In vitro effects of CpG oligodeoxynucleotides delivered by gelatin nanoparticles on canine peripheral blood mononuclear cells of atopic and healthy dogs - a pilot study.

BACKGROUND: Cytosine-phosphate-guanine (CpG) oligodeoxynucleotides offer a novel promising immunotherapeutic approach for atopic dermatitis (AD) both in humans and animals. Gelatin nanoparticles (GNP) enhance and prolong CpG-associated immunomodulatory effects and minimize adverse effects both in vitro and in vivo. Information about the effects of this combination in dogs is lacking. HYPOTHESIS/OBJECTIVES: The aim of this study was to evaluate immunological effects of CpG coupled to GNP on canine peripheral blood mononuclear cells (PBMCs) in vitro. ANIMALS: Eight dogs with AD, diagnosed by standard criteria and with a concurrent immediate hypersensitivity to house dust mites were included. Control samples were taken from eight healthy, age-matched control dogs without history or evidence of cutaneous or systemic illness. METHODS: Peripheral blood mononuclear cells of healthy and allergic dogs were incubated with CpG-GNP and the uptake of CpG-GNP was demonstrated using confocal laser scanning microscopy. Cell culture supernatant concentrations of interferon gamma (IFN-γ), interleukin (IL)-4, IL-6 and IL-10 were measured by Canine Cytokine Milliplex. RESULTS: No significant changes in IFN-γ and IL-4 were found when comparing PBMCs incubated with CpG and CpG-GNP with the negative controls in atopic and healthy dogs. Interleukin-6 was not detected in any of the groups. However, a statistically significant increase in IL-10 concentration was found after 24 h stimulation with CpG-GNP compared with CpG alone both in atopic and healthy dogs. CONCLUSIONS AND CLINICAL IMPORTANCE: As IL-10 is considered an immunosuppressive cytokine playing a key role in peripheral tolerance; the reported CpG-GNP formulation could be a new approach in allergy treatment.

Towards an inhalative in vivo application of immunomodulating gelatin nanoparticles in horse-related preformulation studies.

Delivering active ingredients using biocompatible and biodegradable carriers such as gelatin nanoparticles (GNPs) to the lung constitutes a promising non-invasive route of administration. However, the pulmonary delivery of nanoparticle-based immunotherapy is still a field that requires more clarification. In this study, GNPs loaded with cytosine-phosphate-guanine oligodeoxynucleotides (CpG-ODN)-loaded and plain GNPs were aerosolised either by a conventional pressured metered dose inhaler (pMDI) or by active or passive vibrating-mesh (VM) nebulisers. GNP sizes after nebulisation by active and passive VM nebulisers were 248.2 ± 7.34 and 222.3 ± 1.42 nm, respectively. GNP concentrations after aerosolisation were found consistent and second-stage particle deposition in an impinger was up to 65.68 ± 11.2% of the nebulised dose. VM nebulisers produced high fine particle fractions, while pMDIs did not. Nebulised CpG-ODN-loaded GNPs remained capable to stimulate IL-10 release (225.2 ± 56.3 pg/ml) in vitro from equine alveolar lymphocytes. Thus, a novel system for pulmonary GNP-mediated immunotherapy in vivo was established.

A nebulized gelatin nanoparticle-based CpG formulation is effective in immunotherapy of allergic horses.

PURPOSE: In the recent years, nanotechnology has boosted the development of potential drug delivery systems and material engineering on nanoscale basis in order to increase drug specificity and reduce side effects. A potential delivery system for immunostimulating agents such as cytosine-phosphate-guanine-oligodeoxynucleotides (CpG-ODN) needs to be developed to maximize the efficacy of immunotherapy against hypersensitivity. In this study, an aerosol formulation of biodegradable, biocompatible and nontoxic gelatin nanoparticle-bound CpG-ODN 2216 was used to treat equine recurrent airway obstruction in a clinical study. METHODS: Bronchoalveolar lavage fluid was obtained from healthy and allergic horses to quantify Th1/Th2 cytokine levels before and after inhalation regimen. Full clinical examinations were performed to evaluate the therapeutic potential of this nebulized gelatin nanoparticle-based CpG formulation. RESULTS: Most remarkable was that regulatory anti-inflammatory and anti-allergic cytokine IL-10 expression was significantly triggered by five consecutive inhalations. Thorough assessment of clinical parameters following nanoparticle treatment indicated a partial remission of the allergic condition. CONCLUSION: Thus this study, for the first time, showed effectiveness of colloidal nanocarrier-mediated immunotherapy in food-producing animals with potential future applicability to other species including humans.

