A ventilation apparatus including a pump, a switching unit, and a fluid diffuser is provided. The pump attached to the footwear pumps fluid into and exhausts fluid from a cavity of the footwear. The switching unit in communication with the pump selectively changes modes of operation of the pump. The fluid diffuser connected to the pump within the cavity of the footwear includes a feed pipe for transferring the fluid pumped from the pump to the cavity of the footwear during a pump mode of operation and to transfer the fluid in the cavity of the footwear to an ambient environment external to the footwear during an exhaust mode of operation, for ventilating the footwear. In one or more embodiments, the fluid diffuser includes a diffusing member with one or more openings and/or a fluid distribution channel member for transferring the fluid to and from the cavity of the footwear.

A footwear having a housing seat for a foot and an active control system for actively controlling temperature and humidity inside the housing seat is provided. The active control system has an electronic control unit, a temperature sensor and a humidity sensor operatively connected to the electronic control unit for supplying the electronic control unit with a first electrical signal bearing information correlated to the temperature inside the housing seat and a second electrical signal bearing information correlated to the humidity inside the housing seat, respectively. The active control system has at least one temperature control element operatively connected to the electronic control unit and controllable for varying the temperature inside the housing seat, and at least one humidity control element that is operatively connected to the electronic control unit, controllable for varying the humidity inside the housing seat, and configured to vary the humidity by electrolysis.

A rehabilitation footwear device for assisting in controlling weight application to an injured lower appendage includes a shoe that is configured to position around and reversibly couple to a foot of a user. A control module that comprises a power module and a microprocessor is coupled to the shoe. The microprocessor is operationally coupled to the power module. A plurality of sensors is coupled to and positioned in a sole of the shoe. The sensors are operationally coupled to the microprocessor. The sensors are configured to measure pressure applied to the sole from the foot that is positioned in the shoe and to relay a pressure measurement to the microprocessor. A speaker is coupled to the shoe. The speaker is operationally coupled to the microprocessor. The microprocessor is positioned to compel the speaker to emit an audio alert should the pressure measurement exceed a threshold limit.

A method and wearable system and for enhancing human balance and gait and preventing foot injury through neurological stimulation of the foot and the ankle. Subthreshold stimulation for neurosensory enhancement is provided via electrodes or vibrational actuators, or combination thereof, disposed in or on a wearable a platform, such as an insole, sock shoe, removable shoe insert, or applied without the support of a platform, to the skin surface of an individual. Suprathreshold stimulation for therapeutic purposes, such as improving blood flow, is also provided by the vibrational actuators. The actuators and electrodes are driven by bias signals generated by a bias signal generator that is coupled to a controller. The signal generator under the control of the controller is adapted to generate a non-deterministic random signal, a repetitive pattern or series of patterns. The controller optionally includes a communication port for interfacing with an external computer for purposes of optimizing and programming the controller. The wearable system is powered by a power source.

A method and wearable system and for enhancing human balance and gait and preventing foot injury through neurological stimulation of the foot and the ankle. Subthreshold stimulation for neurosensory enhancement is provided via electrodes or vibrational actuators, or combination thereof, disposed in or on a wearable a platform, such as an insole, sock shoe, removable shoe insert, or applied without the support of a platform, to the skin surface of an individual. Suprathreshold stimulation for therapeutic purposes, such as improving blood flow, is also provided by the vibrational actuators. The actuators and electrodes are driven by bias signals generated by a bias signal generator that is coupled to a controller. The signal generator under the control of the controller is adapted to generate a non-deterministic random signal, a repetitive pattern or series of patterns. The controller optionally includes a communication port for interfacing with an external computer for purposes of optimizing and programming the controller. The wearable system is powered by a power source.

Systems, devices and methods for providing active and/or passive compression therapy to a body part can include a compression device worn over a compression stocking. The compression device can have a pulley based drive train that is driven by a motor to tighten and loosen compression elements, such as compression straps, in a precise, rapid, and balanced manner. Sensors can be used in the compression device and/or compression stockings to provide feedback to modulate the compression treatment parameters.

A system assesses activity and displays a unitless activity value. A detector senses activity of a user. A processor reads sensed activity data from the detector. A display displays the unitless activity value. An enclosure houses the detector and the processor. The processor periodically reads the sensed activity data from the detector and processes the data to generate an activity number, the number being used to generate the unitless activity value based upon a maximum number and a display range.

A system assesses activity and displays a unitless activity value. A detector senses activity of a user. A processor reads sensed activity data from the detector. A display displays the unitless activity value. An enclosure houses the detector and the processor. The processor periodically reads the sensed activity data from the detector and processes the data to generate an activity number, the number being used to generate the unitless activity value based upon a maximum number and a display range.

An article of footwear may include a sole structure fixedly attached to an upper defining an internal cavity configured to receive a foot of a wearer. The sole structure may include an exposed outer member configured to contact the ground, the exposed outer member including a first aperture, and a sensory feedback member disposed at least partially within the first aperture in the outer member, the sensory feedback member including a first end and a second end. The first end of the sensory feedback member may include a projection extending through the first aperture and configured to contact the ground. In addition, the second end of the sensory feedback member may include a plurality of flexible bristles extending through a portion of the sole structure and exposed to the internal cavity.

An article of footwear may include a sole structure fixedly attached to an upper defining an internal cavity configured to receive a foot of a wearer. The sole structure may include an exposed outer member configured to contact the ground, the exposed outer member including a first aperture, and a sensory feedback member disposed at least partially within the first aperture in the outer member, the sensory feedback member including a first end and a second end. The first end of the sensory feedback member may include a projection extending through the first aperture and configured to contact the ground. In addition, the second end of the sensory feedback member may include a plurality of flexible bristles extending through a portion of the sole structure and exposed to the internal cavity.