Droplets, Bubbles and Ultrasound Interactions

Shpak, Oleksandr; Verweij, Martin D.; Jong, Nico de; Versluis, Michel

doi:10.1007/978-3-319-22536-4_9

Cited by 32 publications

(33 citation statements)

References 39 publications

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“…Indeed, recent reports have demonstrated that application of laser-generated focused ultrasound to microgels can enhance drug release kinetics 8,9 . While the effect of ultrasound of microgel deformability has not been studied previously, interactions between ultrasound and highly deformable droplets and microbubbles have been studied in the last few decades for diagnostic and therapeutic applications 10 . Ultrasound contrast agent (UCA) microbubbles are used in combination with ultrasound insonification for numerous applications, including contrast-enhanced ultrasound imaging 11,12 , enhancing effectiveness of High Intensity Focused Ultrasound (HIFU) treatments 13 , multiple scattering based quantitative ultrasound tissue characterization 14 , targeted drug delivery 15 , enhancing drug uptake by tumors 16 , and non-invasive molecular imaging 17 .…”

Section: Introductionmentioning

confidence: 99%

Study of Poly(N-isopropylacrylamide-co-acrylic acid) (pNIPAM) Microgel Particle Induced Deformations of Tissue-Mimicking Phantom by Ultrasound Stimulation

Joshi¹,

Nandi

Chester

et al. 2018

Langmuir

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Poly (N-isopropylacrilamide) (pNIPAm) microgels (microgels) are colloidal particles that have been used extensively for biomedical applications. Typically, these particles are synthesized in the presence of an exogenous cross-linker, such as N, N′-Methylenebis (acrylamide) (BIS); however, recent studies have demonstrated that pNIPAm microgels can be synthesized in the absence of an exogenous crosslinker, resulting in the formation of ultra-low crosslinked (ULC) particles, which are highly deformable. Microgel deformability has been linked in certain cases to enhanced bioactivity when ULC microgels are used for the creation of biomimetic particles. We hypothesized that ultrasound stimulation of microgels would enhance particle deformation and that the degree of enhancement would negatively correlate with the degree of particle crosslinking. Here, we demonstrate in tissue-mimicking phantoms that using ultrasound insonification causes deformations of ULC microgel particles. Furthermore, the amount of deformation depends on the ultrasound excitation frequency and amplitude, and on the concentration of ULC microgel particles. We observed that the amplitude of deformation increases with increasing ULC microgel particle concentration up to 2.5 mg / 100 ml, but concentrations higher than 2.5 mg / 100 ml result in reduced amount of deformation. In addition, we observed that the amplitude of deformation was significantly higher at 1 MHz insonification frequency. We also report that increasing the degree of microgel crosslinking reduces the magnitude of the deformation and increases the optimal concentration required to achieve the largest amount of deformation. Stimulated ULC microgel particle deformation has numerous potential biomedical applications, including enhancement of localized drug delivery and biomimetic activity. These results demonstrate the potential of ultrasound stimulation for such applications.

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Section: Introductionmentioning

confidence: 99%

Study of Poly(N-isopropylacrylamide-co-acrylic acid) (pNIPAM) Microgel Particle Induced Deformations of Tissue-Mimicking Phantom by Ultrasound Stimulation

Joshi¹,

Nandi

Chester

et al. 2018

Langmuir

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“…Additional antivascular approaches include photodynamic therapy (PDT)18192021, embolotherapy22232425, antivascular ultrasound therapy (AVUT)262728, and photothermolysis29. These approaches have been developed to shut down or destroy existing blood vessels.…”

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confidence: 99%

High-precision, non-invasive anti-microvascular approach via concurrent ultrasound and laser irradiation

Zhang

Mordovanakis

et al. 2017

Sci Rep

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Antivascular therapy represents a proven strategy to treat angiogenesis. By applying synchronized ultrasound bursts and nanosecond laser irradiation, we developed a novel, selective, non-invasive, localized antivascular method, termed photo-mediated ultrasound therapy (PUT). PUT takes advantage of the high native optical contrast among biological tissues and can treat microvessels without causing collateral damage to the surrounding tissue. In a chicken yolk sac membrane model, under the same ultrasound parameters (1 MHz at 0.45 MPa and 10 Hz with 10% duty cycle), PUT with 4 mJ/cm2 and 6 mJ/cm2 laser fluence induced 51% (p = 0.001) and 37% (p = 0.018) vessel diameter reductions respectively. With 8 mJ/cm2 laser fluence, PUT would yield vessel disruption (90%, p < 0.01). Selectivity of PUT was demonstrated by utilizing laser wavelengths at 578 nm or 650 nm, where PUT selectively shrank veins or occluded arteries. In a rabbit ear model, PUT induced a 68.5% reduction in blood perfusion after 7 days (p < 0.001) without damaging the surrounding cells. In vitro experiments in human blood suggested that cavitation may play a role in PUT. In conclusion, PUT holds significant promise as a novel non-invasive antivascular method with the capability to precisely target blood vessels.

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“…Moreover droplets are more stable than gas bubbles in blood circulation at 37°C because droplets maintain their liquid core in the circulation avoiding gas dissolution (Lanza and Wickline, 2001;Lea-Banks et al, 2019). Stable PFC emulsions, commonly used droplets, can be prepared to~200 nm in diameter (Fabiilli et al, 2010), which is beneficial for circulating for a longer time in vivo, passing into tissues or cells, and enhancing the EPR effect (Shpak et al, 2016). More interestingly, Lattin et al (2015) supposed that the disruption of droplets may break down the membrane of endosome to aid the escape from the endosome endocytosis pathway of macromolecules such as genes.…”

Section: Dropletsmentioning

confidence: 99%

Ultrasound-Responsive Materials for Drug/Gene Delivery

et al. 2020

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Ultrasound is one of the most commonly used methods in the diagnosis and therapy of diseases due to its safety, deep penetration into tissue, and non-invasive nature. In the drug/gene delivery systems, ultrasound shows many advantages in terms of site-specific delivery and spatial release control of drugs/genes and attracts increasing attention. Microbubbles are the most well-known ultrasound-responsive delivery materials. Recently, nanobubbles, droplets, micelles, and nanoliposomes have been developed as novel carriers in this field. Herein, we review advances of novel ultrasound-responsive materials (nanobubbles, droplets, micelles and nanoliposomes) and discuss the challenges of ultrasound-responsive materials in delivery systems to boost the development of ultrasound-responsive materials as delivery carriers.

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Droplets, Bubbles and Ultrasound Interactions

Cited by 32 publications

References 39 publications

Study of Poly(N-isopropylacrylamide-co-acrylic acid) (pNIPAM) Microgel Particle Induced Deformations of Tissue-Mimicking Phantom by Ultrasound Stimulation

Study of Poly(N-isopropylacrylamide-co-acrylic acid) (pNIPAM) Microgel Particle Induced Deformations of Tissue-Mimicking Phantom by Ultrasound Stimulation

High-precision, non-invasive anti-microvascular approach via concurrent ultrasound and laser irradiation

Ultrasound-Responsive Materials for Drug/Gene Delivery

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