Immunostimulation of bronchoalveolar lavage cells from recurrent airway obstruction-affected horses by different CpG-classes bound to gelatin nanoparticles.

Recurrent airway obstruction (RAO) in horses has become a common problem in stabled horses in industrialized countries and deserves new therapeutic strategies. CpG-oligodeoxynucleotides (CpG-ODNs) were developed as effective immunostimulating agents to induce a Th2/Th1 shift. These agents showed a beneficial therapeutic effect in allergic diseases with predominant Th2 immunoresponse. CpG-ODN delivery by gelatin nanoparticles (GNPs) resulted in enhanced cellular uptake in murine and human in vitro studies and was a starting point for the present trial. The aim of this study was to identify an optimal stimulating CpG motif in horses with regard to species specificity on equine bronchoalveolar lavage (BAL) cells, in terms of a possible specific immunomodulation effect (Th2/Th1 shift) by used CpG-ODN. Accordingly, GNPs were evaluated as a delivery system to improve CpG-ODN immunostimulation in equine BAL cells. BAL fluid (BALF) was obtained from seven horses with moderate RAO and from four healthy horses and was subsequently incubated with five different CpG-ODN sequences (from A-, B- and C-class) and one ODN without any CpG motif. Release of three key cytokines (IL-4, IL-10 and IFN-γ) was quantified by ELISA to detect an allergy mediated Th2 immunoresponse (IL-4) as well as a proinflammatory Th1 response (IFN-γ). Due to its specific anti-inflammatory and anti-allergic effects, IL-10 was considered as a beneficial agent in pathophysiology of RAO. Results showed a significant upregulation of IL-10 and IFN-γ on the one hand and a downregulation of IL-4 on the other hand in RAO affected horses. Cell cultures from healthy horses had a significantly stronger response in cytokine release to all the applied stimuli in contrast to RAO derived cells. Comparing all five CpG sequences, A-class 2216 significantly showed the highest immunomodulatory effects on equine BALF cells and, hence, was chosen for follow-up preliminary clinical studies.

Delivery of immunostimulatory RNA oligonucleotides by gelatin nanoparticles triggers an efficient antitumoral response.

RNA oligonucleotides have emerged as a new class of biologicals that can silence gene expression but also stimulate immune responses through specific pattern-recognition receptors. The development of effective delivery systems remains a major challenge for the therapeutic application of the RNA oligonucleotides. In this study, we have established a novel biodegradable carrier system that is highly effective for the delivery of immunostimulatory RNA oligonucleotides. Formulation of RNA oligonucleotides with cationized gelatin nanoparticles potentiates immune activation through the Toll-like receptor 7 (TLR7) in both myeloid and plasmacytoid dendritic cells. Further, nanoparticle-delivered RNA oligonucleotides trigger production of the antitumoral cytokines IL-12 and IFN-α. Binding to gelatin nanoparticles protects RNA oligonucleotides from degradation by nucleases, facilitates their uptake by dendritic cells, and targets these nucleic acids to the endosomal compartment in which they are recognized by TLR7. In these effects, the nanoparticles are superior to the conventional transfection reagents lipofectamine, polyethylenimine, and DOTAP. In vivo, the delivery of TLR7-activating RNA oligonucleotides by gelatin nanoparticles triggers antigen-specific CD8+ T-cell and antibody responses. Indeed, immunization with RNA-loaded nanoparticles leads to an efficient antitumoral immune response in two different mouse tumor models. Thus, gelatin-based nanoparticles represent a novel delivery system for immunostimulatory RNA oligonucleotides that is both effective and nontoxic.

New doxorubicin-loaded phospholipid microbubbles for targeted tumor therapy: in-vivo characterization.

