In one example embodiment, an apparatus may include a panel with integrated fluid channels, wherein the panel and the fluid channel consist only of surfaces that can be manufactured with a straight-pull mold. A port may also be integrated into the panel to facilitate coupling the fluid channel to pneumatic components in an assembly. A seal may be secured to the panel over the fluid channel to form an integrated fluid conductor. The seal is preferably an adhesive label that can also be used for product labeling. Such an apparatus may be used in a control unit of a therapy system, employing several integrated fluid conductors. A method of manufacturing may include molding a panel, wherein the mold forms a channel integral to the panel. The panel and the channel preferably consist of surfaces that can be molded with a straight-pull mold.

A method for capturing dislodged vegetative growth during a surgical procedure is provided. The method includes maneuvering, into a circulatory system, a first cannula having a distal end and an opposing proximal end, such that the first cannula is positioned to capture the vegetative growth en bloc. A second cannula is positioned in fluid communication with the first cannula, such that a distal end of the second cannula is situated in spaced relation to the distal end of the first cannula. A suction force is provided through the distal end of the first cannula so as to capture the vegetative growth. Fluid removed by the suction force is reinfused through the distal end of the second cannula. Subsequent to becoming dislodged, the vegetative growth is captured by the first cannula. A method for capturing a vegetative growth during removal of a pacemaker lead is also provided.

Aspiration systems and methods for controlling blood loss during thrombus removal are disclosed herein. The systems include an aspiration catheter, an aspiration tubing, a receptacle for collecting aspirated blood, a vacuum line coupled to the receptacle, and a sensor configured to measure a flow parameter associated with a liquid within an aspiration lumen. The systems further include a regulator configured to adjust a vacuum pressure within the vacuum line, and a vacuum controller operably coupled to the sensor and the regulator. The vacuum controller is configured to receive the flow parameter from the sensor, compare the flow parameter to a target range for the flow parameter, and send an automatic control signal to the regulator based on a comparison of the flow parameter to the target range. The automatic control signal causes the regulator to adjust the vacuum pressure within the vacuum line.

A waste collection system for collecting medical waste. A mobile rover includes at least one waste container, and a rover controller. A chassis is removably couplable with the mobile rover and includes a vacuum regulator, and a chassis controller. The chassis controller is configured to control operation of the vacuum regulator based on a pressure signal from a pressure sensor disposed on the mobile rover. The chassis may include a control panel configured to receive an input of and display a vacuum level, and the chassis controller may control operation of the vacuum regulator based on the input. The mobile rover may include plural waste containers, and the chassis may include plural vacuum regulators. The chassis controller may control operation of the vacuum regulators on the chassis to independently regulate the vacuum level supplied to each of the waste containers on the mobile rover.

A method of operating a waste collection unit including a light assembly separate from a display panel. A vacuum level of the vacuum drawn on a waste canister is measured with a vacuum sensor. The light assembly positioned adjacent a manifold receiver is operated to selectively emit light of a color based on the measured vacuum level. A commanded vacuum level may be received on the display panel, and a colored image indicative of a commanded vacuum level may be displayed on the display panel. The waste collection unit may include plural manifold receivers each configured to receive a manifold. The light assembly that is adjacent the manifold receiver corresponding to the waste canister into which the vacuum is being drawn may be operated to selectively emit light to emit light at different colors or different patterns based on the operating state of the waste collection unit.

A cap assembly including a self-sealing membrane that overlaps an opening to an interior of a container. The cap assembly further includes a cap having a cover portion that includes an annular wall that defines a central opening, and at least one evacuating opening located radially outward of the central opening. The cover portion defines a gap above the self-sealing membrane. The gap is configured to allow the self-sealing membrane to be at least partially displaced from the opening to allow fluid communication between the interior of the container and an outside atmosphere when a suction is applied to the cap.

The present invention provide a puncture instrument capable of administering (supplying) a drug solution. The puncture instrument includes a puncture tip section (2); a first tubular body (3) connected to the puncture tip section (2) at the distal end; and an outer tubular body (5) at least partially covering the first tubular body (3). The first tubular body (3) is formed to be rotatable around an axis along the longitudinal direction. The first tubular body (3) has an outer diameter smaller than an inner diameter of the outer tubular body (5). A drug solution supply path (5a) is provided on the outside of the first tubular body (3).

Disclosed herein are methods, systems, and devices for collecting a fluid for use in connection with a fluid pumping device such as a breast pump. A fluid collection receptacle includes a rigid connector attached to the fluid collection receptacle. The rigid connector is connectable to a breast pump manifold. The fluid collection receptacle further includes a liquid tight seal in the fluid collection receptacle. The fluid collection receptacle may be constructed of a flexible plastic.

A surgical drain tray assembly includes a fluid impermeable first layer and a porous second layer positioned on the fluid impermeable first layer. The fluid impermeable first layer includes a drain outlet, a basin, and a sloping surface angled toward the basin, the drain outlet being positioned within the basin. The porous second layer may be formed of a foam material and includes a top work surface. Fluids spilled onto the work surface pass through the porous second layer to the fluid impermeable first layer. The sloping surface of the fluid impermeable first layer conveys the fluids toward the basin for draining through the drainage outlet.

A breast pump system comprises at least one wearable milk collection hub connected via an air line to a combined external air pump and control unit. Each milk collection hub comprises: (a) a breast shield made up of a breast flange and a nipple tunnel; (b) a flexible diaphragm that is configured to prevent milk from reaching the external air pump; (c) an outer shell that is configured to removably attach to the breast shield, such that, when attached, the breast shield and outer shell form a vessel for collecting milk; and (d) a diaphragm cap that is configured to be secured over the diaphragm, forms part of the front face of the outer shell, and includes a port connected to the air line.