Thermally induced degradation pathways of three different antibody-based drug development candidates.

Protein-based medicinal products are prone to undergo a variety of chemical and physical degradation pathways. One of the most important exogenous stress condition to consider during manufacturing, transport and storage processes is temperature, because antibody-based therapeutics are only stable in a limited temperature range. In this study, three different formats of antibody-based molecules (IgG1, a bispecific scFv and a fab fragment) were exposed to thermal stress conditions occurring during transport and storage. For evaluation, an analytical platform was developed for the detection and characterization of relevant degradation pathways of different antibody-based therapeutics. The effect of thermal stress conditions on the stability of the three antibody-based formats was therefore investigated using visual inspection, different spectroscopic measurements, dynamic light scattering (DLS), differential scanning calorimetry (DSC), electrophoresis, asymmetric flow field-flow fractionation (AF4) and surface plasmon resonance technology (SPR). In summary, thermal stress led to heterogeneous chemical and physical degradation pathways of all three antibody-based formats used. In addition, identical exogenous stress conditions resulted in different kinds and levels of aggregates and fragmentation products. This knowledge is fundamental for a systematic and successful stabilization of protein-based therapeutics by the use of formulation additives.

Different Types of Vibrations Interacting with Electronic Excitations in Phycoerythrin 545 and Fenna-Matthews-Olson Antenna Systems.

The interest in the phycoerythrin 545 (PE545) photosynthetic antenna system of marine algae and the Fenna-Matthews-Olson (FMO) complex of green sulfur bacteria has drastically increased since long-lived quantum coherences were reported for these complexes. For the PE545 complex, this phenomenon is clearly visible even at ambient temperatures, while for the FMO system it is more prominent at lower temperatures. The key to elucidate the role of the environment in these long-lived quantum effects is the spectral density. Here, we employ molecular dynamics simulations combined with quantum chemistry calculations to study the coupling between the biological environment and the vertical excitation energies of the bilin pigment molecules in PE545 and compare them to prior calculations on the FMO complex. It is found that the overall strength of the resulting spectral densities for the PE545 system is similar to the experiment-based counterpart but also to those in the FMO complex. Molecular analysis, however, reveals that the origin for the spectral densities in the low frequency range, which is most important for excitonic transitions, is entirely different. In the case of FMO, this part of the spectral density is due to environmental fluctuations, while, in case of PE545, it is essentially only due to internal modes of the bilin molecules. This finding sheds new light on possible explanations of the long-lived quantum coherences and that the reasons might actually be different in dissimilar systems.

The FMO complex in a glycerol-water mixture.

Experimental findings of long-lived quantum coherence in the Fenna-Matthews-Olson (FMO) complex and other photosynthetic complexes have led to theoretical studies searching for an explanation of this unexpected phenomenon. Extending in this regard our own earlier calculations, we performed simulations of the FMO complex in a glycerol-water mixture at 310 K as well as 77 K, matching the conditions of earlier 2D spectroscopic experiments by Engel et al. The calculations, based on an improved quantum procedure employed by us already, yielded spectral densities of each individual pigment of FMO, in water and glycerol-water solvents at ambient temperature that compare well to prior experimental estimates. Due to the slow solvent dynamics at 77 K, the present results strongly indicate the presence of static disorder, i.e., disorder on a time scale beyond that relevant for the construction of spectral densities.

Theory and Simulation of the Environmental Effects on FMO Electronic Transitions.

Long-lived quantum coherence has been experimentally observed in the Fenna-Matthews-Olson (FMO) light-harvesting complex. It is much debated which role thermal effects play and if the observed low-temperature behavior arises also at physiological temperature. To contribute to this debate we use molecular dynamics simulations to study the coupling between the protein environment and the vertical excitation energies of individual bacteriochlorophyll molecules in the FMO complex of the green sulphur bacterium Chlorobaculum tepidum. The so-called spectral densities, which account for the environmental influence on the excited state dynamics, are determined from temporal autocorrelation functions of the energy gaps between ground and first excited states of the individual pigments. Although the overall shape of the spectral density is found to be rather similar for all pigments, variations in their magnitude can be seen. Differences between the spectral densities for the pigments of the FMO monomer and FMO trimer are also presented.