Doxorubicin(DOX) is a potent chemotherapy drug that is often limited by severe adverse effects such as cardiac toxicity and myelosupression. Drug targeting with non invasive techniques would be desirable, aiming at increased local drug concentration and reduced systemic side effects. Ultrasound(US) targeted destruction of drug loaded microbubbles(MBs) has evolved as a promising strategy for non invasive local gene and drug delivery. A recently developed novel DOX-loaded microbubble (DOX-MB) formulation was previously tested in-vitro, with optimal DOX loading capacity, ideal physical characteristics and preserved antiproliferative efficacy. The aim of this study was to evaluate applicability and efficacy of DOX-loaded MBs in a pancreas carcinoma model of the rat. First, immediate toxicity was tested in rats ruling out in-vivo MB agglomeration/capillary adhesion with subsequent embolisation/occlusion of the pulmonary vasculature. In a second set of experiments, tumors derived from pancreas carcinomas were implanted in both flanks of Lewis rats. After establishing the tumors, DOX-MBs were administered intravenously while one of the two tumors was exposed to US (1.3 MHz; mechanical index 1.6). DOX tissue concentration was measured in tumors and control organs after the experiment. Finally, efficacy of US targeted destruction of DOX-MBs in tumors was studied, looking at tumor growth after two therapeutic applications. All rats survived the DOX-MB administration without any sign of embolisation/occlusion of the pulmonary vasculature. US targeted destruction of DOX-MBs leads to a 12-fold higher tissue concentration of DOX and a significantly lower tumor growth in the target tumor compared to the contralateral control tumor. In conclusion, novel DOX-loaded MBs can be safely administered to rats, leading to a relevant increase in local drug concentration and reduction in tumor growth.

Ultrasonic resonator technology as a new quality control method evaluating gelatin nanoparticles.

Nanomedicine is a quickly evolving field where more and more possible applications become evident and start entering clinical trials or even the market. However, the analytic methods are not always able to keep pace with the new formulations' demands. One example of a promising medical implementation is oligodeoxynucleotide (ODN) delivery by gelatin nanoparticles (GNPs). Currently, quality control is dependent on either some time consuming or destructive spectrometric, chromatographic or electrophoretic methods. A possible enlargement of the portfolio by Ultrasonic Resonator Technology (URT) is investigated here by subjecting plain GNPs in various sizes and concentrations as well as ODN-loaded GNPs to URT analysis. If calibrated by photon correlation spectroscopy (PCS) and other spectroscopy methods for each single nanoparticle system parameter, URT is an efficient and non-destructive technique and serves as a broad characterization method. URT is emphasized to play a possible future part in the size, concentration and ODN loading monitoring, e.g. of gelatin nanoparticles in the course of formulation development.

Matrix-loaded biodegradable gelatin nanoparticles as new approach to improve drug loading and delivery.

The long-term objective of this study is to develop a nanoparticulate formulation based on gelatin or its admixtures with other polyelectrolytes, under very gentle nanoprecipitation conditions, for the delivery of fragile macromolecules such as proteins and peptide drugs. However, the objective of the present study was to achieve drug loading into the matrices of gelatin-based nanoparticles through incubation of the drug-gelatin solution prior to formation and cross-linking of the nanoparticles in situ. Two molecular weight types (4 kDa and 20 kDa) of fluorescein isothiocyanate dextran (FITC-D) were used as surrogate macromolecules to study the loading and in vitro release behavior of gelatin nanoparticles. Unloaded and FITC-D-loaded gelatin nanoparticles were prepared by the one-step desolvation technique using ethanol-water mixture as the non-solvent. The preparation method was optimized with respect to the amount of cross-linking agent and cross-linking time. The nanoparticles formed were further characterized for mean size, size distribution and zeta potential using a Zetasizer nano while the morphology of the particles was evaluated by scanning electron microscopy (SEM). For cell uptake studies, FITC-D-labeled nanoparticles were incubated with Caco-2 cell monolayers and then evaluated using fluorescence microscopy. Results obtained showed the formation of very smooth and spherical particles with a unimodal distribution. Zeta potential measurements revealed that both the unloaded and FITC-D-loaded nanoparticles had a surface charge of -23.0 mV at pH 7.0. The loading capacity of the nanoparticles was found to be approximately 93.0 microg FITC-D (20 kDa) and 86 microg FITC-D (4 kDa) per milligram gelatin nanoparticles. Up to 16.5% of the 20 kDa FITC-D was loaded on the surface of the nanoparticles while 76.8% was entrapped into the matrices of the particles. For the 4 kDa FITC-D, 10.8% was bound to the surface of the particles while 75.6% was entrapped into the core of the nanoparticles. The release profile of FITC-D from the nanoparticles over a 168-h period showed a low release in phosphate-buffered saline (PBS), pH 7.4 while more than 80% was released after 3h for both types of FITC-D in PBS containing trypsin. Release of the 4 kDa FITC-D from the nanoparticles was generally more rapid than that of the 20 kDa indicating that its entrapment into gelatin nanoparticles was based on weaker interactions when compared to that of the higher molecular weight FITC-D. Bio-imaging using fluorescence microscopy demonstrated uptake and internalization of the nanoparticles, notably into the nucleus and the cytoplasm, by Caco-2 cells.

