An article of footwear with a dynamic support system that controls arrays of tiles in the upper of the footwear to adjust the level of support provided in different regions of the upper. Sensors in the sole of the footwear, in the upper of the footwear and/or in an article worn by the wearer of the footwear measure the level of stress or other characteristics and provide input to one or more microprocessors that control motors located in the sole or in the upper of the footwear. When the motors are activated, they may compress or loosen arrays of tiles to adjust the stiffness of the upper in one or more regions of the upper.

A damage resistant shoelace may include a lace and a treatment composition applied to at least a portion of the lace. The treatment composition may include a superglue adhesive, an adhesive, and a sealant, such as a liquid rubber sealant coating in aerosol form.

A variety of devices for protecting a user's foot from injury are disclosed. In one embodiment, the device may be a metatarsal protection device, which may include a first layer of material having top and bottom surfaces, with at least one of such surfaces including a series of cones or a pattern of hexagons thereon. The metatarsal protection device may also include a second relatively rigid layer of material overlying the first layer, and the first layer may be shaped to conform to the metatarsal region of the user's foot, such that the device is configured to protect the metatarsal region against injury. Other configurations and variations of a metatarsal protection device are also disclosed, as are other uses for the principles of the invention(s) disclosed herein (e.g., protection devices for other areas of the foot, etc.).

Described are shoes for ball sports including an upper having an outer surface. An actuator is configured to change at least one surface property of a portion of the outer surface of the upper, and a sensor is configured to be sensitive to movements of the shoe. A processing unit is connected to the actuator and the sensor and configured to process sensor data retrieved from the sensor and to cause the actuator to change the at least one surface property of the portion of the outer surface of the upper if a predetermined event is detected in the sensor data.

An article of footwear, such as a shoe, includes an upper and a sole. The upper may be formed with an outer layer and a floating textile layer relative to one or more portions of the outer layer. The floating textile layer has an apparent elongation that is less than an apparent elongation of the outer layer in response to an equal tensile force applied to each of the floating textile layer and the outer layer along a same axis of orientation. The differential in apparent elongation of the outer layer and the floating textile layer may increase wearability and functionability of the upper.

An article of footwear is provided, which may include an upper and a sole structure. The upper may include an exposed outer layer forming at least a portion of an external surface of the upper. The upper may also include a polymer foam material selectively located on an inner side of the exposed outer layer and adjacent portions of the exposed outer layer, thereby forming padded portions of the upper. The padded portions of the upper may be located in areas of the article of footwear that correspond with predetermined bones of a foot of a wearer of the article of footwear.

Described are shoes for ball sports including an upper having an outer surface. An actuator is configured to change at least one surface property of a portion of the outer surface of the upper, and a sensor is configured to be sensitive to movements of the shoe. A processing unit is connected to the actuator and the sensor and configured to process sensor data retrieved from the sensor and to cause the actuator to change the at least one surface property of the portion of the outer surface of the upper if a predetermined event is detected in the sensor data.

The present disclosure provides a knitted component for an article of footwear. The knitted component may include a first side and a second side, where the first side and the second side form an overfoot portion. An underfoot portion may be located between the first side and the second side, where at least a portion of the first side and at least a portion of the second side of the knitted component are located on one of a medial side and a lateral side of the overfoot portion, and where a knitted course extends from the first side, through the underfoot portion, and to the second side.

An article of footwear with a medial contact portion disposed on the medial side of the article is described. The medial contact portion includes a plurality of raised elements that extend outwards from the surface of the upper on the medial side. The raised elements are configured to contact a ball during passing or trapping to absorb and dampen forces associated with the impact of the ball with the article to provide cushioning. The sizing and spacing arrangement of the raised elements on the medial contact portion provide sufficient surface area to allow a portion of the surface of the upper to contact a ball. In one embodiment, the upper is made from a synthetic leather material that has substantially the same coefficient of friction under dry conditions and wet conditions.

A midsole for an article of footwear including a three dimensional mesh including interconnected unit cells and methods of making the same. The interconnected unit cells each include a plurality of struts defining a three dimensional shape. The interconnected unit cells are connected at nodes having a valence number defined by the number of struts connected at that node. The valence number of the nodes may vary to provide customized characteristics to zones or portions of the midsole. The plurality of interconnected unit cells may be organized in a warped cubic lattice structure. The warped cubic lattice structure and the size/shape of interconnected unit cells may vary to provide customized characteristics to zones or portions of the midsole. The three dimensional mesh may be customized based on a biometric data profile for an individual, or group of individuals. The midsole may be manufactured using an additive manufacturing process.