Abstract: A medical electrical device that includes an elongated body extending from a proximal end to a distal end having an inner surface forming an elongated body lumen, a conductor extending through the elongated body lumen, and an electrode positioned along the distal end of the elongated body and electrically coupled to a distal end of the conductor. A connector ring is coupled to a proximal end of the elongated body and electrically coupled to a proximal end of the conductor, and includes an inner surface forming a connector ring lumen extending along the connector ring. A first flange extends from the inner surface to a first flange distal end and forms a conductor channel extending along the inner lumen to position the conductor within the connector ring and to form the electrical coupling of the connector ring and the proximal end of the conductor.

Abstract: An implantable lead has a lead body construction designed to accommodate loading forces exerted on the lead body during patient movement. The lead body may be sufficiently stretchable to resist forces that could otherwise cause lead failure, axial migration of the electrodes, anchor damage, or tissue damage. Increasing stretchability of a lead body can also increase the vulnerability of the lead body to flex fatigue, buckling fatigue, kinking, and crush. Therefore, the lead described herein includes a reinforcement to create a lead body that is resistant to flex fatigue, buckling fatigue, kinking and crush.

Abstract: A connector terminal of a medical electrical lead or adapter includes a strut member supporting at least one electrical contact element and at least one seal zone element, which is positioned adjacent to the contact element.

Abstract: A medical electrical lead includes a conductive component coupling a coil to a wire or cable; the conductive component includes a first side, a second side, a first groove formed in the first side and a second groove formed in the second side. The first groove holds a portion of the cable and the second groove holds a portion of the coil.

Abstract: An iris diaphragm, in particular for an exposure lens in semiconductor lithography, is provided with a diaphragm base (2) and a grooved ring (1) which can be rotated relative to one another, having a multiplicity of leaves (4) which in each case are mounted in the diaphragm base (2) and in the grooved ring (1) and are guided by curved tracks (6), arranged in the grooved ring (1), for the purpose of adjusting the diaphragm aperture. A drive device (11) serves the purpose of twisting the diaphragm base (2) and grooved ring (1) relative to one another. The curved tracks are designed as circumferential tracks (6) in the grooved ring (1). The circumferential track (6) is split up into alternating useful-region curves (6a) and return curves (6b). The diaphragm base (2) or the grooved ring (1) can be rotated in a preselected rotary drive direction by a drive device (11), the leaves (4) being guided in a circulating fashion in the circumferential track (6).

Abstract: An optical imaging device, in particular a lens system, has a system diaphragm (1). An aperture of the system diaphragm (1) is adjustable in its opening diameter (D). The axial position of the aperture of the system diaphragm (1) with respect to the optical axis (4) of the system diaphragm (1) is fixed in dependence on the opening diameter (D) of the system diaphragm (1).

Abstract: An iris diaphragm, in particular for an exposure lens in semiconductor lithography, is provided with a diaphragm base (2) and a grooved ring (1) which can be rotated relative to one another, having a multiplicity of leaves (4) which in each case are mounted in the diaphragm base (2) and in the grooved ring (1) and are guided by curved tracks (6), arranged in the grooved ring (1), for the purpose of adjusting the diaphragm aperture. A drive device (11) serves the purpose of twisting the diaphragm base (2) and grooved ring (1) relative to one another. The curved tracks are designed as circumferential tracks (6) in the grooved ring (1). The circumferential track (6) is split up into alternating useful-region curves (6a) and return curves (6b). The diaphragm base (2) or the grooved ring (1) can be rotated in a preselected rotary drive direction by a drive device (11), the leaves (4) being guided in a circulating fashion in the circumferential track (6).