New doxorubicin-loaded phospholipid microbubbles for targeted tumor therapy: Part I--Formulation development and in-vitro characterization.

Despite high antitumor efficacy and a broad application spectrum, clinical treatment with anthracycline chemotherapeutics is often limited by severe adverse effects such as cardiotoxicity and myelosupression. In recent years, tumor drug targeting has evolved as a promising strategy to increase local drug concentration and reduce systemic side effects. One recent approach for targeting solid tumors is the application of microbubbles, loaded with chemotherapeutic drugs. These advanced drug carriers can be safely administered to the patient by intravenous infusion, and will circulate through the entire vasculature. Their drug load can be locally released by ultrasound targeted microbubble destruction. In addition, tumors can be precisely localized by diagnostic ultrasound since microbubbles act as contrast agents. In the present work a novel microbubble carrier for doxorubicin has been developed and characterized in-vitro. In contrast to many recent tumor-targeting MB designs the newly developed doxorubicin-loaded microbubbles possess a soft but stable phospholipid monolayer shell. Importantly, the active drug is embedded in the microbubble shell and is complexed to the phospholipids by both electrostatic and hydrophobic interactions. Despite their drug load, these novel microbubbles retained all important physical characteristics for ultrasound targeted microbubble destruction, comparable with the commercially available ultrasound contrast agents. In cell culture studies doxorubicin-loaded microbubbles in combination with ultrasound demonstrated an about 3 fold increase of the anti-proliferative activity compared to free doxorubicin and doxorubicin-loaded liposomes. For the first time in the literature the intracellular partition of free doxorubicin and phospholipid-complexed doxorubicin were compared. In conclusion, new doxorubicin-loaded microbubbles with ideal physical characteristics were developed. In-vitro studies show enhanced cytotoxic activity compared to free doxorubicin and doxorubicin-loaded liposomes.

Microbubbles as ultrasound triggered drug carriers.

Originally developed as contrast agents for ultrasound imaging and diagnostics, in the past years, microbubbles have made their way back from the patients' bedside to the researcher's laboratory. Microbubbles are currently believed to have great potential as carriers for drugs, small molecules, nucleic acids, and proteins. This review provides insight into this intriguing new frontier from the perspective of the pharmaceutical scientist. First, basic aspects on the application of ultrasound-targeted microbubble destruction for drug delivery will be presented. Next, we will review the recently applied approaches for manufacturing and drug-loading microbubbles. Important quality issues and characterization techniques for advanced microbubble formulation will be discussed. Finally, we will provide an assessment of the prospects for microbubbles in drug and gene therapy, illustrating the problems and requirements for their future development.

Optimized dispersion of nanoparticles for biological in vitro and in vivo studies.

BACKGROUND: The aim of this study was to establish and validate a practical method to disperse nanoparticles in physiological solutions for biological in vitro and in vivo studies. RESULTS: TiO2 (rutile) dispersions were prepared in distilled water, PBS, or RPMI 1640 cell culture medium. Different ultrasound energies, various dispersion stabilizers (human, bovine, and mouse serum albumin, Tween 80, and mouse serum), various concentrations of stabilizers, and different sequences of preparation steps were applied. The size distribution of dispersed nanoparticles was analyzed by dynamic light scattering and zeta potential was measured using phase analysis light scattering. Nanoparticle size was also verified by transmission electron microscopy. A specific ultrasound energy of 4.2 x 105 kJ/m3 was sufficient to disaggregate TiO2 (rutile) nanoparticles, whereas higher energy input did not further improve size reduction. The optimal sequence was first to sonicate the nanoparticles in water, then to add dispersion stabilizers, and finally to add buffered salt solution to the dispersion. The formation of coarse TiO2 (rutile) agglomerates in PBS or RPMI was prevented by addition of 1.5 mg/ml of human, bovine or mouse serum albumin, or mouse serum. The required concentration of albumin to stabilize the nanoparticle dispersion depended on the concentration of the nanoparticles in the dispersion. TiO2 (rutile) particle dispersions at a concentration lower than 0.2 mg/ml could be stabilized by the addition of 1.5 mg/ml albumin. TiO2 (rutile) particle dispersions prepared by this method were stable for up to at least 1 week. This method was suitable for preparing dispersions without coarse agglomerates (average diameter < 290 nm) from nanosized TiO2 (rutile), ZnO, Ag, SiOx, SWNT, MWNT, and diesel SRM2975 particulate matter. CONCLUSION: The optimized dispersion method presented here appears to be effective and practicable for preparing dispersions of nanoparticles in physiological solutions without creating coarse agglomerates.

