Ultrasound image-guided gene delivery using three-dimensional diagnostic ultrasound and lipid-based microbubbles.

Gene therapy is a promising technology for genetic and intractable diseases. Drug delivery carriers or systems for genes and nucleic acids have been studied to improve transfection efficiency and achieve sufficient therapeutic effects. Ultrasound (US) and microbubbles have also been combined for use in gene delivery. To establish a clinically effective gene delivery system, exposing the target tissues to US is important. The three-dimensional (3D) diagnostic probe can three-dimensionally scan the tissue with mechanical regulation, and homogenous US exposure to the targeted tissue can be expected. However, the feasibility of therapeutically applying 3D probes has not been evaluated, especially gene delivery. In this study, we evaluated the characteristics of a 3D probe and lipid-based microbubbles (LB) for gene delivery and determined whether the 3D probe in the diagnostic US device could be used for efficient gene delivery to the targeted tissue using a mouse model. The 3D probe RSP6-16 with LB delivered plasmid DNA (pDNA) to the kidney after systemic injection with luciferase activity similar to that of probes used in previously studies. No toxicity was observed after treatment and, therefore, the combined 3D probe and LB would deliver genes to targeted tissue safely and efficiently.

Effect of lipid shell composition in DSPG-based microbubbles on blood flow imaging with ultrasonography.

Diagnostic ultrasound is non-invasive and provides real-time imaging. Microbubbles (MBs) are ultrasound contrast agents used to observe small blood flow, such as tumor tissue. However, MBs have short blood flow imaging time. This study developed lipid-based microbubbles (LMBs) with longer blood flow imaging time by focusing on their shell composition. Liposome research reported that addition 1,2-distearoyl-sn-glycero-3-phosphoglycerol (DSPG) to the lipid composition enhances liposome membrane stability. Therefore, we introduced DSPG at different ratios into the LMBs lipid shell. Results showed that the lipid shell composition of MBs affects stability in vivo. 60% DSPG-containing LMBs (DSPG60-LMBs) have sustained blood flow imaging time compared with LMBs, which have other DSPG ratios, Sonazoid® and SonoVue®. DSPG60-LMBs also showed less uptake into the liver compared with Sonazoid®. Therefore, DSPG60-LMBs can have long blood flow imaging time and can be effective diagnostic agents in ultrasound imaging.

Effects of encapsulated gas on stability of lipid-based microbubbles and ultrasound-triggered drug delivery.

The combination of Ultrasound (US) and US contrast agent (microbubbles, MBs), which is gas stabilized by a shell such as phospholipids or proteins, has potential as a useful innovative diagnostic and therapeutic tool. Previous studies have evaluated how particle size or shell components of MBs affect their physical characteristics, imaging ability, and drug delivery efficacy. We reported that MBs composed of neutral, anionic phospholipids, and polyethylene glycol-conjugated phospholipids at appropriate ratios were highly stable for US imaging. However, the effects of encapsulated gas on stability and drug delivery efficacy have not been characterized. Therefore, we developed several gas-loaded MBs with identical shell compositions and assessed their stability by US imaging (LOGIQ E9 with ML6-15 probe, MI 0.20). In addition, we assessed the effects of gas encapsulated in MBs on brain-targeted drug delivery, because the brain requires an efficient drug delivery system. Perfluoropropane and perfluorobutane-loaded MBs (MB-C3F8 and MB-C4F10) showed sustained US imaging in vitro and in vivo compared with sulfur hexafluoride-loaded MBs (MB-SF6). In addition, treatment of MB-C3F8 and MB-C4F10 with non-focused US efficiently delivered Evans blue, which was used as a model drug, to the brain to a greater extent than MB-SF6. In these treatments, notable damage to brain was not observed, which was assessed by HE staining and denatured neuron staining. Our results suggested that perfluoropropane and perfluorobutane could be useful for the production of MBs with high stability to allow for US imaging and drug delivery.