Devices, systems and methods for non-invasive modulation of the baroreflex system of a patient. In embodiments, the present disclosure may be used to measure and monitor baroreflex function for diagnostic purposes in patients acutely or chronically to inform and guide medical treatment, assess disease severity, or assess morbidity/mortality risk. In embodiments, the present disclosure may be used to provide non-invasive baroreflex activation therapy acutely or chronically to treat a variety of disease conditions through rebalancing of the sympathetic and parasympathetic limbs of the autonomic nervous system and their connections to higher brain centers.

A method of relieving a hyperirritable area on or surrounding a mandible. The method may include steps of selecting a first head component from a set of head components of a myofascial release apparatus (MRA); connecting the first head component with a handle of the MRA; locating the hyperirritable area on or surrounding the mandible of a patient experiencing muscle tension; contacting the hyperirritable area, via a contact member of the first head component, on or surrounding the mandible of the patient; actuating a motor of the MRA, via an electrical control assembly of the MRA, from an OFF state to an ON state for vibrating the first head component at at least one predetermined frequency; and relieving the hyperirritable area on or surrounding the mandible. Optional steps may be included when using other head components provided in the set of head components.

Device and method for relieving muscle tension. The device includes three pairs of tips. Each pair is located, relative to the other two pairs of tips, at a vertex in a triangular orientation. Each pair of tips includes a unique horizontal distance in between the tips. Each tip is equidistant in height relative to its respective counterpart tip. The device also includes a connector configured to connect each tip to its counterpart tip. The connector is situated such that there is a pre-determined height differential between the apex of each pair of tips and the top of the connector. The apex of each pair of tips is vertically longer than the height of the connector.

An exercise device comprising a bendable pole with spring-like properties. The bendable pole has grips at opposing ends and in a midsection. The exercise device is configured to be used for a variety of exercise methods. The exercise device provides personal fitness tracking in conjunction with a mobile software application.

A device includes a first vibrational transducer and a second vibrational transducer. The first vibrational transducer has a first vibrating property. The second vibrotactile stimulator has a second vibrating property different than the first vibrating property. A collar may be configured to position the first vibrational transducer and the second vibrational transducer over a neck of a subject. A method for stimulating swallowing in a subject includes applying a first vibrotactile stimulation and applying a second vibrotactile stimulation to a throat area of the subject. The first vibrotactile stimulation has a first vibrating property and the second vibrotactile stimulation has a second vibrating property different than the first vibrating property. Example vibrating properties include vibrating frequency, vibrating frequency range, wave shape, continuousness, frequency phase, and direction of mechanical force.

Apparatus and associated methods relate to a wearable compression therapy system for ambulatory therapy, the system including a wearable garment having one or more inflatable chambers, and a pneumatic engine locally coupled to the garment to provide control and inflation of the one or more inflatable chambers. In an illustrative embodiment, the pneumatic engine may control a pump and one or more valves to inflate the inflatable chambers. The valves and pump may be coordinated according to a pre-programmed profile. In some embodiments, the pneumatic engine may have a wireless interface configured to receive control signals from a remote mobile device untethered from the garment. The pneumatic engine may send to the remote mobile device signals indicative of sensed conditions of the compression therapy system. In some embodiments, the pneumatic engine may include a power source that advantageously permits the user to be untethered from a source of power.

Devices, systems and methods are provided for treating migraine headaches and other conditions by non-invasive electrical stimulation of nerves and other tissue. A hand-held device includes a housing with a controller having a signal generator, an electrode for delivering electrical signals, and a conductive surface configured as a return path for the electrical signals. In certain implementations, the electrode is repositionable with respect to the housing. The patient can self-apply the hand-held device by pressing it against areas in need of pain relief. The device may include a pressure-sensitive gating switch to control delivery of the stimulation therapy. In certain embodiments, the electrode is a rollerball electrode. The device may include a chamber for retaining and dispensing conductive gel to the therapy site. In certain approaches, the device includes an electrode support for coupling an electrical stimulation system to the head for hands-free electrical stimulation therapy.

A training apparatus is disclosed, comprising: a top structure, a bottom structure, and a traction structure disposed between the top structure and the bottom structure, and wherein the traction structure is configured to be retractable along an axial direction of the top or bottom structure to achieve relative movement between the top structure and the bottom structure.

A system for treating a joint of a patient includes a treatment head including a probe, a force impulse wave sensor, and a pressure sensor. When the probe is pressed against the joint and reaches a predetermined pressure, the pressure sensor causes a release of current such that the probe delivers a mechanical force impulse to the joint. The force impulse wave sensor is configured to sense a frequency of the mechanical force impulse associated with a treatment point of the joint. The treatment head remains in the same target spot during the pre-test, treatment, and post-test. The system is configured to perform the pretest and post-test analysis of the plurality of treatment points to evaluate improvement of the joint after the treatment. The treatment protocol for the treatment point is modified based on the sensed frequency of the mechanical force impulse from the pre-test at the treatment point.

A laryngeal nerve exciting system includes a collar holding a bridge, or a neckband, pressing soft tissue nerve exciters against a patient's neck providing a source of vibrations to stimulate the laryngeal nerve through the larynx. At least one exciter, and preferably two exciters, provide vibrations at preferably 70 Hz to 110 Hz and sufficiently strong to penetrate to the laryngeal nerve. The exciters may be held by the collar circling the neck, or by the neck band partially circling the neck. The therapy system includes a Personal Digital Assistant (PDA) and software which wirelessly connects, monitors, and triggers the device. The system may be used to treat dysphagia, chronic cough, and spasmodic dysphonia.