A phased array of ultrasonic transducers may create arbitrary fields that can be utilized to manipulate fluids. This includes the translation of drops on smooth surfaces as well speeding the evaporation of fluids on wetted hands. Proposed herein is the use airborne ultrasound focused to the surface of the hand. The risk is that coupling directly into the bulk of the hand may cause damage to the cellular material through heating, mechanical stress, or cavitation. Using a phased array, the focus may be moved around, thus preventing acoustic energy from lingering too long on one particular position of the hand. While some signaling may penetrate into the hand, most of the energy (99.9%) is reflected. Also disclosed are methods to couple just to the wetted surface of the hand.

An apparatus for generating an acoustic energy pulse and delivering it into a body is described. The apparatus includes a generator for creating an acoustic energy pulse having an energy density field that can be measured at all points within a space in the shape of an imaginary cylinder having a length greater than or equal to 2 cm and a diameter. The cylindrically shaped space has a cylinder longitudinal axis oriented relative to a longitudinal axis of the energy pulse at an angle in the range from zero to twenty degrees. A minimum energy density for the pulse at all locations within the cylindrically shaped space is at least 50% of a maximum energy density for the pulse within the space.

Apparatuses and methods for generating therapeutic compressed acoustic waves (e.g., shock waves) with an improved acoustic wavefront. In the apparatuses, a housing is defined by a chamber and a shockwave outlet, the chamber is configured to be filed with liquid, a plurality of electrodes defining one or more spark gaps and an acoustic reflector can disposed in the chamber, and a pulse generation system configured to apply voltage pulses to the electrodes at a rate of between 10 Hz and 5 MHz. The improved acoustic wavefront is achieved via a free-form acoustic reflector and/or a stable spark gap location. The free-form acoustic reflector is designed according to a disclosed method including iterating reflector shape using spline interpolation based on defined variables. Additionally, a stable spark gap location is achieved via a single servomotor that adjusts both electrodes simultaneously.

The method of treating a patient addicted to pain medication or opioids has the step administering acoustic shock waves or pressure pulses to the patient. A second embodiment includes a treatment to reduce a patient's pain caused by a medical condition and/or medical procedure to reduce or eliminate the taking of addictive pain medication. The treatment has the step of administering acoustic shock waves or pressure pulses directed to an area near a source of the pain or to one or more reflexology zones or to one or more reflexology zones and to an area near the source of the pain or both to treat the medical condition or prior to the medical procedure or during the medical procedure or after the medical procedure or any combination thereof.

An apparatus for generating an acoustic energy pulse and delivering it into a body is described. The apparatus includes a generator for creating an acoustic energy pulse having an energy density field that can be measured at all points within a space in the shape of an imaginary cylinder having a length greater than or equal to 2 cm and a diameter. The cylindrically shaped space has a cylinder longitudinal axis oriented relative to a longitudinal axis of the energy pulse at an angle in the range from zero to twenty degrees. A minimum energy density for the pulse at all locations within the cylindrically shaped space is at least 50% of a maximum energy density for the pulse within the space.

A processor-controlled, energy-based therapy apparatus includes a pressure wave therapy device configured to provide therapeutic acoustic pulses to a patient and a processor that controls the output of the device. The pressure wave therapy device may include a control unit configured to control the pressure wave therapy device to deliver a treatment program, the treatment program comprising a plurality of acoustic pulses, each acoustic pulse comprising a pressure, the control unit including a memory storing patient-specific treatment information relating to a pain threshold of the patient; and a pain threshold indicator coupled to the control unit, the pain threshold indicator operable by the patient to provide an indication to the control unit of when a patient's pain threshold has been reached because an energy level delivered to the patient is unbearable.

A method of modulating glandular secretions by administering acoustic shock waves to a gland, includes the steps of activating acoustic shock waves of an acoustic shock wave generator to emit acoustic shock waves and subjecting the gland to acoustic shock waves stimulating the gland to have a modulated response. The modulated response is one of an adjustment in hormonal release which increases low level output, decreases high level output or stabilizes erratic output. The emitted acoustic shock waves are focused or unfocused low energy acoustic shock waves. The gland underlies the patient's skin. The shock wave generator is acoustically coupled to the patient's skin using a coupling gel or liquid. The gland is one of a testicle, ovary, pituitary gland, adrenal gland, thyroid gland, thymus, pineal gland, parathyroid, or hypothalamus. The method can be repeated one or more times.

Devices and methods for generating acoustic shock wave within a cavity is disclosed. The shock wave device optionally includes a housing having a cylindrical portion and a cone frustum portion. The housing optionally forms a cavity configured to receive a body appendage. The shock wave device optionally includes a plurality of shock wave generators and a coupling assembly having a deformable sac configured to hold shock wave transmitting liquid. The volume of the transmitting liquid is optionally increased or decreased as needed so that the coupling assembly can conform to the shape of the body appendage. The shock waves generated optionally has an intensity gradient within the cavity of the shock wave device, where the intensity gradient is optionally controllable using a control and power supply unit.

Hair cells are exquisitely sensitive to auditory stimuli, but also to damage from a variety of sources including noise trauma and ototoxic drugs. Mammals cannot regenerate cochlear hair cells, while non-mammalian vertebrates exhibit robust regenerative capacity. To allow for the effective examination of this process disclosed herein is a design and method of utilizing a device capable of inducing acoustic trauma in the larval lateral line. The device uses ultrasonic transducers to induce cavitation wherein microbubbles form in the fluid medium inside the container. These bubbles oscillate and then implode, sending shockwaves into the fluid inside the well-plate containing the fish. The device emits a broadband signal with peak sound energy in the low-frequency range below 200 Hz, consistent with the response range of the larval lateral line.

An apparatus for generating an acoustic energy pulse and delivering it into a body is described. The apparatus includes a generator for creating an acoustic energy pulse having an energy density field that can be measured at all points within a space in the shape of an imaginary cylinder having a length greater than or equal to 2 cm and a diameter. The cylindrically shaped space has a cylinder longitudinal axis oriented relative to a longitudinal axis of the energy pulse at an angle in the range from zero to twenty degrees. A minimum energy density for the pulse at all locations within the cylindrically shaped space is at least 50% of a maximum energy density for the pulse within the space.