Abstract
Magnetic nanoparticle-incorporated liposomes (magnetic liposomes) are considered a promising site-specific drug delivery carrier. Although there are many reports on the development of magnetic liposomes, most of them focus on the characteristics of magnetic nanoparticles, rather than liposomes. Therefore, we first evaluated the effect of the physicochemical properties of magnetic liposomes on their interaction with cells. The highest cellular uptake and retention under a magnetic field was observed using small magnetic cationic liposomes. However, magnetic cationic liposomes exhibited strong cytotoxicity. Based on these results, we constructed complexes of less toxic magnetic anionic liposomes (Mag-AL) and atelocollagen (ATCOL), a biocompatible cationic biomaterial. The cellular associated amount of Mag-AL under a magnetic field was significantly increased when Mag-AL was complexed with ATCOL, and it was comparable to that of magnetic cationic liposomes. Additionally, Mag-AL/ATCOL complexes produced no cytotoxic effect. Moreover, liver accumulation of Mag-AL/ATCOL complexes was significantly increased at a magnetic field-exposed region after intravenous injection in rats. These results indicate that Mag-AL/ATCOL complexes may be a safe and efficient magnetic responsive drug carrier. Next, we applied Mag-AL/ATCOL complexes to prepare magnetized cells for effective cell therapy. Mesenchymal stem cells (MSCs), which have the capacity to suppress tissue inflammation, were efficiently magnetized by incubation with Mag-AL/ATCOL complexes under a magnetic field. Intramuscularly injected magnetized MSCs were significantly retained in mouse skeletal muscle in the presence of a magnetic field and modulated tissue inflammatory responses. These results suggest that magnetized MSCs are useful for muscle regeneration.
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