Targeting CpG oligonucleotides to the lymph node by nanoparticles elicits efficient antitumoral immunity.

Viral nucleic acids are recognized by specific pattern-recognition receptors of the Toll-like and RIG-I-like receptor families. Synthetic DNA and RNA oligonucleotides can activate the immune system through these receptors and potentiate Ab and CD8 cytotoxic responses to Ags. Systemic application of immunostimulatory oligonucleotides however also results in a generalized, non-Ag-specific stimulation of the immune system. In this study, we have dissociated the induction of an Ag-specific response from the systemic immune activation generally associated with immunostimulatory oligonucleotides. Delivery of CpG oligodeoxynucleotides that bind TLR9 by cationized gelatin-based nanoparticles potentiates the in vivo generation of an Ag-specific cytotoxic T cell and Ab response. Furthermore, immunization with CpG-loaded nanoparticles induces a protective antitumoral response in a murine model of melanoma. The systemic release of proinflammatory cytokines and widespread immunostimulation associated with free CpG is however completely abolished. In addition, we show that gelatin nanoparticle formulation prevents the destruction of lymphoid follicles mediated by CpG. Nanoparticle-delivered CpG, in contrast to free CpG, are selectively targeted to APCs in the lymph nodes where they mediate local immune stimulation. We describe a novel strategy to target immunostimulatory oligonucleotides to the initiation site of the immune response while at the same time protecting from an indiscriminate and generalized activation of the immune system.

Formulation development of freeze-dried oligonucleotide-loaded gelatin nanoparticles.

The freeze-drying properties of gelatin nanoparticles were investigated with the goal of providing practicable nanoparticle formulations for in vitro applications or clinical studies. Various excipients and rehydration protocols were assessed, and gelatin nanoparticles loaded with oligonucleotides were successfully freeze-dried and rehydrated. An NF-kappaB decoy oligonucleotide-loaded gelatin nanoparticle formulation was developed and applied in a drug targeting approach in an animal model. The high concentrations of nanoparticles achieved after rehydration with reduced volumes proved to be critical for the in vivo effect. Finally, short term storage stability under accelerated conditions was assessed for dried gelatin nanoparticles formulated in sucrose, trehalose, mannitol, or a mannitol/sucrose mixture. Size, size distribution, and residual moisture content were investigated. Sucrose- and trehalose-containing formulations exhibited the greatest stability, but mannitol-containing formulations also showed notable stabilization despite their crystalline nature.

Delivery by cationic gelatin nanoparticles strongly increases the immunostimulatory effects of CpG oligonucleotides.

PURPOSE: Cationized gelatin nanoparticles (GNPs) were used as carrier to improve delivery of immunostimulatory CpG oligonucleotides (CpG ODN) both in vitro and in vivo. METHODS: Uptake of CpG ODN-loaded cationized gelatin nanoparticles (CpG-GNPs) into murine myeloid dendritic cells (DCs) and their respective immunostimulatory activity was monitored. In vivo, induction of cytokine secretion by CpG-GNPs was measured. For experiments on primary human cells, prototypes of the three CpG ODN classes were adsorbed onto GNPs. Uptake and induction of proinflammatory cytokines were assessed in human plasmacytoid DCs and B cells, the only existing human target cells for CpG ODN. RESULTS: In the murine system, gelatin nanoparticle formulations enhanced the uptake and immunostimulatory activity of CpG ODN both in vitro and in vivo. Furthermore, delivery by cationized gelatin nanoparticles of CpG ODN of the classes B and C to primary human plasmacytoid DCs increased production of IFN-alpha, a key cytokine in the driving of both the innate and adaptive immune responses. CONCLUSION: GNPs can be used as a biodegradable and well tolerated carrier to deliver CpG ODN to their target cells and strongly increase activation of the immune system. This concept may be applied as novel adjuvant for antiviral and antitumoral vaccines.

