A treatment device includes a housing having a longitudinal axis extending between a proximal end and a distal end, a striking element disposed within the housing and moveable along the longitudinal axis, a tip disposed adjacent the distal end, and a nose cone disposed about at least a portion of the tip, the tip being moveable within the nose cone.

Implantable devices and/or sensors can be wirelessly powered by controlling and propagating electromagnetic waves in a patient's tissue. Such implantable devices/sensors can be implanted at target locations in a patient, to stimulate areas such as the heart, brain, spinal cord, or muscle tissue, and/or to sense biological, physiological, chemical attributes of the blood, tissue, and other patient parameters. The propagating electromagnetic waves can be generated with sub-wavelength structures configured to manipulate evanescent fields outside of tissue to generate the propagating waves inside the tissue. Methods of use are also described.

A respiratory acoustic analysis system for sensing and analyzing respiratory sounds of a patient may include a High Frequency Chest Wall Oscillation (HFCWO) vest, at least one sensor coupled with the HFCWO vest, and an algorithm stored in a processor for processing sensed data from the at least one acoustic sensor to provide processed data describing the respiratory sounds of the patient, in a form that can be used by a physician or other user.

A percussive adjusting instrument is provided which includes a percussive instrument head and a traversing arm that couples to the percussive instrument head. The percussive instrument head is movable with respect to the traversing arm. A vertical arm supports the traversing arm. The vertical arm also pivots the traversing arm and the percussive instrument head about an axis. A pivot assembly allows movement of the vertical arm and the percussive instrument head.

Systems and processes for determining pressure settings for a percussive massage applicator are described. According to one embodiment, a method comprises obtaining an operational current measurement of the motor when the motor has a load. difference value is determined between the current measurement and the operational current measurement. The difference value is compared to two or more predetermined ranges of values that correspond to a pressure level of the percussive applicator. The pressure level may be provided as feedback to the user.

A treatment device includes a housing having a longitudinal axis extending between a proximal end and a distal end, a striking element disposed within the housing and moveable along the longitudinal axis, a tip disposed adjacent the distal end, and a nose cone disposed about at least a portion of the tip, the tip being moveable within the nose cone.

An oscillating health device includes a top cover and a bottom cover. The top cover and the bottom cover, each of which is made of a titanium sheet and molded in a metal stamping process, are welded together for development of a box body. The box body is provided with a drive element unit inside, and both the top cover and the bottom cover accommodate an oscillating hoop in between. The drive element unit enables a lamina lever of the oscillating hoop to induce vibrations which are transferred to the box body for generation of regular low-frequency oscillation, so that a health effect can be produced when the box body is in contact with a user's human body.

In some embodiments, a method may include clearing a biological airway. The method may include positioning an inner wearable harness on a torso of a subject. The method may include selectively positioning at least some of a plurality of engines on and/or adjacent at least one treatment area. At least one of the plurality of engines may be releasably couplable to the inner wearable harness. The method may include positioning an outer wearable harness on a torso of a subject. The method may include applying an oscillation force to at least one of the treatment areas using at least some of the plurality of engines. The method may include adjusting the applied oscillation force to the treatment area by activating the outer wearable harness. The method may include mobilizing at least some secretions in an airway within the subject substantially adjacent the at least one treatment area.

In some embodiments, a method may include monitoring use of a medical device. The method may include positioning a wearable harness of a medical device on a subject. The method may include selectively positioning at least some of a plurality of engines on and/or adjacent at least one treatment area. The method may include applying an oscillation force to at least one of the treatment areas using at least some of the engines. The method may include mobilizing at least some secretions in an airway within the subject substantially adjacent the treatment areas. The method may include monitoring use of the medical device by the subject using a controller associated with the medical device to determine if the medical device has been used effectively as prescribed.

Implantable devices and/or sensors can be wirelessly powered by controlling and propagating electromagnetic waves in a patient's tissue. Such implantable devices/sensors can be implanted at target locations in a patient, to stimulate areas such as the heart, brain, spinal cord, or muscle tissue, and/or to sense biological, physiological, chemical attributes of the blood, tissue, and other patient parameters. The propagating electromagnetic waves can be generated with sub-wavelength structures configured to manipulate evanescent fields outside of tissue to generate the propagating waves inside the tissue. Methods of use are also described.