The present invention is a shoe or sandal type of footwear comprising wireless, remote controlled, mechanical portions which pivot and/or slide to affix to a foot, or to detach from a foot, on command, in a handsfree manor. Wireless charging elements are also utilized to charge batteries of footwear in a handsfree manor.

The present invention is a shoe or sandal type of footwear comprising wireless, remote controlled, mechanical portions which pivot and/or slide to affix to a foot, or to detach from a foot, on command, in a handsfree manor. Wireless charging elements are also utilized to charge batteries of footwear in a handsfree manor.

A system and method and apparatus comprising an anti-microbial, self-adhesive film, are provided which prevents dirt, sweat, fungus, and bacteria, from absorbing into the insole and the sides and bottoms of the insole. The antimicrobial, self-adhesive film of the invention is provided in a size suitable for application to an insole so as to prevent dirt, sweat, bacteria, foot wort fungus etc. from absorbing into an insole and sides, to and bottom areas of said insole.

A system and method and apparatus comprising an anti-microbial, self-adhesive film, are provided which prevents dirt, sweat, fungus, and bacteria, from absorbing into the insole and the sides and bottoms of the insole. The antimicrobial, self-adhesive film of the invention is provided in a size suitable for application to an insole so as to prevent dirt, sweat, bacteria, foot wort fungus etc. from absorbing into an insole and sides, to and bottom areas of said insole.

A method of manufacturing an insert system for footwear includes assembling electronic components. The electronic components include a sensor array having physiological sensors. Each physiological sensor includes a first high resistance layer configured to be in contact with a second high resistance layer when no force is applied to the sensor. The method further includes positioning the sensor array between a first layer and a base layer. An insert system for footwear includes a first layer, a base layer, a sensor array between the first and base layers, and a circuit board. The sensor array includes physiological sensors. Each physiological sensor includes a first high resistance layer in contact with a second high resistance layer when no force is applied to the sensor. The circuit board can transmit signals external to the system to trigger an alert being issued to a user, based on an output of the sensor array.

A method of manufacturing an insert system for footwear includes assembling electronic components. The electronic components include a sensor array having physiological sensors. Each physiological sensor includes a first high resistance layer configured to be in contact with a second high resistance layer when no force is applied to the sensor. The method further includes positioning the sensor array between a first layer and a base layer. An insert system for footwear includes a first layer, a base layer, a sensor array between the first and base layers, and a circuit board. The sensor array includes physiological sensors. Each physiological sensor includes a first high resistance layer in contact with a second high resistance layer when no force is applied to the sensor. The circuit board can transmit signals external to the system to trigger an alert being issued to a user, based on an output of the sensor array.

The general field of the disclosure herein relates to the design of one or more health related monitoring or maintenance devices. These devices may include but are not limited to devices that monitor and/or maintain the health of users or devices that monitor and/or maintain the health of assets. The devices include oral cleaning devices for maintaining and monitoring the oral health of users, clothing for monitoring the health and fitness of users and charging pads which may monitor the health or assets being charged. Sensors may be integrated in these devices including but not limited to IMUs, thermocouples or oral cleaning devices, IMUs in clothing like shoes or wrist bands, or timers or charging sensors in magnetic surfaces which may cause one or more objects and/or other magnetic surfaces to float when a desired function is achieved.

A method of differentially tuning a lower limb muscle in a human in need thereof is provided. The method includes placement of at least two calibrated, differential disturbances or protuberances under the human's feet thereby tuning a lower limb muscle.

A method of differentially tuning a lower limb muscle in a human in need thereof is provided. The method includes placement of at least two calibrated, differential disturbances or protuberances under the human's feet thereby tuning a lower limb muscle.

The present invention is directed to an antimicrobial shoe insole comprising an antimicrobial composition. The antimicrobial shoe insole has the density from 0.12 to 0.30 g/cm.sup.3, preferably 0.18 to 0.22 g/cm.sup.3, the hardness of the shore C is 28 to 45, the ball rebound rate is ≥65%, and anti-fatigue test (20% compression rate) is over 10,000 times. The antimicrobial shoe insole is formulated to have a sterilization rate over 99.99%, durable, and the mildew resistance index can be zero with no detectable mildew growth.