From atomistic modeling to excitation transfer and two-dimensional spectra of the FMO light-harvesting complex.

The experimental observation of long-lived quantum coherences in the Fenna-Matthews-Olson (FMO) light-harvesting complex at low temperatures has challenged general intuition in the field of complex molecular systems and provoked considerable theoretical effort in search of explanations. Here we report on room-temperature calculations of the excited-state dynamics in FMO using a combination of molecular dynamics simulations and electronic structure calculations. Thus we obtain trajectories for the Hamiltonian of this system which contains time-dependent vertical excitation energies of the individual bacteriochlorophyll molecules and their mutual electronic couplings. The distribution of energies and couplings is analyzed together with possible spatial correlations. It is found that in contrast to frequent assumptions the site energy distribution is non-Gaussian. In a subsequent step, averaged wave packet dynamics is used to determine the exciton dynamics in the system. Finally, with the time-dependent Hamiltonian, linear and two-dimensional spectra are determined. The thus-obtained linear absorption line shape agrees well with experimental observation and is largely determined by the non-Gaussian site energy distribution. The two-dimensional spectra are in line with what one would expect by extrapolation of the experimental observations at lower temperatures and indicate almost total loss of long-lived coherences.

Quest for spatially correlated fluctuations in the FMO light-harvesting complex.

The light absorption in light-harvesting complexes is performed by molecules such as chlorophyll, carotenoid, or bilin. Recent experimental findings in some of these complexes suggest the existence of long-lived coherences between the individual pigments at low temperatures. In this context, the question arises if the bath-induced fluctuations at different chromophores are spatially correlated or not. Here we investigate this question for the Fenna-Matthews-Olson (FMO) complex of Chlorobaculum tepidum by a combination of atomistic theories, i.e., classical molecular dynamics simulations and semiempirical quantum chemistry calculations. In these investigations at ambient temperatures, only weak correlations between the movements of the chromophores can be detected at the atomic level and none at the more coarse-grained level of site energies. The often-employed uncorrelated bath approximations indeed seem to be valid. Nevertheless, correlations between fluctuations in the electronic couplings between the pigments can be found. Depending on the level of theory employed, also correlations between the fluctuations of site energies and the fluctuations in electronic couplings are discernible.

DNA condensation by TmHU studied by optical tweezers, AFM and molecular dynamics simulations.

The compaction of DNA by the HU protein from Thermotoga maritima (TmHU) is analysed on a single-molecule level by the usage of an optical tweezers-assisted force clamp. The condensation reaction is investigated at forces between 2 and 40 pN applied to the ends of the DNA as well as in dependence on the TmHU concentration. At 2 and 5 pN, the DNA compaction down to 30% of the initial end-to-end distance takes place in two regimes. Increasing the force changes the progression of the reaction until almost nothing is observed at 40 pN. Based on the results of steered molecular dynamics simulations, the first regime of the length reduction is assigned to a primary level of DNA compaction by TmHU. The second one is supposed to correspond to the formation of higher levels of structural organisation. These findings are supported by results obtained by atomic force microscopy.

Time-dependent atomistic view on the electronic relaxation in light-harvesting system II.