Ultrasound targeted microbubble destruction increases capillary permeability in hepatomas.

Ultrasound-targeted microbubble destruction (UTMD) has evolved as a promising tool for organ-specific gene and drug delivery. Taking advantage of high local concentrations of therapeutic substances and transiently increased capillary permeability, UTMD could be used for the treatment of ultrasound accessible tumors. The aim of this study was to evaluate if UTMD can locally increase capillary permeability in a hepatoma model of the rat. Furthermore, we evaluated whether UTMD can transfect DNA into such tumors. Subcutaneous Morris hepatomas were induced in both hind limbs of ACI rats by cell injection. A total of 18 rats were divided into three groups. Only one tumor per rat was treated by ultrasound. The first group received injection of Evans blue, followed by UTMD. The second group received a phosphate-buffered saline solution infusion and ultrasound to the target tumor after Evans blue injection. The third group received UTMD first, followed by Evans blue injection. Tumors and control organs were harvested, and Evans blue extravasation was quantified. Another 12 rats received DNA-loaded microbubbles by UTMD to one tumor, encoding for luciferase. Evans blue injection followed by UTMD showed about fivefold higher Evans blue amount in the target tumors compared with the control tumors. In contrast, no significant difference in Evans blue content was detected between target and control tumors when ultrasound was applied without microbubbles or when UTMD was performed before Evans blue injection. Plasmid transfection was not successful. In conclusion, ultrasound targeted microbubble destruction is able to transiently increase capillary permeability in hepatomas. Using naked DNA, this technique does not seem to be feasible for noninvasive transfection of hepatomas.

Method for quantifying the PEGylation of gelatin nanoparticle drug carrier systems using asymmetrical flow field-flow fractionation and refractive index detection.

The PEGylation of colloidal drug carrier systems protects them from a rapid clearance from the blood stream and therefore prolongs their plasma half-lives. This fundamental concept is nowadays widely applied whereas the analytical description, i.e., the quantification of the PEGylation process, is still challenging due to the poor spectrophotometrical properties of PEG. The aim of this work is to quantify the PEGylation process of gelatin nanoparticles by utilizing the combination of asymmetrical flow field-flow fractionation (AF4) and refractive index (RI) detection and to demonstrate the potential of AF4 in the work with colloidal drug carrier systems. An AF4 separation mechanism of gelatin nanoparticles and PEG was developed without further sample preparation. After separation, the PEGylation could be directly quantified from the respective RI data and a threshold of a maximum amount of PEG that can be bound onto the surface of the nanoparticles could be determined. The PEGylation could be further visualized by atomic force microscopy (AFM). In sum, the presented results show the successful application of AF4 in the field of colloidal drug carrier systems, and in combination with AFM, both techniques can be stated as promising tools for the future analysis of colloidal drug carrier systems.

In vitro uptake of gelatin nanoparticles by murine dendritic cells and their intracellular localisation.

The long term goal of this study is to develop an efficient nanoscopic vaccine delivery system, based on the biodegradable and natural polymer gelatin, to deliver therapeutic protein antigens along with adjuvants into dendritic cells (DCs). In this study, gelatin nanoparticles were tested for qualitative and quantitative uptake in murine DCs in vitro. A second aim of this study was to prove that the carrier system is able to deliver tetramethylrhodamine conjugated dextran (TMR-dextran), as a model drug into the DCs. The TMR-dextran was incorporated during the preparation of the gelatin nanoparticles. DCs were generated from murine bone marrow cells by an established ex vivo technique. Flow cytometry showed that 88% of the cells positive for the specific murine DC marker CD11c took up TMR-dextran loaded gelatin nanoparticles, whereas only 4% of the soluble form of TMR-dextran was taken up. Double color confocal laser scanning microscopy (CLSM) showed that gelatin nanoparticles were phagocytosed by DCs and the triple color CLSM showed that the TMR-dextran was localized mainly in lysosomes as expected, but partly also outside the lysosomes, presumably in the cytoplasm. An in vitro release study of TMR-dextran from gelatin nanoparticles demonstrated that there was hardly any release in phosphate buffered saline (PBS), but by trypsin-assisted degradation of gelatin nanoparticles resulted in the release of about 80% of the TMR-dextran from the particles. These results suggest that gelatin nanoparticles hold promise as a new biocompatible tool for vaccine delivery to DCs, with applications in cancer immunotherapy.

