In some embodiments, a system may include an inner wearable harness worn, during use, on a torso of a subject. The system may include a plurality of engines which when activated apply an oscillation force. The system may include a positioning system which allows positioning at least one of the plurality of engines on the inner wearable system such that the oscillation force is applied to at least one treatment area of the subject. The oscillation force may mobilize, during use, at least some secretions in an airway within the subject substantially adjacent the treatment area. The system may include an outer harness worn, during use, on a torso of a subject. The outer wearable harness, when activated, adjusts the oscillation force applied by at least some of the activated plurality of engines to the treatment area.

In some embodiments, a kit may include systems allowing for clearing a biological airway. The kit may include an inner wearable system worn, during use, on a torso of a subject. The kit may include a plurality of engines which when activated apply an oscillation force to at least one treatment area of the subject. At least one of the plurality of engines may be releasably couplable to the inner wearable system. The oscillation force may be applied to at least one of the treatment areas of the subject such that the oscillation force mobilizes, during use, at least some secretions in an airway within the subject at least adjacent the treatment area. The kit may include an outer wearable system worn, during use, on a torso of a subject which when activated, adjusts the oscillation force. The kit may include one or more batteries and/or a control unit.

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.

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 system may include an inner wearable harness worn, during use, on a torso of a subject. The system may include a plurality of engines which when activated apply an oscillation force. The system may include a positioning system which allows positioning at least one of the plurality of engines on the inner wearable system such that the oscillation force is applied to at least one treatment area of the subject. The oscillation force may mobilize, during use, at least some secretions in an airway within the subject substantially adjacent the treatment area. The system may include an outer harness worn, during use, on a torso of a subject. The outer wearable harness, when activated, adjusts the oscillation force applied by at least some of the activated plurality of engines to the treatment area.

In some embodiments, a kit may include systems allowing for clearing a biological airway. The kit may include an inner wearable system worn, during use, on a torso of a subject. The kit may include a plurality of engines which when activated apply an oscillation force to at least one treatment area of the subject. At least one of the plurality of engines may be releasably couplable to the inner wearable system. The oscillation force may be applied to at least one of the treatment areas of the subject such that the oscillation force mobilizes, during use, at least some secretions in an airway within the subject at least adjacent the treatment area. The kit may include an outer wearable system worn, during use, on a torso of a subject which when activated, adjusts the oscillation force. The kit may include one or more batteries and/or a control unit.

A compression device particularly suited for DVT prophylaxis includes a disposable wrap and a re-usable controller removably mounted on the wrap to apply a tensioning force to the wrap when it is encircling the limb of a patient. The wrap includes an RF chip with a unique identifier and the controller includes an RF sensor and processor to authenticate the wrap before commencing a compression cycle. A kiosk is provided for storing a plurality of wraps for use by patients and a plurality of controllers to be used with any of the wraps. The processor of each controller can control an electric motor in the controller to tighten and loosen the wrap according to a compression protocol between a pre-tension compression force and maximum compression force. The amount of movement of the wrap changes as the patient's physiology changes while maintaining the pre-tension and maximum compression forces.

A compression device particularly suited for DVT prophylaxis includes a disposable wrap and a re-usable controller removably mounted on the wrap to apply a tensioning force to the wrap when it is encircling the limb of a patient. The wrap includes an RF chip with a unique identifier and the controller includes an RF sensor and processor to authenticate the wrap before commencing a compression cycle. A kiosk is provided for storing a plurality of wraps for use by patients and a plurality of controllers to be used with any of the wraps. The processor of each controller can control an electric motor in the controller to tighten and loosen the wrap according to a compression protocol between a pre-tension compression force and maximum compression force. The amount of movement of the wrap changes as the patient's physiology changes while maintaining the pre-tension and maximum compression forces.