Abstract: An assembly is configured to position a peristaltic tube with respect to a linear peristaltic pump drive of an infusion pump. The assembly can include a peristaltic tube, first and second tube couplers, a frame, first and second securement plates, a free-flow prevention arm, and a biasing mechanism. The frame can include a snap-fit tab configured to releasably secure the assembly to an assembly receptacle of the infusion pump. The free-flow prevention arm can be selectively movable between a free-flow preventing position and a free-flow allowing position. A latching mechanism can be ergonomically manipulable to latch the free-flow prevention arm in a free-flow allowing position, and to unlatch the free-flow prevention arm such that the biasing mechanism is able to bias the free-flow prevention arm to the free-flow preventing position.

Abstract: An assembly is configured to position a peristaltic tube with respect to a linear peristaltic pump drive of an infusion pump. The assembly can include a peristaltic tube, first and second tube couplers, a frame, first and second securement plates, a free-flow prevention arm, and a biasing mechanism. The frame can include a snap-fit tab configured to releasably secure the assembly to an assembly receptacle of the infusion pump. The free-flow prevention arm can be selectively movable between a free-flow preventing position and a free-flow allowing position. A latching mechanism can be ergonomically manipulable to latch the free-flow prevention arm in a free-flow allowing position, and to unlatch the free-flow prevention arm such that the biasing mechanism is able to bias the free-flow prevention arm to the free-flow preventing position.

Abstract: An assembly is configured to position a peristaltic tube with respect to a linear peristaltic pump drive of an infusion pump. The assembly can include a peristaltic tube, first and second tube couplers, a frame, first and second securement plates, a free-flow prevention arm, and a biasing mechanism. The frame can include a snap-fit tab configured to releasably secure the assembly to an assembly receptacle of the infusion pump. The free-flow prevention arm can be selectively movable between a free-flow preventing position and a free-flow allowing position. A latching mechanism can be ergonomically manipulable to latch the free-flow prevention arm in a free-flow allowing position, and to unlatch the free-flow prevention arm such that the biasing mechanism is able to bias the free-flow prevention arm to the free-flow preventing position.

Abstract: An assembly is configured to position a peristaltic tube with respect to a linear peristaltic pump drive of an infusion pump. The assembly can include a peristaltic tube, first and second tube couplers, a frame, first and second securement plates, a free-flow prevention arm, and a biasing mechanism. The frame can include a snap-fit tab configured to releasably secure the assembly to an assembly receptacle of the infusion pump. The free-flow prevention arm can be selectively movable between a free-flow preventing position and a free-flow allowing position. A latching mechanism can be ergonomically manipulable to latch the free-flow prevention arm in a free-flow allowing position, and to unlatch the free-flow prevention arm such that the biasing mechanism is able to bias the free-flow prevention arm to the free-flow preventing position.

Abstract: A cardiac lead comprising a lead body extending from a proximal end portion to a distal end portion; a cardiac electrode disposed along the lead body; and a coating associated with at least a portion of the electrode, wherein the coating comprises a conductive polymer.

Abstract: A cardiac lead comprising a lead body extending from a proximal end portion to a distal end portion; a cardiac electrode disposed along the lead body; and a coating associated with at least a portion of the electrode, the coating comprises a conductive polymer.

Abstract: A tachy lead includes a lead body extending from a lead proximal end portion to a lead distal end portion and having an intermediate portion therebetween, one or more tissue sensing/stimulation electrodes disposed along the lead body, one or more terminal connections disposed along the lead proximal end portion. The lead further includes one or more conductors contained within the lead body extending between the tissue sensing/stimulation electrodes and the terminal connections, a porous drug-eluting coating disposed onto at least a portion of the lead body and/or sensing/stimulation electrodes, wherein the drug-eluting coating comprises porous polytetrafluoroethylene (PTFE), a biodegradable polymer and one or more drugs.

Abstract: A cardiac lead comprising a lead body extending from a proximal end portion to a distal end portion; a cardiac electrode disposed along the lead body; and a coating associated with at least a portion of the electrode, wherein the coating comprises a conductive polymer.

Abstract: A medical lead including a lead body extending from a first end portion to a second end portion and a coating disposed along a portion of the lead, wherein the coating includes at least one matrix polymer layer, at least one anti-inflammatory agent and at least one anti-proliferative agent.

Abstract: A substrate processing apparatus has a process chamber with a substrate support, a gas supply to introduce a gas into the chamber, and a gas energizer to energize the gas in the processing of a substrate, thereby generating an effluent gas. A catalytic reactor has an effluent gas inlet to receive the effluent gas and an effluent gas outlet to exhaust treated effluent gas. A heater is adapted to heat the effluent gas in the catalytic reactor. The heated catalytic treatment of the effluent gas abates the hazardous gases in the effluent. An additive gas source and a prescrubber may also be used to further treat the effluent.

Abstract: A substrate processing apparatus has a process chamber with a substrate support, a gas supply to introduce a gas into the chamber, and a gas energizer to energize the gas in the processing of a substrate, thereby generating an effluent gas. A catalytic reactor has an effluent gas inlet to receive the effluent gas and an effluent gas outlet to exhaust treated effluent gas. A heater is adapted to heat the effluent gas in the catalytic reactor. The heated catalytic treatment of the effluent gas abates the hazardous gases in the effluent. An additive gas source and a prescrubber may also be used to further treat the effluent.

Abstract: An apparatus delivers plural molten plastic pellets into cavities for compression molding of the pellets into bottle closures or bottle closure liners. The apparatus is provided for delivering molten plastic pellets from a supply of molten plastic to a plurality of molding blocks, each molding block having a row of cavities. The molding blocks are carried on a rotating carousel. The apparatus includes a rotating multi-cutter with a plurality of cutter blades, and a manifold block which receives the extruded molten-plastic and delivers the molten plastic to a plurality of nozzles, each nozzle aligned with one or more of the cutter blades. The cutter blades remove a row of plastic pellets from the molten plastic at the nozzles and deliver the plastic pellets into one row of cavities of a molding block.