-specific antibodies. The application of polymeric nanocapsules synthesized exclusively out of antigen avoids the risk of unintended side effects caused by additional carrier substances. Functionalization with adjuvants like MPLA and the efficient targeting to liver-resident APCs inherits the potential for application of antigen nanocapsules in further vaccination approaches against pathogens affecting the liver.

MPLA-coated hepatitis B virus surface antigen (HBsAg) nanocapsules induce vigorous T cell responses in cord blood derived human T cells.

Chronic hepatitis B virus (HBV) infection is the most prevalent serious liver infection in the world. A frequent route of infection represents mother-to-child transmission. Efficient control of HBV replication depends on antigen-specific cellular immune response mediated by dendritic cells (DCs). Aim of the present study was to evaluate optimized adjuvant combinations, efficiently maturing monocyte-derived neonatal and adult dendritic cells (moDCs). In addition, the potential of polymeric HBsAg-nanocapsules (HBsAg-NCs) was investigated regarding up-take by moDCs and the subsequent induction of specific T cell responses in a human co-culture model. Simultaneous stimulation of moDCs with MPLA and IFNγ induced up-regulation of CD80 and HLA-DR along with vigorous secretion of IL-12p70. MPLA-coating of HBsAg-NCs promoted NCs-uptake by moDCs. Finally, MPLA-HBsAg-NCs-pulsed moDCs with IFNγ increased T cell proliferation and induced antigen-specific IFNγ release by T cells. The herein presented vaccine approach provides a rational for neonatal and therapeutic immunization strategies against HBV.

Reactions and Polymerizations at the Liquid-Liquid Interface.

Reactions and polymerizations at the interface of two immiscible liquids are reviewed. The confinement of two reactants at the interface to form a new product can be advantageous in terms of improved reaction kinetics, higher yields, and selectivity. The presence of the liquid-liquid interface can accelerate the reaction, or a phase-transfer catalyst is employed to draw the reaction in one phase of choice. Furthermore, the use of immiscible systems, e.g., in emulsions, offers an easy means of efficient product separation and heat dissipation. A general overview on low molecular weight organic chemistry is given, and the applications of heterophase polymerization, occurring at or in proximity of the interface, (mostly) in emulsions are presented. This strategy can be used for the efficient production of nano- and microcarriers for various applications.

Biodegradable protein nanocontainers.

The application of synthetic polymers for drug delivery often requires tremendous efforts to ensure biocompatibility and -degradation. To use the body's own substances can help to overcome these problems. Herein, we present the first synthesis of nanocontainers entirely composed of albumin proteins. These protein nanocontainers (PNCs) were loaded with hydrophilic compounds and release of the payload is triggered through natural lysis in vitro in human monocyte-derived dendritic cells (moDCs). No aggregation of PNCs in human blood plasma was observed, indicating stability for blood circulation. As the PNCs were readily taken up by moDCs, they are considered as a promising delivery platform for vaccination strategies and could minimize the risk of side effects caused by foreign carrier substances.