Targeted Gene Silencing of TLR4 Using Liposomal Nanoparticles for Preventing Liver Ischemia Reperfusion Injury (original) (raw)
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Biomaterials, 2007
Although small interfering RNA (siRNA) is a potentially useful therapeutic approach to silence the targeted gene of a particular disease, its use is limited by its stability in vivo. For the liver parenchymal cell (PC)-selective delivery of siRNA, siRNA was complexed with galactosylated cationic liposomes. Galactosylated liposomes/siRNA complex exhibited a higher stability than naked siRNA in plasma. After intravenous administration of a galactosylated liposomes/siRNA complex, the siRNA did not undergo nuclease digestion and urinary excretion and was delivered efficiently to the liver and was detected in PC rather than liver non-parenchymal cells (NPC). Endogenous gene (Ubc13 gene) expression in the liver was inhibited by 80% when Ubc13-siRNA complexed with galactosylated liposomes was administered to mice at a dose of 0.29 nmol/g. In contrast, the bare cationic liposomes did not induce any silencing effect on Ubc13 gene expression. These results indicated that galactosylated liposomes/siRNA complex could induce gene silencing of endogenous hepatic gene expression. The interferon responses by galactosylated liposomes/siRNA complex were controlled by optimization of the sequence of siRNA. Also no liver toxicity due to galactosylated liposomes/siRNA complex was observed under any of the conditions tested. In conclusion, we demonstrated the hepatocyte-selective gene silencing by galactosylated liposomes following intravenous administration.
Journal of Controlled Release, 2012
Tumor necrosis factor alpha (TNFα) is a classic proinflammatory cytokine implicated in the pathogenesis of several autoimmune and inflammatory diseases including viral encephalitis. Macrophages being major producers of TNFα are thus attractive targets for in vivo RNA interference (RNAi) mediated down regulation of TNFα. The application of RNAi technology to in vivo models however presents obstacles, including rapid degradation of RNA duplexes in plasma, insufficient delivery to the target cell population and toxicity associated with intravenous administration of synthetic RNAs and carrier compounds.
Molecular Pharmaceutics, 2014
Effective delivery of small interfering RNA (siRNA) requires efficient cellular uptake and release into cytosol where it forms an active complex with RNAi induced silencing complex (RISC). Despite rapid developments in RNAi therapeutics, improvements in delivery efficiency of siRNA are needed to realize the full potential of this modality in broad therapeutic applications. We evaluated potential physiological and biochemical barrier(s) to the effective liver delivery of siRNA formulated in lipid nanoparticle (LNP) delivery vehicles. The comparative siRNA delivery performance of three LNPs was investigated in rats. They were assembled with either C14-or C18-anchored PEG-lipid(s), cationic lipid(s), and various helper lipid(s) and contained the same siRNA duplex. These LNPs demonstrated differentiated potency with ED 50 's ranging from 0.02 to 0.25 mg/kg. The two C14-PEG-LNPs had comparable siRNA exposure in plasma and liver, while the C18-PEG-LNP demonstrated a higher plasma siRNA exposure and a slower but sustained liver uptake. RISC bound siRNA within the liver, a more proximal measure of the pharmacologically active siRNA species, displayed loading kinetics that paralleled the target mRNA knockdown profile, with greater RISC loading associated with more potent LNPs. Liver perfusion and hepatocyte isolation experiments were performed following treatment of rats with LNPs containing VivoTag-fluorescently labeled siRNA. One hour after dosing a majority of the siRNA within the liver was associated with hepatocytes and was internalized (within small subcellular vesicles) with no significant cell surface association, indicating good liver tissue penetration, hepatocellular distribution, and internalization. Comparison of siRNA amounts in hepatocytes and subcellular fractions of the three LNPs suggests that endosomal escape is a significant barrier to siRNA delivery where cationic lipid seems to have a great impact. Quantitation of Ago-2 associated siRNA revealed that after endosomal escape further loss of siRNA occurs prior to RISC loading. This quantitative assessment of LNP-mediated siRNA delivery has highlighted potential barriers with respect to endosomal escape and incomplete RISC loading for delivery optimization efforts.
Journal of Histochemistry & Cytochemistry, 2011
Chemically stabilized small interfering RNA (siRNA) can be delivered systemically by intravenous injection of lipid nanoparticles (LNPs) in rodents and primates. The biodistribution and kinetics of LNP–siRNA delivery in mice at organ and cellular resolution have been studied using immunofluorescence (IF) staining and quantitative polymerase chain reaction (qPCR). At 0.5 and 2 hr post tail vein injection of Cy5-labeled siRNA encapsulated in LNP, the organ rank-order of siRNA levels is liver > spleen > kidney, with only negligible accumulation in duodenum, lung, heart, and brain. Similar conclusions were drawn by using qPCR to measure tissue siRNA levels as a secondary end point. siRNA levels in these tissues decreased by more than 10-fold after 24 hr. Within the liver, LNPs delivered siRNA to hepatocytes, Kupffer cells, and sinusoids in a time-dependent manner, as revealed by IF staining and signal quantitation methods established using OPERA/Columbus software. siRNA first accu...
Efficient systemic delivery of siRNA to the mouse liver by pegylated lipopolymer
International journal of pharmaceutics, 2012
Short interfering RNA (siRNA) drugs have entered clinical trials in various disease areas. However, systemic use of siRNA drugs faces a challenge of tissue in-specificity and membrane impenetrability. In this study, we hypothesized that the combined of lipidic molecules with a pegylated cationic polymer through random polymerization of Micheal reaction could enhance the hepatocyte's preferential uptake and improve membrane penetrability. We reported the efficacy of in vitro knockdown of apoB mRNA in HepG2 cell line and in vivo knockdown of the liver apoB mRNA using a pegylated lipopolymer-siapoB complex. Results show that apoB mRNA in the nu/nu and C57BL/6 black mice was knockdown to ∼60-80%, up to 2 weeks, at low doses of 1.0-2.5 mg/kg of siRNA. The finding sets a new stage for further developments for apoB siRNA therapeutics.