An oxygen supply apparatus is configured to directly supply oxygen-containing gas to an user for inhalation while facilitating blood circulation of a specific portion of the user. The oxygen supply apparatus includes a power supply; an oxygen-containing gas source for providing the oxygen-containing gas; a gas catheter having one end thereof connected to the oxygen-containing gas source; an inhalator connected to the other end of the gas catheter; and a circulation facilitating device at least partially attached to the specific portion of the user. The circulation facilitating device includes a sonic oscillation circuit and a housing. The sonic oscillation circuit is configured to produce oscillation at a frequency ranging from 20 Hz to 10 MHz, and the housing encloses the sonic oscillation circuit in a watertight manner

The present disclosure relates generally to nanoparticle-based imaging, binding, and/or therapy at a targeted anatomical location within a subject. In particular, certain embodiments relate to intraluminal devices and systems configured to apply nanoparticles to an imaging target and/or treatment target within an anatomical lumen and to communicate imaging and/or treatment data wirelessly to one or more external devices.

First data comprising a first range of audio frequencies is received. The first range of audio frequencies corresponds to a predetermined cochlear region of a listener. Second data comprising a second range of audio frequencies is also received. Third data comprising a first modulated range of audio frequencies is acquired. The third data is acquired by modulating the first range of audio frequencies according to a stimulation protocol that is configured to provide neural stimulation of a brain of the listener. The second data and the third data are arranged to generate an audio composition from the second data and the third data.

A method is provided for achieving transfection of host cells using sonoporation. An acoustic radiation generator is positioned in acoustic coupling relationship with respect to a reservoir containing host cells to be transfected, exogenous material to be incorporated into the host cells, and a cell-compatible fluid medium. The acoustic radiation generator is activated to generate acoustic radiation and direct the acoustic radiation into the reservoir in a manner effective to enable transfection of the host cells with the exogenous material.

Methods and techniques for obtaining enriched cell samples from an organ in a subject using an ultrasound contrast agent and insonating. Contiguous fragments of epithelia are obtained which are useful for subsequent histological analysis and for informing therapy and other medical considerations.

Disclosed are a method for increasing the viability of a cell by irradiating the cell with ultrasonic waves, and an ultrasound irradiation apparatus using same, wherein in a state where each of ultrasonic parameters is preconfigured in a predetermined range, the ultrasonic irradiation apparatus places an ultrasonic generation unit within a threshold range from the epidermis of an object to irradiate the epidermis of the object with ultrasonic waves, the ultrasonic parameters include at least a pressure of ultrasonic waves and a duty percentage of the ultrasonic waves, the pressure of the ultrasonic waves is 0.5 MPa to 1 MPa, and the duty percentage of the ultrasonic waves is 1% to 5%.

A system and method for acquiring magnetic resonance (MR) images, with an MR system, of tissue proximal to a target treatment region in a patient, the tissue including a non-spatially uniform subcutaneous fat layer; in a computer comprising a hardware-based processor, automatically determining a thickness of the subcutaneous fat layer using a trained neural network, the neural network trained using manually-segmented MR images from previous patients; in the computer, automatically adjusting a treatment parameter based on the thickness of the subcutaneous fat layer; and delivering thermal therapy to the target treatment region with a high-intensity focused ultrasound system based on the adjusted treatment parameter.

Disclosed are methods of obtaining zero vergence ultrasound waves for providing sonodynamic therapy with ultrasound waves that do not converge and do not diverge. The method includes coupling a sonodynamic therapy device with an array of flat piezoelectric transducers to a skin surface. A controller is configured to generate an electrical drive signal at a frequency, modulate the drive signal, and drive the transducer with the modulated drive signal at the frequency to produce a zero vergence ultrasound wave to produce an average acoustic intensity sufficient to activate a sonosensitizer in a treatment region without damaging healthy cells in the treatment region.

A method for ultrasound stimulation of musculo-skeletal tissue structures includes generating a plurality of acoustic spatial-temporal modes comprised of a sinusoidal-complex, wherein the sinusoidal-complex has a modulation envelope that enhances spatial-temporal measurement accuracy at a site of a multi-layered biological tissue structure, and a pulse repetition frequency and duty cycle that are osteogenic at the site of the multi-layered biological tissue structure, beam steering the acoustic spatial-temporal modes to the site of the multi-layered biological tissue structure to promote tissue healing, and producing bi-modal stress levels in the multi-layered biological tissue structure that are sufficient to generate bone fracture healing.

A system for treating fat tissue, including: an ultrasound applicator, including: two or more ultrasound transducers configured to generate and direct ultrasonic waves to a selected tissue volume including fat tissue; a control unit, including: a control circuitry electrically connected to the two or more ultrasound transducers, wherein the control circuitry is configured to activate the two or more ultrasound transducers to heat the selected tissue volume.