The present invention is footwear having a convex shaped outsole with opposing wedge shaped configurations in the bottom of the front sole section and the back sole section which provide rotation of the front sole section and the back sole section in opposite directions when weight is applied. The present invention is also footwear convex shaped in the longitudinal direction with a split sole having opposing wedge shaped configurations in the bottom of the front sole section and the back sole section that provide rotation of the front sole section and the back sole section in opposite directions when weight is applied. The invention further includes footwear having at least one pair of wedges on the outsole which provide footwear having improved arch support. The invention is also footwear with a flexible, elastic, member between the front sole section and the back sole section of the sole.

Disclosed herein are various methods and devices for modifying the comfort and performance characteristics of a shoe. In various embodiments, the devices are soles, insole or outsoles, of a shoe comprising one or more shocks. The shocks may be defined by shock cavities positioned within one or more surfaces of a sole. In some embodiments the shock cavity may be configured to receive one or more shock cavity inserts.

Described herein is a shock absorbing apparatus configured for use in a sole or insole for footwear. The device is generally provided in a raised structure equipped with air flow holes, a gripped bottom, and a smooth top.

The presently disclosed subject matter is generally directed to a shoe insert sized and shaped to accommodate a user's foot and fit inside a standard shoe (e.g., a golf shoe). The insert is configured with a gradient with a first height on a lateral edge and a second (lesser) height on a medial edge. In this way, the insert does not lay flat on the inside of the user's shoe but provides a gradient that stabilizes the user's weight to the center of the foot. Advantageously, the inserts allow the golfer to automatically assume a proper stance and to properly shift the body weight during a swing. As a result, the insert keeps a golfer from swaying during a golf swing, thereby reducing the incidence of shanking the ball.

An insole comprises an insole body of a suitable thickness and softness, which comprises a metatarsal area, an arch area, and a heel area, wherein the metatarsal area has a treading portion, which is concaved and corresponded to a ball of the foot for receiving the ball of foot, and an outer supporting portion, which is extended from the treading portion toward the transverse arch to form an inclined plane and having a thickness which is more than the thickness of the treading portion. Accordingly, the soles of user's feet are adjusted inward by the insole of the present invention which is designed for adjusting the foot posture, lowering the pressure on the normal or valgus feet to keep the guide path of the stress on feet in a relaxed posture. Furthermore, the insole of the present invention is freely put in or out from the shoes, being convenient use.

This invention generally relates to a shoe in which an orthopedic adjustment has been integrated into the construction of the shoe itself. The invention entails adjusting one or more of the soles or other construction features of the shoe itself in order to accommodate a medical condition or treatment regimen. In particular, in instances of abnormalities in the knee joint, there is a need to redistribute the weight of the body from an afflicted symptomatic medial compartment of the knee to an un-afflicted and asymptomatic, or lesser effected and less symptomatic compartment so as to relieve the pain and stress at the most afflicted and most symptomatic compartment. Benefits are also achieved by reducing a common ankle injury, and by improving lateral cutting, cornering, and push off maneuvers. The present invention achieves all this by laterally wedging the sole of a shoe, where the angle is chosen to counter and redistribute the weight of the body accordingly thereby changing the axial load on the knee and ankle joints.

An insole is provided that is constructed out of a mesh material that is stretched and suspended over a cavity formed in a shoe. The mesh surrounds a foam base and a rigid frame positioned under the foam base. The foam base is shaped so that a cavity is formed between the top surface of the foam base and the mesh positioned over the foam base to provide a “trampoline” effect for a wearer's foot.

A shoe 1 or an inlay 3 for a shoe 1 having a pocket-like slot 7 integrated in the shoe 1 or in the inlay 3 for at least one wedge-like insert 8, 9, which provides a good structure and corresponding support for the human foot 50 or longitudinal arch 51. The insert 8, 9 is fixed in the pocket-like slot 7, so that it always retains its optimal support position for the foot 50 even with changing loads.

Provided is a shoe article with an arch spring. A shoe article with an arch spring comprises an arch part 13 contacting a side part of a foot middle part and having a convex curved shape upwardly; and an arch spring 20, 30 formed at the arch part 13, wherein at least one part of the arch spring 20, 30 has an elastic property for moving in an up and down direction and being recovered in an original shape.

Methods of using a foot device are disclosed herein. The foot device includes a generally U-shaped portion having an arcuate portion and first and second legs extending from the arcuate portion. Each leg has an end and a relief area disposed adjacent the respective end. A method of using the foot device comprises engaging the arcuate portion with a heel of a foot to form a first point of contact; positioning the relief area of the first leg proximate a fifth metatarsal head of the foot such that the fifth metatarsal head drops to form a second point of contact; and positioning the relief area of the second leg proximate a first metatarsal head of the foot such that the first metatarsal head drops to form a third point of contact, wherein the first, second, and third points of contact form a triangle-shaped contact surface.