Evaluating gelatin based nanoparticles as a carrier system for double stranded oligonucleotides.

PURPOSE: Surface modified gelatin nanoparticles were tested as a potential carrier system for double stranded DNA and RNA oligonucleotides. The results will be discussed with regard to former experiments conducted with single stranded oligonucleotides. METHODS: Gelatin nanoparticles were prepared by a two step desolvation method and surface modified by the covalent coupling of a quaternary amine to obtain a permanent positive net charge. Oligonucleotide loading was conducted in three different media applying 50 microg oligonucleotide per mg nanoparticles in total. Five batches of nanoparticles varying in size and zeta potential (zeta) were tested. The zeta potentials were determined under enforced ionic conditions in a 10 mmol sodium chloride solution at pH 7.0. The separation of unbound oligonucleotides and gelatin nanoparticles was achieved by centrifugation. Free oligonucleotide was determined UV-spectrophotometrically (260 nm) in the supernatant. RESULTS: It could be shown that up to 50 microg nucleic acid per mg nanoparticles can be bound depending on the particle's zeta potential and the chosen incubation medium. CONCLUSIONS: The results suggest that the proposed procedure allows a successful drug loading of double stranded oligonucleotides onto to the surface of accordingly modified gelatin nanoparticles.

Gelatin nanoparticles as a new and simple gene delivery system.

PURPOSE: The aim of this study was to evaluate cationized gelatin nanoparticles as biodegradable and low cell toxic alternative carrier to existing DNA delivery systems. METHODS: Native gelatin nanoparticles were produced using a two step desolvation method. In order to bind DNA by electrostatic interactions onto the surface of the particles, the quaternary amine cholamine was covalently coupled to the particles. The modified nanoparticles were loaded with different amounts of plasmid in varying buffers and compared to polyethyleneimine-DNA complexes (PEI polyplexes) as gold standard. Transfection ability of the loaded nanoparticles was tested on B16 F10 cells. Additionally, the cell toxicity of the formulations was monitored. RESULTS: Different setups resulted in efficient gene delivery displayed by exponential increase of gene expression. The gene expression itself occurred with a certain delay after transfection. In contrast to PEI polyplexes, cationized gelatin nanoparticles almost did not show any significant cytotoxic effects. CONCLUSIONS: Cationized gelatin nanoparticles have shown the potential of being a new effective carrier for nonviral gene delivery. The major benefit of gelatin nanoparticles is not only the very low cell toxicity, but also their simple production combined with low costs and multiple modification opportunities offered by the matrix molecule.

Asymmetrical flow field-flow fractionation and multiangle light scattering for analysis of gelatin nanoparticle drug carrier systems.

The physicochemical properties of nanosized colloidal drug carrier systems are of great influence on drug efficacy. Consequently, a broad spectrum of analytical techniques is applied for comprehensive drug carrier characterization. It is the primary objective of this paper to present asymmetrical flow field-flow fractionation (AF4), coupled online with multiangle light scattering detection, for the characterization of gelatin nanoparticles. Size and size distribution of drug-loaded and unloaded nanoparticles were determined, and data were correlated with results of state-of-the-art methods, such as scanning electron microscopy and photon correlation spectroscopy. Moreover, the AF4 fractionation of gelatin nanoparticulate carriers from a protein model drug is demonstrated for the first time, proposing a feasible way to assess the amount of loaded drug in situ without sample preparation. This hypothesis was set into practice by monitoring the drug loading of nanoparticles with oligonucleotide payloads. In this realm, various fractions of gelatin bulk material were analyzed via AF4 and size-exclusion high-pressure liquid chromatography. Mass distributions and high-molecular-weight fraction ratios of the gelatin samples varied, depending on the separation method applied. In general, the AF4 method demonstrated the ability to comprehensively characterize polymeric gelatin bulk material as well as drug-loaded and unloaded nanoparticles in terms of size, size distribution, molecular weight, and loading efficiency.