With the aim of obtaining a carrier for combined magnetic‐field‐ and ultrasound‐targeted nucleic acid delivery, acoustically active lipospheres are prepared that comprise magnetic nanoparticles and plasmid DNA or synthetic siRNA. The lipospheres, with average diameters of 5 μm and smaller, are obtained upon shaking a mixture of soybean oil, a cationic lipid, magnetic nanoparticles, a nucleic acid, and aqueous buffer in a perfluoropropane atmosphere in a sealed vial. These lipospheres create contrast in ultrasound imaging and display greatly increased magnetophoretic mobility and in consequence greatly improved magnetic retention in a flow model when compared with free magnetic nanoparticles. In cell culture, the lipospheres are sedimented within minutes to the surface of cells using a gradient magnetic field. This sedimentation results in the association of about 50% of the applied plasmid DNA with the cells and in functional DNA and siRNA delivery in vitro. Under these conditions, ultrasound does not have an enhancing effect on nucleic acid delivery. When magnetic, acoustically active lipospheres carrying 125iodine‐labeled plasmid DNA are injected into the tail veins of mice, the application of a gradient magnetic field to the chests of the mice results in a two‐ to threefold enrichment of both lung lobes with the plasmid. A similar enrichment is obtained when ultrasound alone (1 MHz, 10 min) is applied. The combined application of magnetic field and ultrasound has no synergistic effect in terms of liposphere capture in the lungs. Histological analysis reveals intact lipospheres in lung capillaries. A synergistic effect of magnetic field and ultrasound is observed in site‐specific plasmid deposition in a dorsal skinfold chamber model in mice after injection into the carotis. These conditions also result in functional plasmid delivery to the vasculature after intrajugular injection.
Lipospheres made from soy bean oil and a combination of the cationic lipid Metafectene and the helper lipid dioleoylphosphatidyl-ethanolamine were functionalized with magnetic nanoparticles (NPs) and small interfering RNA (siRNA). The resulting magnetic lipospheres loaded with siRNA are proven here as efficient nonviral vectors for gene silencing. Embedding magnetic NPs in the shell of lipospheres allows for magnetic force-assisted transfection (magnetofection) as well as magnetic targeting in both static and fluidic conditions mimicking the bloodstream.
Magnetophoretic velocity of magnetic nano-objects for biomedical applications was characterized by measuring space-and time-resolved extinction profiles (STEP-Technology) using a customized LUMiReader device equipped with a set of permanent magnets (STEP-MAG). The resulting magnetic fields and gradients in a sample volume enable the operator to choose measurement conditions for magnetic micro-and nanoparticles and their assemblies. The dependence of magnetophoretic velocity on concentration and optical wavelengths indicated assembly of the nano-objects upon magnetophoresis. The method has potential applications in biomedicine to develop advanced materials and protocols for cell separation, tissue engineering, and drug/nucleic acid targeting.
Nucleic acid delivery to cells to make them produce a desired protein or to shut down the expression of endogenous genes opens unique possibilities for research and therapy. During the last decade, to realize the potential of this approach, nanomagnetic methods for delivering and targeting nucleic acids have been developed, methods which are often referred to as Magnetofection™. Our research group at the Institute of Experimental Oncology and Therapy Research, located at the University Hospital Klinikum rechts der Isar in the center of Munich, Germany, develops new magnetic nanomaterials and, their formulations with gene-delivery vectors and technologies to allow localized and efficient gene delivery in vitro and in vivo for a variety of research, diagnostic and therapeutic applications.
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