A treatment method to reduce or eliminate a patient's symptoms caused by a medical condition or disease is disclosed. The treatment has the step of administering acoustic shock waves or pressure pulses directed to one or more reflexology zones or to one or more reflexology zones and an area near a source of the pain if any is exhibited to treat the medical condition. The treatment further has the steps of activating acoustic shock waves or pressure pulses of an acoustic shock wave or pressure pulse generator to emit acoustic shock waves or pressure pulses and subjecting the one or more reflexology zones or the one or more reflexology zones and the area near a source of the medical condition or pain, if any is exhibited, to acoustic shock waves or pressure pulses to treat the medical condition.

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 device for stimulating at least one cranial nerve and/or spinal nerve is described. The device includes a vibratory motor, and an earpiece, wherein the earpiece is molded substantially to fit within the external ear canal and contacting the concha of a subject's ear. A method of reducing migraine headache and trigeminal neuropathy pain is also described. The method includes positioning a vibratory earpiece within an ear of a subject, applying vibrational energy to at least a portion of the skin of at least one of the auditory canal, auricle and concha of the ear, thereby stimulating at least one sensory fiber of at least one of cranial nerve 5, cranial nerve 7, cranial nerve 9, cranial nerve 10, spinal nerve C2, and spinal nerve C3. A method to normalize breathing, normalize blood pressure, induce sleep, increase salivation, and improve vertigo, nausea, and visual dysfunction accompanying migraine is also described.

An auricular peripheral nerve field stimulator includes an electrical stimulation device for generating electrical stimulation signals, at least one therapy electrode electrically coupled to the stimulation device and configured for percutaneous insertion into an auricle of a human ear near at least one neurovascular bundle, a processor, and a memory with software executable by the processor to (i) control the stimulation device to generate and deliver to the inserted at least one therapy electrode the stimulation signals at a selected frequency with one of a positive and a negative pulse relative to a reference to stimulate at least one auricular peripheral nerve field within the auricle, (ii) continually repeat (i) for a first duration, (iii) following expiration of the first duration, control the stimulation device to generate no stimulation signals for a second duration, and (iv) repeat (i) through (iii) with the stimulation signals having a modulated frequency.

We disclose methods and medical device systems for selectively recruiting a nerve fiber type within a cranial nerve, a peripheral nerve or a spinal root. Such a method may comprise applying a first pressure, a heating, and/or a cooling to a second location of the nerve, the pressure, heating, or cooling sufficient to substantially block at least one of activation or conduction in at least one fiber population through the second location of the nerve for a blocking time period; and applying an electrical signal to a first location during the blocking time period.

A manual ear pump including one or more of a support element configured to releasably engage an external ear canal and having an interior chamber, a resilient element capable of being resiliently deformed coupled to a support element, and an aperture disposed on a support element bottom surface communicating with the external ear canal and interior chamber.

A system includes a processor configured to generate stimulation control signals in response to a detection of a respiratory disorder. The system further includes at least one kinesthetic effector with a vibrating electromechanical transducer applied to a site on a patient's skin for delivering a kinesthetic stimulation energy determined by the control signals. The processor is further configured to determine the effectiveness of a stimulation by detecting a cessation of the respiratory disorder. The processor is further configured to extend the stimulation control signals for a determined duration following the cessation of the respiratory disorder.

An electro-stimulation device where the innervation of the external ear canal is transcutaneously stimulated for treatment of neurological diseases. More particularly, an electrostimulation device having a cylindrical ear insert the surface of which contains at least one electrode being provided with a stimulation end adapted to be transcutaneously attached to the innervation of the external ear canal of a human. The electro-stimulation device is configured to stimulate anterior, superior, posterior or inferior positions of the external ear canal to stimulate simultaneously, sequentially or separately the trigeminal nerve, facial nerve, vagus nerve or glossopharyngeal nerve of the external ear canal. A control unit and a wireless communication unit are preferably placed in the cylindrical ear insert and the control unit is configured adjust the stimulation based on sensor signals such as motion sensor (accelerometer), video/image sensor (blinking movements), EEG, ECG, voice/swallowing sensor, temperature sensor.

The invention describes a non-electrically stimulation system, devices, and methods for non-invasive vibration stimulation procedures for treating, reducing and alleviating symptoms associated with pain, e.g., headache pain, migraine pain, and joint pain, stroke, mood, vascular action, breathing disorders during sleep and waking, limb, head and swallowing movement disorders, and sleep induction. The invention also describes a system, devices, and methods for non-invasive vibration stimulation procedures for retraining breathing.

An expansible ear canal insert for treating TMJ disorders and headaches which acts directly on the TMJ and associated ligament and muscle structures to reduce stress and loads placed on the articulator disc located between the temporal bone and the mandible, as well as supportive muscles and ligaments near the TMJ. The insert is adapted to expand by application of body heat. In the expanded condition, the insert provides support to the TMJ and associated ligament and muscle structures.