Aiming at a better understanding of the molecular details in light absorption during photosynthesis, spatial and temporal correlation functions as well as spectral densities have been determined. At the focus of the present study are the light-harvesting II complexes of the purple bacterium Rhodospirillum molischianum. The calculations are based on a time-dependent combination of molecular dynamics simulations and quantum chemistry methods. Using a 12 ps long trajectory, different quantum chemical methods have been compared to each other. Furthermore, several approaches to determine the couplings between the individual chromophores have been tested. Correlations between energy gap fluctuations of different individual pigments are analyzed but found to be negligible. From the energy gap fluctuations, spectral densities are extracted which serve as input for calculations of optical properties and exciton dynamics. To this end, the spectral densities are tested by determining the linear absorption of the complete two-ring system. One important difference from earlier studies is given by the severely extended length of the trajectory along which the quantum chemical calculations have been performed. Due to this extension, more accurate and reliable data have been obtained in the low frequency regime which is important in the dynamics of electronic relaxation.

Polymeric micelles for parenteral delivery of sagopilone: physicochemical characterization, novel formulation approaches and their toxicity assessment in vitro as well as in vivo.

PURPOSE: The block copolymers PEG(2000)-b-PLA(2200), PEG(2000)-b-PCL(2600) and PEG(5000)-b-PCL(5000) have been currently identified as optimal solubilizing agents for Sagopilone, a poorly water-soluble anticancer drug. In the present study, the stability, formulation feasibility and in vitro as well as in vivo toxicity were evaluated. METHODS: Dispersion media, storage conditions, and dilutions were varied for stability assessment. The critical micelle concentration (CMC) was determined using a fluorescent probe technique. Lyophilizates and polymeric films were investigated as formulation options. Furthermore, the toxicity was studied in vitro and in vivo using HeLa/MaTu cells and a nude mouse model, respectively. RESULTS: A drug-polymer ratio as low as 1:20 (w/w) was sufficient to solubilize Sagopilone effectively and to obtain stable dispersions (24h: drug content >or= 95%). Although the micelles exhibited a similar thermodynamic stability (CMC: 10(-7)-10(-6)M), PEG-b-PCL micelles were kinetically more stable than PEG(2000)-b-PLA(2200) (24h at 37 degrees C: drug content >or= 90% compared to 30%, respectively). Lyophilization of PEG-b-PCL micelles and storage stability of solid drug-loaded PEG(2000)-b-PLA(2200) films (3m, 6 degrees C: drug content of (95.6+/-1.4)%) were demonstrated for the first time. The high antiproliferative activity has been maintained in vitro (IC(50)<1 nM). Carrier-associated side effects have not been observed in vivo and the maximum tolerated dose of micellar Sagopilone was determined to be 6 mg/kg. CONCLUSION: The results of this study indicate that polymeric micelles, especially PEG-b-PCL micelles, offer excellent potential for further preclinical and clinical cancer studies using Sagopilone.

Non-ionic dendritic glycerol-based amphiphiles: novel excipients for the solubilization of poorly water-soluble anticancer drug Sagopilone.

The purpose of this study was to investigate dendritic glycerol-based amphiphiles as novel solubilizers using poorly water-soluble anticancer drug Sagopilone. The effect of different core structures on the solubilization, formulation stability, and cytotoxicity using human umbilical vein endothelial cells (HUVECs) were investigated and compared to standard excipients. Structurally, all amphiphiles were composed of 2nd generation polyglycerol (PG[G2]) as the hydrophilic part and a single C(18)-chain (PG[G2]-C(18)), a C(18)-chain coupled by a diaromatic spacer (PG[G2]-DiAr-C(18)), a C(18)-chain with a naphthyl or bisphenyl end group (PG[G2]-C(18)-Naph/-BiP), or two C(18)-chains (PG[G2]-(C(18))(2)) as the hydrophobic part. They formed small (7-10 nm), monodisperse (PDI 0.04-0.20) micelles with the exception of PG[G2]-(C(18))(2). The amphiphiles revealed a 2-3-fold higher solubilization of Sagopilone than Cremophor ELP and polysorbate 80 independent of the core structure. PG[G2]-DiAr-C(18) exhibited the highest solubilization capacity (56.7+/-1.3 mg/g) compared to Cremophor ELP (18.5+/-0.1 mg/g). The micellar dispersions were stable in drug content over 3 days (> or = 97%). In contrast to polysorbate 80, dilutions did not show any precipitation after 3 days at 37 degrees C (remaining drug content: > 95%). They did not induce significant cytotoxicity at a concentration of 0.01 g/L after 24 h, and PG[G2]-C(18)-Naph was the least cytotoxic structure after 72 h with values comparable to Cremophor ELP and polysorbate 80. Overall, these amphiphiles possess superior solubilization properties compared to standard excipients used in parenteral formulations with an excellent formulation stability profile and comparable cytotoxicity.

