Embodiments of the present disclosure are directed to systems, devices, and methods of inducing physical effects in tissue, such as dermis, adipose, musculoskeletal, vascular, hepatic tissue, using unfocused or planar, non-cavitating acoustic shock waves. The physical effects include disruption of fibrous extracellular matrix of the targeted tissues. Embodiments of the present disclosure include applying rapid acoustic pulses (e.g., shock waves) to cause a breakdown in the fibrous extracellular matrix to reduce the appearance of cellulite or scars in a treatment area. Such unfocused or planar, non-cavitating acoustic shock waves may induce a tissue reaction, such as reduction of fibrosis, induction of angiogenesis, or lymphangiogenesis.

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.

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.

A system and a method of turnkey neurological solution to provide a variety of stimulations including photo-stimulation, binaural stimulation, and electro-acupuncture in wearable form, such as in glasses. Light may be generated from at least one light source powered by integrated photovoltaic cells and amplified light may be sent to a predetermined direction through the at least one angularly oriented optical window in which one face is covered by an optical film or coating. Also, the system and method may provide that, as an optical window is fabricated, photovoltaics may be fused directly to faces of the optical window for absorption of ambient light energy, and a light source may be fused into grooves on the edge of the optical window, with nanoelectrodes attached for electrical connections to controllers inserted in a housing. It may also be contemplated to provide binaural stimulation and electro-acupuncture effectors on the wearable device.

A mat assembly that includes a mat that includes a top layer and a bottom layer, a plurality of vibration motors positioned between the top layer and the bottom layer, a plurality of sensors associated with the mat, a removable battery pack, and a controller. In use, a first set of vibration motors within the plurality of vibration motors is configured to be actuated when a first one of the plurality of sensors is actuated.

A handheld acoustic shock wave or pressure pulse applicator device has a body structure and an applicator head. The body structure has a proximal end and a distal end with a longitudinal axis extending between the ends. The applicator head is at the distal end. the head emits pressure pulses or shock waves at an inclined angle relative to the longitudinal axis of the body structure. The applicator head has a balloon or lens or membrane through which the emitted pressure pulses or shock waves pass. The lens or membrane is configured to be coupled directly or indirectly to an exposed soft tissue surface of a palate inside a patient's mouth to direct emitted pressure pulses or shock waves to the brain. The applicator device can be configured with the inclined obtuse angle fixed between 150 degrees and 90 degrees or can be adjustable between 180 degrees and 90 degrees.

A treatment device includes a housing having a longitudinal axis extending between a proximal end and a distal end, a motor, a drive shaft operatively coupled to the motor, a compression spring at least partially disposed about the drive shaft, a helical cam disposed adjacent the compression spring, the helical cam having at least one discontinuity, a hammer coupled to the helical cam and moveable therewith, and a tip disposed adjacent the distal end.

A therapeutic device for treating one or more conditions associated with a user's nasal cavities, sinuses, and/or ear canals includes a housing having an opening, an acoustic vibrator within the housing that is operable to provide an acoustic vibration to the user, a fan within the housing that is operable to provide a pressure to the user and a power supply that provides power to the acoustic vibrator and the fan. A mask is connected to the housing at the opening and includes a nasal interface appliable around the nose of the user, a nasal chamber in which the user's nostrils are located and an aperture through which the fan delivers the pressure.

The present invention generally relates to improved medical devices, systems, and methods, with exemplary embodiments providing improved cooling treatment probes and cooling treatment methods and systems. In some embodiments, freezing of the skin may be desirable to effect the hypopigmentation of the skin of the patient. Generally, embodiments may limit supercooling of the skin of the patient during a cooling treatment. Additionally, embodiments may limit adverse side effects such as hyperpigmentation. It has been found that the freezing behavior (frequency and time to freeze) can be modified by adjusting the thermal parameters of the cooling applicator. Accordingly, in some aspects of the invention, a method of treating the skin may be provided where the thermal parameters of the cooling applicator are adjusted during treatment.

A method of treatment includes using an electrical energizing source coupled to a current conducting coil to cause the current conducting coil to produce pulsed electromagnetic fields. A conducting membrane is placed adjacent the current conducting coil and an insulating coupling interface is placed adjacent the membrane, such that the membrane is between the current conducting coil and the insulating coupling interface. One portion of the pulsed electromagnetic fields is intercepted by the membrane so that the membrane oscillates to generate acoustic waves to tissue adjacent the insulating coupling interface and another portion of the pulsed electromagnetic fields propagates through the insulating coupling interface to the tissue.