Liposome based systems for systemic siRNA delivery: stability in blood sets the requirements for optimal carrier design.

siRNA therapeutics are currently regarded as promising candidates to make a leap forward in the search for treatments of various hard to cure diseases. In order to exploit the full potential of siRNA based therapeutics, development of delivery systems that can efficiently guide the siRNA molecules to their target without major side effects will be the key to success. Lipid based delivery systems, originating from earlier research in the fields of gene delivery, are the most studied candidates for siRNA delivery. Here we discuss the requirements that need to be met by these siRNA delivery systems to ensure adequate stability after systemic application and subsequent deposition in the target tissue. The encountered hurdles in the blood stream and the solutions proposed in literature are discussed.

Sizing nanomatter in biological fluids by fluorescence single particle tracking.

Accurate sizing of nanoparticles in biological media is important for drug delivery and biomedical imaging applications since size directly influences the nanoparticle processing and nanotoxicity in vivo. Using fluorescence single particle tracking we have succeeded for the first time in following the aggregation of drug delivery nanoparticles in real time in undiluted whole blood. We demonstrate that, by using a suitable surface functionalization, nanoparticle aggregation in the blood circulation is prevented to a large extent.

Advanced fluorescence microscopy methods illuminate the transfection pathway of nucleic acid nanoparticles.

A great deal of attention in biopharmacy and pharmaceutical technology is going to the development of nanoscopic particles to efficiently deliver nucleic acids to target cells. Despite the great potential of nucleic acids for treatment of various diseases, progress in the field is fairly slow. One of the causes is that development of suitable nanoscopic delivery vehicles is hampered by insufficient knowledge of their physicochemical and biophysical properties during the various phases of the transfection process. To address this issue, in the past decade we have developed and applied advanced fluorescence microscopy techniques that can provide a better insight in the transport and stability of nanoparticles in various biological media. This mini-review discusses the basic principles of fluorescence recovery after photobleaching (FRAP), fluorescence correlation spectroscopy (FCS) and single particle tracking (SPT), and gives an overview of studies in which we have employed these techniques to characterize the transport and stability of nucleic acid containing nanoparticles in extracellular media and in living cells.

Synergistic effects between natural histone mixtures and polyethylenimine in non-viral gene delivery in vitro.

Nanoparticles made of plasmid DNA (pDNA) and cationic polymers are promising strategies for non-viral gene delivery. However, many cationic polymers are toxic to cells when used in higher concentrations. Positively charged proteins, such as histones, are biodegradable and a good alternative, especially for potential in vivo applications. It has previously been shown that histones are able to complex DNA and mediate transfection of cells. To investigate possible synergistic effects between the different histone types and to avoid the use of recombinant proteins, we analysed whether natural histone mixtures would be functional as gene carriers. Core and linker histones from calf thymus and from chicken erythrocytes were used to transfect different cell lines. The protein mixtures efficiently complexed the pDNA, and the resulting particles entered the cells. However, only marginal expression of the gene encoded by the pDNA was observed. Transfection rates increased drastically when minimal amounts of the basic polymer polyethylenimine (PEI) were added to the particles. Neither PEI nor histones alone mediated any transfection under the conditions where a combination of both worked efficiently, and the combined particles were well tolerated by the cells. These results demonstrate that histone mixtures from natural sources in combination with minimal amounts of PEI can be used as gene carriers. This might have consequences for the development of novel gene delivery strategies, such as DNA vaccines, with minimal side-effects.

Monitoring the disassembly of siRNA polyplexes in serum is crucial for predicting their biological efficacy.

To exploit the full therapeutic potential of short interfering RNA (siRNA), efficient delivery vehicles are needed as siRNA fails to enter cells spontaneously. Such carriers should also protect siRNA against degradation while it is on its way to the cytosol of the target cells. Cationic polymers are widely investigated as siRNA carriers. Cationic polymers and siRNA self-assemble into siRNA polyplexes which have been shown to silence genes in cell cultures. While siRNA polyplexes will become exposed to full blood after intravenous injection, in vitro gene knockdown is mostly evaluated in serum free media or media containing only a few percent of serum. Little knowledge is currently available on the stability of siRNA polyplexes in blood, while there are no methods available which allow a quantitative measurement of the disassembly of nucleic acid containing nanoparticles in such complex biological media. This paper shows that fluorescence fluctuation spectroscopy allows us to quantitatively monitor the disassembly of siRNA containing nanoparticles in full serum. It further shows that the gene silencing efficacy of siRNA polyplexes in serum containing media can be very well explained by their disassembling behavior in these media. Our findings are important for the further development of siRNA polyplexes and also other nanoparticulate nucleic acid delivery systems.