Solubilization of sagopilone, a poorly water-soluble anticancer drug, using polymeric micelles for parenteral delivery.

Polymeric micelles were studied as a drug delivery system for Sagopilone, a poorly water-soluble anticancer drug, with respect to passive tumour targeting. Poly(ethylene glycol)-b-Poly(lactide) (PEG-b-PLA) and Poly(ethylene glycol)-b-Poly(epsilon-caprolactone) (PEG-b-PCL) were investigated to identify suitable copolymers and to assess the predictive value of solubility parameters. The impact of copolymer compositions (different hydrophobic/hydrophilic-ratios (w/w) from 0.3 to 1.3) and the preparation method (sonication; film formation) on the solubilization efficiency, size characteristics and micelle stability were studied. Thermal analysis was used to determine the apparent solid-state solubility. PEG(2000)-b-PLA(2200), PEG(2000)-b-PCL(2600) and PEG(5000)-b-PCL(5000) were identified as the most suitable delivery systems for Sagopilone. They exhibited efficient solubilization (> or =70%) yielding small (<100 nm), monodisperse, and spherical micelles. (80+/-12), (93+/-0.4) and (96+/-6)% of the drug still remained solubilized after 24h, respectively. Calculated solubility parameters were not predictive since they showed a reversed order of preference relative to experimental data. High solubilization after film hydration was accompanied with a 'supersaturation'. The reason for this well-known effect and the solubilization of Sagopilone within the block copolymer was elucidated by the evidence of glass solutions exceeding the solubilization capacity of the corresponding micelles. Overall, micellar drug delivery systems for Sagopilone were identified offering the potential for an improved cancer therapy.

The in vitro stability of air-filled polybutylcyanoacrylate microparticles.

Different methods of manufacturing permitted the production of air-filled PBCA microparticles (af-pbca-mp) with different physical properties such as size and wall thickness. These differences led to distinctions with respect to mechanical stability and, at the same time, to different levels of biochemical stability when incubated in biofluids. Microparticles, designed as they are to be mechanically more stable (composed of larger nanoparticles resulting in thicker shell wall, no surface hydrolysis), persist longer under in vitro conditions in biofluids such as serum, plasma and whole blood than do the more fragile ones. It was possible when using the measurement of ultrasound attenuation to characterize af-pbca-mp degradation with respect to the disappearance of the ultrasound properties of the particles and therefore to find out how long different formulations can be expected to be active as contrast agents under simulated in vivo conditions. The present examination showed that using either serum, plasma or whole blood leads to results with the same tendencies in terms of the stability and durability of af-pbca-mp in the media, mimicking in vivo conditions. It was thus possible to validate successfully the use of either serum or plasma as substitutes for whole blood. Further studies dealing with the in vitro in vivo correlation will be needed to find out if the situation in this in vitro assay corresponds to the situation in the body.

Specific targeting of ultrasound contrast agent (USCA) for diagnostic application: an in vitro feasibility study based on SAW biosensor.

