An apparatus comprises a vibrational transducer, a placement band, a driver module and a control module. The placement band is configured to hold the vibrational transducer adjacent to the skin surface overlying the cricoid cartilage and trachea region of a patient's neck. The driver module is configured to apply a drive signal to the vibrational transducer. The control module is configured to receive at least one input configured to provide vibrational operating information and control the driver module to cause the vibrational transducer to apply a vibratory stimulation in an amount determined, at least in part, by the vibrational operating information.

A method of treating an infected implant by administering acoustic shock waves to an implant area or region encompassing an implantation, includes the steps of activating acoustic shock waves of an acoustic shock wave generator to emit acoustic shock waves and subjecting the implant area to acoustic shock waves stimulating the implant area or region. The emitted acoustic shock waves are focused or unfocused acoustic shock waves, or acoustic pressure waves, generated electrohydraulically, electromagnetically, radially, or via a piezo electric generating system.

A system for treating soft tissue of a patient. The system includes a treatment head and a computer portion. The treatment head includes a probe and an electrode operably coupled to the probe. The probe and electrode are configured to respectively deliver a mechanical force impulse and an electrical stimulation to the soft tissue when placed in operable contact with the soft tissue. The computer portion includes a CPU and is configured to coordinate the delivery of the mechanical force impulse and electrical stimulation relative to each other. The system is configured to sense a shockwave in the soft tissue of the patient, the shockwave resulting from the mechanical force impulse delivered to the soft tissue via the probe. The system is also configured to analyze a characteristic of the sensed shockwave and configure the electrical stimulation to be delivered to the soft tissue via the electrode based on the characteristic analysis of the sensed shockwave. The characteristic may be at least one of frequency of the sensed shockwave, amplitude of the sensed shockwave, and/or wave shape (form) of the sensed shockwave.

Systems and methods for treatment using acoustic shock waves within an enclosed negative pressure chamber to fragment or otherwise to modify plaque in a patient's penile shaft.

Systems and methods for treating Peyronie's disease, including systems for generating acoustic shock waves within an enclosed negative pressure chamber to fragment or otherwise modify plaque in a patient's penile shaft.

A soliton beam useful in influencing material in a target structure is described. Such a soliton beam can be generated suing a plasma antenna to generate an electromagnetic carrier wave, λ. The confined plasma antenna also pulses the carrier wave at a sonic frequency, f, to create a sonic wave. Pulsing the carrier wave results in a soliton beam having a sequential plurality of solitons which are separated from each other by a periodicity p, wherein λ<<p.

Systems and methods for treating cognitive dysfunction are disclosed. The system can include a sound source, a light source, an input device, and a neural stimulation system that retrieves or selects a stimulation profile. The stimulation profile can include one or more musical pieces for playback and one or more rhythmic stimulation patterns having variable parameters, and time-varying signal properties that can be tuned to music. The system can select the signal properties of rhythmic stimulation based on analysis of the music, measure the physiological condition of the subject, and further adjust the rhythmic stimulation based on neural responses. The neural stimulation system can play back the selected musical pieces to direct sound toward the ear, or respond to ambient musical sounds detected by a microphone, and set the values of the variable parameters and properties of the rhythmic pattern, construct an output signal, and provide an output signal.

The present invention pertains to a medical treatment device (10) for stimulating neurons of a patient to suppress a pathologically synchronous activity of the neurons. The device (10) comprises a non-invasive stimulation unit (12) configured for simultaneously administering at least one acoustic stimulus and at least one non-acoustic stimulus to a patient's body, each of which is configured to suppress the pathologically synchronous activity when being administered to the patient's body.

A method of treating neurodegeneration in a subject that includes administering a non-invasive tactile stimulus having a stimulus frequency of about 30 Hz to about 50 Hz to a subject to induce synchronized gamma oscillations in at least one portion of the peripheral nervous system of the subject, of the spinal cord of the subject, or both.

A self-contained reciprocation mechanism is coupleable within an enclosure of a percussive massage device and is configured to receive an applicator head for stimulating a user's muscles. The self-contained reciprocation mechanism includes a spatial positioning bracket, a semi-cylindrical bracket, a piston, a motor, a crank, and a reciprocation linkage. The spatial positioning bracket is configured to receive the other interconnected components of the self-contained reciprocation mechanism and position said components relative to each other at close predetermined tolerances to assure that the interconnected components are properly positioned to provide consistent operating characteristics. The self-contained reciprocation mechanism is coupled within the enclosure using screws which extend through mounting tabs of the spatial positioning bracket.