Laser-enhanced cavitation during high intensity focused ultrasound: An <i>in vivo</i> study

Cui, Huizhong; Zhang, Ti; Yang, Xinmai

doi:10.1063/1.4800780

Cited by 23 publications

(14 citation statements)

References 30 publications

(35 reference statements)

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“…Hu et al demonstrated that combined laser and ultrasound can be used to selectively target micro‐vessels without damaging the surrounding . Similar studies have described how combined laser and ultrasound resulted in increased cavitation , which has been used with optically absorbent nanoparticles for targeted cavitation . These previous ablation studies have looked at internal applications, while this study intends to explore dermatological applications.…”

Section: Introductionmentioning

confidence: 79%

Enhanced laser surface ablation with an integrated photoacoustic imaging and high intensity focused ultrasound system

Hazlewood

Yang

2019

Lasers Surg Med

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Background and Objective Combined laser and ultrasound treatments have been found to have synergistic effects, which may be of particular note in dermatology. We aim to investigate the potential of this technology for dermatology through in vitro and ex vivo experiments. Methods In vitro tissue phantoms made of agar and tattoo ink and tattooed ex vivo chicken breast tissue were used. An integrated photoacoustic imaging and high intensity focused ultrasound (HIFU) system, using a 5‐ns tunable OPO laser system and a 5 MHz HIFU transducer, was used to perform photoacoustic analysis to identify the optical contrast, and perform combined laser and ultrasound ablation. On the tissue phantoms, lines of ablation were created under various operating conditions. The samples were then quantified to determine the level of ablation. Same procedures were performed on the tattooed chicken breast tissue and the tattoo was removed by using combined laser and ultrasound. Results Ablation in the in vitro tissue phantoms was observed with properly synchronized laser and ultrasound while no ablation was found with either laser or ultrasound alone. Increases to the intensity or pulse duration of ultrasound caused an increase in ablation to the samples. The tattoo was removed from the ex vivo chicken breast using combined laser and ultrasound with a radiant exposure of 1.2 J/cm2 while laser and ultrasound alone were unable to remove the tattoo. Conclusions We determined that by supplementing nanosecond laser pulses with ultrasound, ablation, and tattoo removal can be achieved at laser radiant exposures levels would otherwise be ineffective. The area of ablation can be adjusted through changes in the intensity and duration of the ultrasound burst with a constant laser intensity. Additionally, the system can be used to perform photoacoustic analysis of the tissue to estimate the relative optical absorbance at various available wavelengths, allowing for pretreatment analysis. Lasers Surg. Med. 9999:1–9, 2019. © 2019 Wiley Periodicals, Inc.

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Section: Introductionmentioning

confidence: 79%

Enhanced laser surface ablation with an integrated photoacoustic imaging and high intensity focused ultrasound system

Hazlewood

Yang

2019

Lasers Surg Med

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“…a blood vessel), the laser-induced photoacoustic wave can converge into the center and achieve a significantly high acoustic pressure and produce cavitation44, which is referred to as “cold bubbles” and has been observed in cells45. Unlike other use of therapeutic ultrasound and laser irradiation4647484950, when ultrasound and laser irradiation are concurrently applied, a portion of the ultrasound waves can modulate the transient thermal-elastic negative stress produced through photospallation, which will increase the cavitation efficiency because of the greater negative pressure31. One of the key features of photoacoustic cavitation is that cavitation may be induced at a laser energy level that is much lower than that needed for laser thermal therapies (such as photothermolysis and photocoagulation) because photoacoustic cavitation is not a strictly thermal effect.…”

Section: Discussionmentioning

confidence: 99%

“…When a laser pulse is absorbed by hemoglobin, the tissue is excited and the photoacoustic effect occurs. The concurrent application of ultrasound significantly increases the likelihood of micro-cavitation in the blood vessel31. The produced cavitation can then be further enhanced and driven by the subsequent ultrasound pulses.…”

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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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“…Hydrophobic particulates (Soltani 2013), perfluorocarbon droplets (Pajek et al 2014) and focused laser pulses (Cui et al 2013) have been used to nucleate cavitation effectively during sonothrombolysis. However, ultrasound contrast agents (UCAs), or stabilized microbubbles, are also used to nucleate cavitation.…”

Section: 2 Mechanisms Of Thrombolytic Enhancementmentioning

confidence: 99%

Sonothrombolysis

Bader¹,

Bouchoux²,

Holland³

2016

Advances in Experimental Medicine and Biology

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Thrombo-occlusive disease is a leading cause of morbidity and mortality. In this chapter, the use of ultrasound to accelerate clot breakdown alone or in combination with thrombolytic drugs will be reported. Primary thrombus formation during cardiovascular disease and standard treatment methods will be discussed. Mechanisms for ultrasound enhancement of thrombolysis, including thermal heating, radiation force, and cavitation, will be reviewed. Finally, in-vitro, in-vivo and clinical evidence of enhanced thrombolytic efficacy with ultrasound will be presented and discussed.

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Laser-enhanced cavitation during high intensity focused ultrasound: An in vivo study

Cited by 23 publications

References 30 publications

Enhanced laser surface ablation with an integrated photoacoustic imaging and high intensity focused ultrasound system

Enhanced laser surface ablation with an integrated photoacoustic imaging and high intensity focused ultrasound system

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

Sonothrombolysis

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