Abstract
High intensity focused ultrasound therapeutics are widely used to noninvasively treat various types of primary tumors and metastasis. However, ultrasound penetration depth is shallowed with increasing frequency which limits the therapeutic accuracy for deep tissues. Although acoustic waveguides are commonly inserted into tissue for localized therapy, powerful ultrasound delivery is difficult. Here, we invent double-parabolic-reflectors acoustic waveguides, where high-power ultrasound emission and large mechanical vibration enhance the therapeutic efficiency. High-energy-density ultrasound with around 20 times amplification by two parabolic reflectors propagates through the thin waveguide between 1 to 2 MHz, and wideband large mechanical vibration at the waveguide tip from 1 kHz to 2.5 MHz accelerates the therapeutics. This fundamental work serves as a milestone for future biomedical applications, from therapeutics to diagnostics. Since the high-power ability at high frequencies, our waveguide will also open up new research fields in medical, bio, physics and so on.
Highlights
High intensity focused ultrasound therapeutics are widely used to noninvasively treat various types of primary tumors and metastasis
Waveguides are required to be thinner than several mm for minimally invasive treatments[23,24,25,26,27,28], large diameter difference exists between piezoelectric element (PZT) and waveguides, which limits the amount of energy being directly transmitted to the waveguides
Speaking, we have proved that the proposed acoustic waveguide can generate powerful ultrasound that is over one order-of-magnitude of conventional configuration in acoustic pressure and over two orders-of-magnitude in power[32]
Summary
High intensity focused ultrasound therapeutics are widely used to noninvasively treat various types of primary tumors and metastasis. High-energy-density ultrasound with around 20 times amplification by two parabolic reflectors propagates through the thin waveguide between 1 to 2 MHz, and wideband large mechanical vibration at the waveguide tip from 1 kHz to 2.5 MHz accelerates the therapeutics. This fundamental work serves as a milestone for future biomedical applications, from therapeutics to diagnostics. The available designs are suffering from limited energy source (large diameter difference between piezoelectric element and waveguide)[20,21] and energy loss during transmission (multiple changes of transmission mediums)[22], so, high-power transmission had been impossible. This proposal will provide a new solution for accurate minimally invasive ultrasound therapeutics
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