Min Joo Choi scite author profile

High-intensity focused ultrasound therapy is a novel, emerging, therapeutic modality that uses ultrasound waves, propagated through tissue media, as carriers of energy. This completely non-invasive technology has great potential for tumor ablation as well as hemostasis, thrombolysis and targeted drug/gene delivery. However, the application of this technology still has many drawbacks. It is expected that current obstacles to implementation will be resolved in the near future. In this review, we provide an overview of high-intensity focused ultrasound therapy from the basic physics to recent clinical studies with an interventional radiologist's perspective for the purpose of improving the general understanding of this cutting-edge technology as well as speculating on future developments.

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Temperature-Dependent Thermal Properties of ex Vivo Liver Undergoing Thermal Ablation

Guntur

Lee

Paeng

et al. 2013

Ultrasound in Medicine & Biology

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Changes in Ultrasonic Properties of Liver Tissue In Vitro During Heating-Cooling Cycle Concomitant with Thermal Coagulation

Choi

Guntur

Lee

et al. 2011

Ultrasound in Medicine & Biology

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Acoustic emission and sonoluminescence due to cavitation at the beam focus of an electrohydraulic shock wave lithotripter

Coleman

Choi

Saunders

et al. 1992

Ultrasound in Medicine & Biology

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Histological correlates of optical coherence tomography in non‐melanoma skin cancer

Coleman

Richardson

Orchard

et al. 2012

Skin Research and Technology

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A Tissue Mimicking Polyacrylamide Hydrogel Phantom for Visualizing Thermal Lesions Generated by High Intensity Focused Ultrasound

Choi¹,

Guntur²,

Lee³

et al. 2013

Ultrasound in Medicine & Biology

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Songwriting oriented activities improve the cognitive functions of the aged with dementia

Hong

Choi

2011

The Arts in Psychotherapy

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Empirical angle-dependent Biot and MBA models for acoustic anisotropy in cancellous bone

et al. 2006

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The Biot and the modified Biot-Attenborough (MBA) models have been found useful to understand ultrasonic wave propagation in cancellous bone. However, neither of the models, as previously applied to cancellous bone, allows for the angular dependence of acoustic properties with direction. The present study aims to account for the acoustic anisotropy in cancellous bone, by introducing empirical angle-dependent input parameters, as defined for a highly oriented structure, into the Biot and the MBA models. The anisotropy of the angle-dependent Biot model is attributed to the variation in the elastic moduli of the skeletal frame with respect to the trabecular alignment. The angle-dependent MBA model employs a simple empirical way of using the parametric fit for the fast and the slow wave speeds. The angle-dependent models were used to predict both the fast and slow wave velocities as a function of propagation angle with respect to the trabecular alignment of cancellous bone. The predictions were compared with those of the Schoenberg model for anisotropy in cancellous bone and in vitro experimental measurements from the literature. The angle-dependent models successfully predicted the angular dependence of phase velocity of the fast wave with direction. The root-mean-square errors of the measured versus predicted fast wave velocities were 79.2 m s(-1) (angle-dependent Biot model) and 36.1 m s(-1) (angle-dependent MBA model). They also predicted the fact that the slow wave is nearly independent of propagation angle for angles about 50 degrees , but consistently underestimated the slow wave velocity with the root-mean-square errors of 187.2 m s(-1) (angle-dependent Biot model) and 240.8 m s(-1) (angle-dependent MBA model). The study indicates that the angle-dependent models reasonably replicate the acoustic anisotropy in cancellous bone.

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Min Joo Choi

High-Intensity Focused Ultrasound Therapy: an Overview for Radiologists

Temperature-Dependent Thermal Properties of ex Vivo Liver Undergoing Thermal Ablation

Changes in Ultrasonic Properties of Liver Tissue In Vitro During Heating-Cooling Cycle Concomitant with Thermal Coagulation

Acoustic emission and sonoluminescence due to cavitation at the beam focus of an electrohydraulic shock wave lithotripter

Histological correlates of optical coherence tomography in non‐melanoma skin cancer

A Tissue Mimicking Polyacrylamide Hydrogel Phantom for Visualizing Thermal Lesions Generated by High Intensity Focused Ultrasound

Songwriting oriented activities improve the cognitive functions of the aged with dementia

Empirical angle-dependent Biot and MBA models for acoustic anisotropy in cancellous bone

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