Stability of siRNA polyplexes from poly(ethylenimine) and poly(ethylenimine)-g-poly(ethylene glycol) under in vivo conditions: effects on pharmacokinetics and biodistribution measured by Fluorescence Fluctuation Spectroscopy and Single Photon Emission Computed Tomography (SPECT) imaging.

In search of optimizing siRNA delivery systems for systemic application, one critical parameter remains their stability in blood circulation. In this study, we have traced pharmacokinetics and biodistribution of each component of siRNA polyplexes formed with polyethylenimine 25 kDa (PEI) or PEGylated PEIs by in vivo real-time gamma camera recording, SPECT imaging, and scintillation counting of blood samples and dissected organs. In vivo behavior of siRNA and polymers were compared and interpreted in the context of in vivo stability of the polyplexes which had been measured by fluorescence fluctuation spectroscopy (FFS). Both pharmacokinetics and biodistribution of polymer-complexed siRNA were dominated by the polymer. PEGylated polymers and their siRNA polyplexes showed significantly less uptake into liver (13.6-19.7% ID of PEGylated polymer and 9.5-10.2% ID of siRNA) and spleen compared to PEI 25 kDa (liver deposition: 36.2% ID of polymer and 14.6% ID of siRNA). With non-invasive imaging methods we were able to predict both kinetics and deposition in living animals allowing the investigation of organ distribution in real time and at different time points. FFS measurements proved stability of the applied polyplexes under in vivo conditions which explained the different behavior of complexed from free siRNA. Despite their stability in circulation, we observed that polyplexes dissociated upon liver passage. Therefore, siRNA/(PEG-)PEI delivery systems are not suitable for systemic administration, but instead may be useful when the first-pass effect is circumvented, which is the case in local application.

Elucidating the encapsulation of short interfering RNA in PEGylated cationic liposomes.

Short interfering RNA (siRNA) holds great potential for the treatment of hard-to-cure diseases. One of the major challenges to translate siRNA into drugs is its efficient delivery to its site-of-action, namely the cytoplasm of the target cells. Cationic liposomes have been shown to do the trick, but their short circulation lifetime and potential aggregation in blood limit their applicability for intravenous administration. These hurdles might be overcome by attaching poly(ethylene glycol) (PEG) at the surface of the cationic liposomes through the use of PEGylated lipids. However, this paper reveals that the classical mixing of siRNA with preformed PEGylated cationic liposomes, as frequently done to load PEGylated liposomes with siRNA, prevents an efficient encapsulation of the siRNA in the liposomes. We show that only a minor fraction of the siRNA becomes encapsulated in the core of the PEGylated liposomes, whereas a major part of the siRNA becomes bound at the liposome's outer surface. In serum, the surface-bound siRNA is immediately released and becomes degraded by serum nucleases. By contrast, hydrating a lipid film (containing PEGylated and cationic lipids) directly with a concentrated solution of siRNA (so-called HYDRA protocol), instead of mixing the siRNA with preformed PEGylated liposomes, encapsulates almost 50% of the siRNA in the core of the PEGylated liposomes, which is the maximal encapsulation efficiency for this type of complexes. We show that the siRNA encapsulated in the core of the thus obtained "HYDRA siPLexes" remains fully encapsulated upon dispersing the PEGylated liposomes in human serum.

A fast and sensitive method for measuring the integrity of siRNA-carrier complexes in full human serum.

SiRNA based therapeutics are currently under investigation for treatment of cancer and viral infections. Upon intravenous administration, the nanoscopic delivery systems which carry the siRNA need to be stable in serum, an aspect which is often overlooked in numerous publications on siRNA delivery systems. Techniques currently available for studying the dissociation of siRNA-liposome complexes are time consuming and incompatible with full serum. We therefore developed a fluorescence fluctuation spectroscopy (FFS) based method which allows to monitor the integrity of siRNA-carrier complexes. The method can very rapidly provide quantitative information on the complex integrity in biological media, like full human serum, and at very low siRNA concentrations (approximately 20 nM siRNA). Information on the integrity of intravenously injected siRNA nanoparticles in serum is crucial. Consequently, the FFS method reported in this work may find broad applicability in the field of siRNA-carrier design.