Abstract: Multi-layer devices suitable for thermal cycling processes. The devices are particularly suitable for performing polymerase chain reactions (PCR). One embodiment includes a first conducting layer, a second conducting layer adjacent to the first layer, and a third conducting layer adjacent to the second layer opposite the first layer. Insulating layers are positioned between said three conducting layers. Continuous channels are formed within the layers. The channels can be formed in either the conducting layer or the insulating layers, or both. Other embodiments include two conducting layers. At least one integral or separate temperature source may be provided to maintain the conducting layers at various desired temperatures.

Abstract: Devices and systems for extracting, purifying and amplifying nucleic acids, and methods for use of such devices and systems. The devices have top sections which include a plurality of syringe vessels with applicable reagent materials, as well as a channel for a specimen collection dropper. Plungers force the materials sequentially into reaction chambers in the middle sections. Once the samples are extracted and purified, they are drawn by a vacuum into PCR devices where they are subjected to denaturing, annealing and extension steps and amplified. Interrogation of flow cells provide real-time quantitative detection.

Abstract: Implantable electrical leads including an axial reinforcement member are disclosed. In some embodiments, an implantable electrical lead can have a body, one or more electrodes, a cable conductor, a conductor coil, and a reinforcement member. A cable conductor can be disposed within the body and is configured to convey electrical signals between the proximal region and the distal region of the lead. The reinforcement member may be coupled to or integrally formed within the lead body and is configured to limit elongation of the lead body in response to a tensile force.

Abstract: A multi-layer device suitable for thermal cycling is set forth. The device is particularly suitable for performing a polymerase chain reaction (PCR). One embodiment includes a first layer (18), a second layer (20) adjacent to the first layer, and a third layer (22) adjacent to the second layer opposite the first layer. A continuous channel (54) is formed within the first layer (18), the second layer (20), and the third layer (22). The continuous channel (54) has a plurality of cycle segments, each of the cycle segments comprises a first portion (58) disposed within the first layer (18), a second portion (62) disposed within the third layer (22), and a third portion (66) disposed within the second layer (20). An integral or separate temperature source or sources (14), (16) may be provided to maintain the first layer (18) at a first temperature and the third layer (22) at a second temperature.

Abstract: A multi-layer device suitable for thermal cycling is set forth. The device is particularly suitable for performing a polymerase chain reaction (PCR). One embodiment includes a first layer (18), a second layer (20) adjacent to the first layer, and a third layer (22) adjacent to the second layer opposite the first layer. A continuous channel (54) is formed within the first layer (18), the second layer (20), and the third layer (22). The continuous channel (54) has a plurality of cycle segments, each of the cycle segments comprises a first portion (58) disposed within the first layer (18), a second portion (62) disposed within the third layer (22), and a third portion (66) disposed within the second layer (20). An integral or separate temperature source or sources (14), (16) may be provided to maintain the first layer (18) at a first temperature and the third layer (22) at a second temperature.

Abstract: Multi-layer devices suitable for thermal cycling processes. The devices are particularly suitable for performing polymerase chain reactions (PCR). One embodiment includes a first conducting layer, a second conducting layer adjacent to the first layer, and a third conducting layer adjacent to the second layer opposite the first layer. Insulating layers are positioned between said three conducting layers. Continuous channels are formed within the layers. The channels can be formed in either the conducting layer or the insulating layers, or both. Other embodiments include two conducting layers. At least one integral or separate temperature source may be provided to maintain the conducting layers at various desired temperatures.

Abstract: A multi-layer device suitable for thermal cycling is set forth. The device is particularly suitable for performing a polymerase chain reaction (PCR). One embodiment includes a first layer (18), a second layer (20) adjacent to the first layer, and a third layer (22) adjacent to the second layer opposite the first layer. A continuous channel (54) is formed within the first layer (18), the second layer (20), and the third layer (22). The continuous channel (54) has a plurality of cycle segments, each of the cycle segments comprises a first portion (58) disposed within the first layer (18), a second portion (62) disposed within the third layer (22), and a third portion (66) disposed within the second layer (20). An integral or separate temperature source or sources (14), (16) may be provided to maintain the first layer (18) at a first temperature and the third layer (22) at a second temperature.