The present study described a new strategy to examine the interaction between the targeted ultrasound contrast agent (USCA) and its target under flow conditions with a surface acoustic wave (SAW) transducer. The sensing principle is based on the measurement of the phase change on the sensing element upon the binding of specific biomolecules. Love-wave biosensor array was consisting of sensor elements and reference elements. The sensor elements have been prepared by coating the sensor surface with tumor marker EDB-fibronectin by means of SAM technique and carbodiimide chemistry. Reference elements were left blank or coated with fibronectin and used to eliminate thermal drift, unspecific binding, and turbulence from injection of liquids by calculating the differential phase shift with respect to the sensor elements. The binding of targeted USCA to the sensor surface was constantly recorded by monitoring the phase shift on the sensor element. The binding of targeted USCA generated a high phase shift on the sensor elements, but almost no change on the reference elements. Control experiments using non-targeted and isotype-targeted USCA confirmed the specificity of binding due to anti-EDB-fibronectin scFv-antibody-fragment-EDB-fibronectin antigen interaction. The suitability of the SAW technique to monitor the specific binding behavior of targeted micron-sized USCA in real time has been well established.

Cytotoxicity studies of Dynasan 114 solid lipid nanoparticles (SLN) on RAW 264.7 macrophages-impact of phagocytosis on viability and cytokine production.

Solid lipid nanoparticles (SLN) based on Dynasan 114 (D114) were tested using RAW 264.7 cells. The influence of different surfactants on the cytotoxicity of this type of SLN was examined, expressed as 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl-tetrazolium bromide (MTT) viability and the production of cytokines such as interleukin 6 (IL-6), IL-12 and tumour necrosis factor-alpha (TNF-alpha). Results were compared with previously obtained data when peritoneal mouse macrophages were used. SLN produced with stabilizers/surfactants such as poloxamer 188, sodium cholate, Lipoid S75, Tween 80, Poloxamine 908 and sodium dodecylsulfate were shown to be nontoxic towards RAW 264.7 cells. Cytokine production was reduced and stimulation, expressed in elevated cytokine levels, could not be found. Using cetylpyridinium chloride (CPC) as stabilizing surfactant, SLN became cytotoxic in a concentration-dependent manner. Not only were the viabilities reduced but also cytokine production. Cytotoxic effects of CPC stabilized SLN could be antagonized using cytochalasin B to block phagocytosis. D114-SLN produced with pharmaceutically accepted surfactants for intravenous injection (poloxamer 188, Lipoid S75, sodium cholate, Tween 80) were very well tolerated by the cells. Even sodium dodecylsulfate-stabilized D114-SLN did not exert toxic effects. Comparison of the RAW 264.7 data with previously obtained data from toxicity studies of D114-SLN towards peritoneal mouse macrophages showed similar results. This offers the possibility of using the RAW 264.7 cell line for cytotoxicity studies of colloidal drug carrier systems, rather than using laboratory animals as source of macrophages for these kinds of studies.

Transfection with different colloidal systems: comparison of solid lipid nanoparticles and liposomes.

Cationic solid lipid nanoparticles (SLN) for gene transfer are formulated using the same cationic lipids as for liposomal transfection agents. To investigate the differences and similarities in structure and performance between SLN and liposomes, a SLN preparation (S1), its counterpart formulation without matrix lipid (L1), a commercially available liposomal preparation (DLTR)--all based on the cationic lipid DOTAP--and a liposomal formulation that additionally contained the helper lipid dioleoylphosphatidylethanolamine (DOPE) (Escort) were compared. Photon correlation spectroscopy (PCS) showed that the SLN were smaller in diameter than the corresponding liposomes (88 vs. 148 nm) and atomic force microscopy (AFM) supported the expected structural differences. Desoxy ribonuclein acid (DNA) binding differed only marginally. Surprisingly, reporter gene expression was comparable between all DOTAP based formulations (S1, L1, DLTR), surpassed only by the DOPE containing liposomes (Escort). In conclusion, cationic lipid composition seems to be more dominant for in vitro transfection performance than the kind of colloidal structure it is arranged in. Hence, cationic SLN extend the range of highly potent non-viral transfection agents by one with favourable and distinct technological properties. Further SLN optimisation should be facilitated by the accumulated knowledge about cationic lipids in liposomal formulations.

