Vascular gene transfer and drug delivery in vitro using low-frequency ultrasound and microbubbles

Yang, Hong; Z, Liu; Liu, Yi-yao; Lou, Changchun; Ren, Zhenglong; Miyoshi, Hirokazu

doi:10.1038/aps.2010.21

Cited by 8 publications

(3 citation statements)

References 31 publications

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“…The use of low-frequency (20 kHz) and low-energy (3.77 W/cm 2 , 10% duty cycle) ultrasound in combination with bubbles (SonoVue) could be a promising physical method of increasing drug/gene delivery efficiency [56]. The dose of MBs injected into the tail vein of the mice was 0.2 mL for each treatment.…”

Section: Ultrasound Instruments and Microbubbles (Mbs)mentioning

confidence: 99%

Cavitation-Enhanced Delivery of the Nanomaterial Graphene Oxide-Doxorubicin to Hepatic Tumors in Nude Mice Using 20 kHz Low-Frequency Ultrasound and Microbubbles

Shen

et al. 2020

Journal of Nanomaterials

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Graphene oxide (GO) is a kind of nanomaterial. Here, we explored its application in tumor treatment. We loaded doxorubicin onto the surface of GO to form graphene oxide-doxorubicin (GO-DOX). After injection of the contrast agent SonoVue microbubbles (MBs) into the tail vein of tumor-bearing nude mice, subcutaneous hepatic carcinomas inoculated with the HepG2 cell line were irradiated with 20 kHz low-frequency ultrasound (US). Subsequently, GO-DOX was injected into the tail vein of nude mice. Transmission electron microscopy (TEM) and TUNEL assays were performed to observe the curative effects. Biocompatibility tests of GO-DOX included routine blood cell counts, blood smears, serum biochemical assays, and histological sampling of important organs. It was found that the nanomaterial GO-DOX promoted apoptosis of tumor cells in nude mice. TEM of the USMB+GO-DOX treatment showed vascular endothelial cell wall rupture, widened endothelial cell gaps, black granules in the vascular lumen, interstitial erythrocyte leakage, and apparent apoptosis of tumor cells. There were no toxic side effects of GO-DOX on the blood system and in the major organs of these mice. Ultrasound cavitation destroys tumor blood vessels and enhances the release of nanomaterials to tumor cells of nude mice.

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Section: Ultrasound Instruments and Microbubbles (Mbs)mentioning

confidence: 99%

Cavitation-Enhanced Delivery of the Nanomaterial Graphene Oxide-Doxorubicin to Hepatic Tumors in Nude Mice Using 20 kHz Low-Frequency Ultrasound and Microbubbles

Shen

et al. 2020

Journal of Nanomaterials

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“…Microbubble contrast agents which were targeted to diseased tissue by using certain chemical constituents in the microbubble shell or by attaching disease-specific ligands such as antibodies to the microbubble [21], play an important role in the ultrasound molecular imaging. On the other hand, there are also many indications that microbubbles could be widely applied as drugdelivery carriers, or to assist in drug/gene delivery [22][23][24][25][26].…”

Section: Introductionmentioning

confidence: 99%

Polymeric Microbubbles for Ultrasonic Molecular Imaging and Targeted Therapeutics

Xiong

Zhao

Shi

et al. 2011

Journal of Biomaterials Science, Polymer Edition

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Gas-filled microbubbles ultrasound agent have received wide attention, not only because they can improve ultrasound signals, but also they can be used as drug/gene carriers. Among all types of microbubbles fabricated by different membrane materials and core gases, polymer-shell microbubbles are highly promising. Polymeric microbubbles are more stable than other soft shell microbubbles in vivo. Under destructive ultrasound, polymer-stabilized microbubbles disintegrate and emit a strong non-linear signal, which enables ultrasound imaging with superior sensitivity. Except for ultrasound imaging, polymeric microbubbles could also be applied as drug/gene-delivery system. The thick polymeric shells allow loading a large amount of drugs. Meanwhile, site-specific targeting and controlled drug release in the area of interest can be realized through chemical and physical modification. In this review, we highlight some of the recent examples on polymeric microbubbles and their applications in ultrasound molecular imaging and drug delivery.

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“…If the goal is to produce the inertial cavitation in situ, a sound field with strong focus and low driving frequency (for example 0.5 MHz instead of 2 MHz) is recommended (Wu and Nyborg, 2008). Low-frequency ultrasound is a novel tool for the treatment of several areas such as blood-tumor barrier (Shang et al, 2011;Fan et al, 2011), local gene delivery (Lin et al, 2010;Yang et al, 2010), tumor cell destruction (Lagneaux et al, 2002;Ward et al, 1999;Sergeeva et al, 2001). However, the in vivo environment where low-frequency ultrasound exerts effects is different from that in vitro.…”

Section: Introductionmentioning

confidence: 99%

Low-frequency low-intensity ultrasound with contrast agent for the treatment of subcutaneous tumors in mice

Shen¹

2011

Sci. Res. Essays

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To determine the effects of ultrasound exposure in the presence of microbubble contrast agent (SonoVue) on the subcutaneous tumor of nude mice. Nude mice bearing subcutaneous tumor were prepared and treated with ultrasound. These animals were divided into three groups: control group (without treatment), low-frequency ultrasound group (US) and low-frequency ultrasound  contrast agent group (US+UCA). UCA was microbubble contrast agent (SonoVue). The tumors were exposed to pulsed ultrasound with a 40% duty cycle and an intensity of 26 MW/cm 2 at a frequency of 20 kHz for 3 minutes using a digital sonifier once every other day for two weeks. The damage to vascular endothelial cells was assessed via transmission electron microscopy (TEM). The protein expressions of VEGF and COX-2 of vessels were detected by Western blot assay. The percentage of tumor shrinkage in US UCA group was higher than US group and down-regulation of VEGF and COX-2 were detected in US  UCA group. After treatment, degeneration of endothelial cells, mitochondrial vacuolation and lumen occlusion were observed in the tumor of US  UCA group. These changes were seldom observed in the US group. Low-frequency ultrasound in the presence of contrast agent may exert therapeutic effect on subcutaneous tumor through destruct of the blood vessels in the tumor.

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Vascular gene transfer and drug delivery in vitro using low-frequency ultrasound and microbubbles

Cited by 8 publications

References 31 publications

Cavitation-Enhanced Delivery of the Nanomaterial Graphene Oxide-Doxorubicin to Hepatic Tumors in Nude Mice Using 20 kHz Low-Frequency Ultrasound and Microbubbles

Cavitation-Enhanced Delivery of the Nanomaterial Graphene Oxide-Doxorubicin to Hepatic Tumors in Nude Mice Using 20 kHz Low-Frequency Ultrasound and Microbubbles

Polymeric Microbubbles for Ultrasonic Molecular Imaging and Targeted Therapeutics

Low-frequency low-intensity ultrasound with contrast agent for the treatment of subcutaneous tumors in mice

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