Therapeutic strategies in which recombinant growth factors are injected to stimulate arteriogenesis in patients suffering from occlusive vascular disease stand to benefit from improved targeting, less invasiveness, better growth-factor stability, and more sustained growth-factor release. A microbubble contrast-agent-based system facilitates nanoparticle deposition in tissues that are targeted by 1-MHz ultrasound. This system can then be used to deliver poly(d,l-lactic-co-glycolic acid) nanoparticles containing fibroblast growth factor-2 to mouse adductor muscles in a model of hind-limb arterial insufficiency. Two weeks after treatment, significant increases in both the caliber and total number of collateral arterioles are observed, indicating that the delivery of nanoparticles bearing fibroblast growth factor-2 by ultrasonic microbubble destruction may represent an effective and minimally invasive strategy for the targeted stimulation of therapeutic arteriogenesis.
Nanoparticle (NP) drug delivery vehicles may eventually offer improved tumor treatments; however, NP delivery from the bloodstream to tumors can be hindered by poor convective and/or diffusive transport. We tested whether poly(lactic-co-glycolic acid) NP delivery can be improved by covalently linking them to ultrasound (US)-activated microbubbles in a "composite-agent" formulation and whether drug 5-fluorouracil (5FU)-loaded NPs delivered in this fashion inhibit the growth of tumors that are typically not responsive to intravenously administered 5FU. After intravenous composite-agent injection, C6 gliomas implanted on Rag-1(-/-) mice were exposed to pulsed 1 MHz US, resulting in the delivery of 16% of the initial NP dose per gram tissue. This represented a five- to 57-fold increase in NP delivery when compared to multiple control groups. 5FU-bearing NP delivery from the composite-agent formulation resulted in a 67% reduction in tumor volume at 7 days after treatment, and animal survival increased significantly when compared to intravenous soluble 5FU administration. We conclude that NP delivery from US-activated composite agents may improve tumor treatment by offering a combination of better targeting, enhanced payload delivery, and controlled local drug release.
Object In this study, the authors sought determine whether microbubble (MB) destruction with pulsed low duty cycle ultrasound can be used to reduce brain tumor perfusion and growth through nonthermal microvascular ablation. Methods Studies using C57BLJ6/Rag-1 mice inoculated subcutaneously with C6 glioma cells were approved by the institutional animal care and use committee. Microbubbles were injected intravenously, and 1 MHz ultrasound was applied with varying duty cycles to the tumor every 5 seconds for 60 minutes. During treatment, tumor heating was quantified. Following treatment, tumor growth, hemodynamics, necrosis, and apoptosis were measured. Results Tumor blood flow was significantly reduced immediately after treatment, with posttreatment flow ranging from 36% (0.00002 duty cycle) to 4% (0.01 duty cycle) of pretreatment flow. Seven days after treatment, tumor necrosis and apoptosis were significantly increased in all treatment groups, while treatment with ultrasound duty cycles of 0.005 and 0.01 inhibited tumor growth by 63% and 75%, respectively, compared with untreated tumors. While a modest duty cycle–dependent increase in intratumor temperature was observed, it is unlikely that thermal tissue ablation occurred. Conclusions In a subcutaneous C6 glioma model, MB destruction with low–duty cycle 1-MHz ultrasound can be used to markedly inhibit growth, without substantial tumor tissue heating. These results may have a bearing on the development of transcranial high-intensity focused ultrasound treatments for brain tumors that are not amenable to thermal ablation.
Intravenously-injected nanoparticles can be delivered to skeletal muscle through capillary pores created by the activation of microbubbles with ultrasound; however, strategies that utilize co-injections of free microbubbles and nanoparticles are limited by nanoparticle dilution in the bloodstream. Here, we tested whether fluorescently-labeled (VT680; far-red fluorophore) nanoparticle [~150nm; poly(lactic-co-glycolic acid)] delivery to skeletal muscle can be improved by covalently linking them to albumin-shelled microbubbles in a composite agent formulation. Studies were performed using an experimental model of peripheral arterial disease, wherein the right and left femoral arteries of BalbC mice were surgically ligated. Four days after arterial ligation, composite agents, co-injected microbubbles and nanoparticles, or nanoparticles alone were administered intravenously and 1 MHz pulsed ultrasound was applied to the left hindlimb. Nanoparticle delivery was assessed at 0, 1, 4, and 24 hrs post-treatment by fluorescence-mediated tomography. Within the co-injection group, as expected, both microbubbles and ultrasound were required for nanoparticle delivery to skeletal muscle. Within the composite agent group, nanoparticle delivery was enhanced 8- to 18-fold over “no ultrasound” controls, depending on the time of measurement. A maximum of 7.2% of initial nanoparticle dose per gram tissue (ID/g) was delivered at 1 hr in the composite agent group, which was significantly greater than in the co-injection group (3.6% ID/g). We conclude that covalently linking 150 nm diameter poly(lactic-co-glycolic acid) nanoparticles to microbubbles before intravenous injection can improve their delivery to skeletal muscle.
Our goal was to enhance ultrasound (US)-targeted skeletal muscle transfection through the use of poly(ethyleneglycol) (PEG)/polyethylenimine (PEI) nanocomplex gene carriers and adjustments to US and microbubble (MB) parameters. C57BL/6 mice received an intravenous infusion of MBs and either “naked” luciferase plasmid or luciferase plasmid condensed in PEG/PEI nanocomplexes. Pulsed ultrasound (1MHz; 0.6 MPa or 0.8 MPa) was applied to the right hindlimb for 12 mins. Luciferase activity in both hindlimbs was assessed at 3, 5, 7, and 10 days post-treatment by bioluminescent imaging. When targeted to hindlimb using unsorted MBs and 0.6 MPa US, 7 days after treatment, we observed a >60-fold increase in luciferase activity in PEG/PEI nanocomplex treated muscles over muscles treated with “naked” plasmid DNA. Luciferase activity was consistently greater after treatment with PEG/PEI nanocomplexes at 0.6 MPa as compared to 0.8 MPa. The combination of small diameter MBs and 0.6 MPa US also resulted in significantly greater gene expression when compared to concentration matched intramuscular injections, a control condition in which considerably more PEG/PEI nanocomplexes were present in tissue. This result suggests that, in addition to facilitating PEG/PEI nanocomplex delivery from the bloodstream to tissue, US enhances transfection via one or more secondary mechanisms, including increased cellular uptake and/or trafficking to the nucleus of PEG/PEI nanocomplexes. We conclude that PEG/PEI nanocomplexes may be used to markedly enhance the amplitude of US-MB-targeted skeletal muscle transfection and that activating “small” MBs with a moderate level (0.6 MPa) of acoustic pressure can further enhance these effects.
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