A real-time in vitro assay for studying functional characteristics of target-specific ultrasound contrast agents.

PURPOSE: To develop an in vitro assay for studying the feasibility of specific targeting of ultrasound contrast agents (USCAs) for ultrasound diagnostics by employing the parallel plate flow chamber, which provides an environment that mimics some aspects of the in vivo conditions like shear rate and flow effects. METHODS: USCAs based on air-filled microparticles (MP) were functionalized with specific antibodies using carbodiimide coupling chemistry and characterized by fluorescence activated cell sorter (FACS). The binding experiments were done by subjecting the MP to shear stress as they interact with the target-coated surface of the flow chamber. RESULTS: A successive modification of MP with antibody and the glass surface with antigen was achieved and quantified. The binding studies showed specific attachment of targeted MP to EDB-FN (EDB domain of fibronectin) surface. The binding of MP via nonspecific interactions was minimal. The binding efficiency of antibody-loaded MP is dependent on the applied shear stress. An increase in the wall shear stress resulted in a decrease in binding efficiency. Binding efficiency was found to be correlated with the antibody density and antigen density on the interacting surfaces. CONCLUSIONS: The results indicate that the test system developed is reliable for characterizing targeted MP without any additional labeling and can be used as a functionality assay for studying the binding characteristic of USCA with respect to different parameters like density of targeting antibodies on the microparticle surface and of target protein. In addition, the microparticles can be studied in detail under different shear rates and flow conditions. Further studies concerning the in vitro-in vivo correlation will be necessary to further increase the value of this in vitro method.

Lipid-drug conjugate nanoparticles of the hydrophilic drug diminazene-cytotoxicity testing and mouse serum adsorption.

Sleeping sickness is a widely distributed disease in great parts of Africa. It is caused by Trypanosoma brucei gambiense and rhodiense, transmitted by the Tse-Tse fly. After a hemolymphatic stage, the parasites enter the central nervous system where they cannot be reached by hydrophilic drugs. To potentially deliver the hydrophilic antitrypanosomal drug diminazene diaceturate to the brain of infected mice, the drug was formulated as lipid-drug conjugate (LDC) nanoparticles (NP) by combination with stearic- (SA) and oleic acid (OA). To estimate the in vivo compatibility, the particles were incubated with human granulocytes. Because as potential delivery mechanism the absorption of specific serum proteins (ApoE, Apo AI and Apo AIV) was found to be responsible for the delivery of nanoparticles to the brain, demonstrated using PBCA nanoparticles coated with polysorbate 80 (LDL uptake mechanism) the nanoparticles were incubated with mouse serum and the adsorption pattern was determined using the 2-D PAGE technique. As a result of this study, the cytotoxic potential was shown to decrease when diminazene is part of the particle matrix compared to pure fatty acid nanoparticles and the mouse serum protein adsorption pattern differs from the samples studied earlier in human serum. Especially, the fact concerning Apo-E that could be detected when the particles were incubated in human serum is absent after the mouse serum incubation, potentially, is a critical point for the delivery via the LDL-uptake mechanism but the data demonstrate that LDC nanoparticles, with 33% (wt/wt) drug loading capacity possess the potential to act as a delivery system for hydrophilic drugs like diminazene diaceturate and that further studies have to demonstrate the usability as a brain delivery system.

Effect of cationic lipid and matrix lipid composition on solid lipid nanoparticle-mediated gene transfer.

