Abstract: A sole structure for an article of footwear includes a baseplate defining a ground-contacting surface of the sole structure and at least two ground-engaging members extending from the ground-contacting surface. The at least two ground-engaging members including a first portion and a second portion, the first portions of the ground-engaging members being connected to one another by a bridge formed separately from the baseplate.

Abstract: A sole structure for an article of footwear includes a baseplate defining a ground-contacting surface of the sole structure and at least two ground-engaging members extending from the ground-contacting surface. The at least two ground-engaging members including a first portion and a second portion, the first portions of the ground-engaging members being connected to one another by a bridge formed separately from the baseplate.

Abstract: A sole structure for an article of footwear includes a first sole plate extending from an anterior end of the sole structure to a posterior end of the sole structure. The sole structure further includes a first cleat set disposed in a forefoot region and having a first plurality of traction elements arranged in a first annular pattern about a first axis disposed in the forefoot region. The sole structure also A second cleat set is disposed in a heel region of the sole structure and includes a second plurality of the traction elements arranged in a second annular pattern about a second axis disposed in the heel region.

Abstract: A sole structure for an article of footwear includes a first annular group of traction elements arranged along a first annular zone and a second annular group of traction elements arranged along a second annular zone concentric with the first annular group. The first and second annular groups of traction elements include a plurality of directional traction elements arranged in a first rotational direction about a common rotation zone. Optionally, the first annular group of traction elements may include an omnidirectional traction element arranged at a location associated with a relatively low degree of alignment between radii of rotation corresponding to different torsional movements of the sole structure during use. The directional traction elements may include unidirectional traction elements or bidirectional traction elements at locations associated with moderate to high degrees of alignment between radii of rotation corresponding to the different torsional movements.

Abstract: A sole structure for an article of footwear includes a first annular group of traction elements arranged along a first annular zone and a second annular group of traction elements arranged along a second annular zone concentric with the first annular group. The first and second annular groups of traction elements include a plurality of directional traction elements arranged in a first rotational direction about a common rotation zone. Optionally, the first annular group of traction elements may include an omnidirectional traction element arranged at a location associated with a relatively low degree of alignment between radii of rotation corresponding to different torsional movements of the sole structure during use. The directional traction elements may include unidirectional traction elements or bidirectional traction elements at locations associated with moderate to high degrees of alignment between radii of rotation corresponding to the different torsional movements.

Abstract: A sole structure for an article of footwear includes a first annular group of traction elements arranged along a first annular zone and a second annular group of traction elements arranged along a second annular zone concentric with the first annular group. The first and second annular groups of traction elements include a plurality of directional traction elements arranged in a first rotational direction about a common rotation zone. Optionally, the first annular group of traction elements may include an omnidirectional traction element arranged at a location associated with a relatively low degree of alignment between radii of rotation corresponding to different torsional movements of the sole structure during use. The directional traction elements may include unidirectional traction elements or bidirectional traction elements at locations associated with moderate to high degrees of alignment between radii of rotation corresponding to the different torsional movements.

Abstract: A sole structure for an article of footwear includes a first annular group of traction elements arranged along a first annular zone and a second annular group of traction elements arranged along a second annular zone concentric with the first annular group. The first and second annular groups of traction elements include a plurality of directional traction elements arranged in a first rotational direction about a common rotation zone. Optionally, the first annular group of traction elements may include an omnidirectional traction element arranged at a location associated with a relatively low degree of alignment between radii of rotation corresponding to different torsional movements of the sole structure during use. The directional traction elements may include unidirectional traction elements or bidirectional traction elements at locations associated with moderate to high degrees of alignment between radii of rotation corresponding to the different torsional movements.

Abstract: A sole structure for an article of footwear, the sole structure including a forefoot region and a heel region. The sole structure further includes a chassis plate, an outsole plate extending from the forefoot region to the heel region, the outsole plate including a recess disposed in a top surface, wherein the outsole plate is disposed below the chassis plate, and a cushioning element disposed within the recess.

Abstract: A sole structure for an article of footwear, the sole structure including a forefoot region and a heel region. The sole structure further includes a chassis plate, an outsole plate extending from the forefoot region to the heel region, the outsole plate including a recess disposed in a top surface, wherein the outsole plate is disposed below the chassis plate, and a cushioning element disposed within the recess.

Abstract: A sole structure for an article of footwear includes a baseplate defining a ground-contacting surface of the sole structure and at least two ground-engaging members extending from the ground-contacting surface. The at least two ground-engaging members including a first portion and a second portion, the first portions of the ground-engaging members being connected to one another by a bridge formed separately from the baseplate.

Abstract: A sole structure for an article of footwear includes a baseplate defining a ground-contacting surface of the sole structure and at least two ground-engaging members extending from the ground-contacting surface. The at least two ground-engaging members including a first portion and a second portion, the first portions of the ground-engaging members being connected to one another by a bridge formed separately from the baseplate.

Abstract: A sole structure for an article of footwear includes a first annular group of traction elements arranged along a first annular zone and a second annular group of traction elements arranged along a second annular zone concentric with the first annular group. The first and second annular groups of traction elements include a plurality of directional traction elements arranged in a first rotational direction about a common rotation zone. Optionally, the first annular group of traction elements may include an omnidirectional traction element arranged at a location associated with a relatively low degree of alignment between radii of rotation corresponding to different torsional movements of the sole structure during use. The directional traction elements may include unidirectional traction elements or bidirectional traction elements at locations associated with moderate to high degrees of alignment between radii of rotation corresponding to the different torsional movements.

Abstract: A voice prosthesis includes a body carrying a passage, and a magnetic passage sealing mechanism having a ball that can selectively seal/block or open the passage. The voice prosthesis can include an outer skin that covers the body. The voice prosthesis can include a polymer carrying a nanomaterial. The voice prosthesis can be fabricated as a patient specific device in accordance with images of a fistula of a target patient for whom the voice prosthesis is intended.

Abstract: The present invention provides methods for packaging small size memory cards wherein the methods comprise molding over a populated printed circuit board, thereby an encapsulated memory card is obtained with desirable external dimensions and features. In one aspect of the invention, methods are provided for preventing mold bleed underneath of the contact pads of memory cards. In one embodiment, the mold bleeding is prevented by using slidable holding pins that exert pressure directly upon the contact pins during the molding process. In another embodiments, the mold bleeding is prevented by covering the contact pads with temporary substrate coverage during the molding process. In yet another embodiment, the mold bleeding is prevented by using pressing edges that exert pressure directly upon the area of contact pads during the molding process. In still another embodiment, the mold bleeding is prevented by using vacuum pressure to secure the populated PCB onto the bottom of a molding apparatus.

Abstract: Method for packaging small size memory cards A method is disclosed for packaging a small size memory card, including xD Picture card, Memory Stick™, Secure Digital™ (SD) card, SmartMedia™ (SM) card, Multimedia card (MMC), CompactFlash™ (CF) card and PC card, by moulding over to encapsulate a populated printed circuit board (PCB) (10) to form the standard external dimensions and features of the memory card.