This investigation is focused on the enhancement of in vitro transfection activity by optimizing cationic lipid and matrix lipid composition of solid lipid nanoparticles (SLN). For this purpose SLN were formulated by using two different matrix lipids and six different cationic detergents. These 12 formulations were tested for physical parameters such as particle size, zeta potential and DNA-binding capacity, and also for their biological properties such as cytotoxicity and in vitro transfection efficiency. The SLN were produced by hot high-pressure homogenization, all formulations were physically stable and showed a highly positive surface charge (+34 to +45 mV). In vitro cytotoxicity measurements on COS-1 cells revealed that cytotoxicity is strongly dependent on the cationic lipid used. SLN made from one-tailed cationic detergents were highly cytotoxic. In contrast the two-tailed cationic lipids were all well tolerated. Transfection activity seems to be determined by both the cationic lipid and the matrix lipid used. Here, the combination of cetylpalmitate and N-[1-(2,3-dioleoyloxy)propyl]-N,N,N-trimethylammonium chloride led to significantly higher transfection efficiencies than in all other tested combinations. These results indicate that well tolerated and highly efficient in vitro transfection could be achieved with SLN whenever selecting good combinations of two-tailed cationic lipids and matrix lipids.

Lipid-drug-conjugate (LDC) nanoparticles as novel carrier system for the hydrophilic antitrypanosomal drug diminazenediaceturate.

The objective of the present study was to incorporate the hydrophilic drug diminazenediaceturate at a high loading into lipid nanoparticles by creating nanoparticles from lipid-drug conjugates (LDC). IR and DSC data showed that the antitrypanosomal drug diminazene is able to react with fatty acids to form water-insoluble salts like diminazenedistearate and -dioleate. The salts could be transformed into nanoparticles using high-pressure homogenization technique, established for solid lipid nanoparticles (SLN). By using polysorbate 80 as surfactant, physically stable LDC nanoparticle dispersions of both salts could be obtained. The mean PCS diameters and polydispersity indices were 364 nm and 0.233 for diminazenedistearate and 442 nm and 0.268 for diminazenedioleate, respectively. Due to the composition of the LDC bulk materials, nanoparticles with a high drug load of 33% (w/w) were obtained even for this highly water-soluble drug diminazenediaceturate. The new carrier system of LDC nanoparticles overcomes one limitation of SLN, i.e. the limited loading capacity for hydrophilic drugs. Transforming water-soluble hydrophilic drugs into LDC and formation of nanoparticles allows prolonged drug release and targeting to specific sites by i.v. injection. These results provide a first basis of using LDC-polysorbate 80 nanoparticles for brain delivery of diminazene to treat second stage human African trypanosomiasis (HAT).

Stable biocompatible adjuvants--a new type of adjuvant based on solid lipid nanoparticles: a study on cytotoxicity, compatibility and efficacy in chicken.

A new type of adjuvant was tested for its ability to initiate antibody production in chickens, and its cellular and tissue compatibility were assessed. The stable biocompatible adjuvants tested are based on surface-modified solid lipid nanoparticles (SLNs), made from paraffin or biodegradable glycerides, and are simply admixed to the antigens before administration. The tissue-damaging potency of four formulations of the new adjuvants (H1, H2, H3 and H4) were first tested in vitro by using human foreskin fibroblasts and RAW 264.7 macrophages. The adjuvants were well tolerated by both cell types. Immunisation studies in chickens were performed by using a Mycoplasma bovis antigen and mouse immunoglobulin G (IgG). The resulting antibodies were non-invasively extracted from egg yolk. The use of the various adjuvant formulations resulted in a significant production of specific antibodies after the first and second booster immunisations. Freund's complete adjuvant (FCA), considered until now to be the "gold standard" among the adjuvants, revealed the highest antibody titre against mouse IgG. SLNs with a particle size of more than 100 nm exhibited a clear adjuvant activity, whereas SLNs with a particle size below 100 nm, in various concentrations, revealed a lower adjuvant activity. Immunisation of chickens with the mouse IgG alone, dissolved in phosphate-buffered saline, resulted in a slow antibody titre development. At the end of the experiment, the chickens were examined for vaccination-associated tissue damage. In contrast to FCA, the SLN formulations caused only minor tissue irritation at the injection sites. In conclusion, SLNs seem to be a promising alternative to FCA for antibody production in chickens, and potentially in other animals.