Various irrigation fluid containment systems and components are disclosed. In some embodiments, the irrigation fluid containment system comprises a medical kit and/or an irrigation kit. In some embodiments, the irrigation fluid containment system comprises a medical basin and/or an irrigation basin. In some embodiments, the irrigation fluid containment system comprises an irrigation shield. In some embodiments, the irrigation fluid containment system comprises a suction hose.

A liquid waste bag includes a bag body which is provided with a receptor cavity and a joint inserted into the receptor cavity and stuck onto the bag body. A tear part used for tearing the hag body to discharge liquid is connected to an outer wall of the receptor cavity of the bag body. The liquid waste bag is reasonable in design and simple in structure, is used to collect liquid waste and facilitates transferring and unified treatment of liquid waste. The tear part is reasonably connected to the outer wall of the receptor cavity of the bag body, the receptor cavity of the bag body can be rapidly and conveniently torn through the tear part, and then, the liquid waste is rapidly and conveniently discharged.

A bodily fluid drainage assembly can include a fluid bag and one or more covers. The assembly can include one or more volume indicators from which an approximate volume of a bodily fluid that is retained within the bag can be ascertained. In some arrangements, a cover includes a volume indicator that defines an opening through which a transparent or semitransparent portion of the bag can be viewed.

A product bag suspension assembly includes a rod having a first end, a second end, and a body extending between the first end and the second end. A platform is operatively coupled to the second end of the rod and defines an aperture arrangement configured to receive a mounting device of a product bag. The rod is configured to suspend the product bag in an upright position when the product bag is coupled to the platform.

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.

An arrangement adapted for enhanced continuous flow of urine in a catheterized patient, the arrangement comprising a catheter tube having an inner diameter of less than six millimeters, said tube having an inner surface which is hydrophobic at least along a first segment thereof and being adapted to provide a continuously negative fluid pressure therein.

An external catheter system is provided. The system includes an elongated sheath having an open upper end and an open lower end. An inflatable ring is affixed about the open upper end. In some embodiments, the inflatable ring is removably securable to the open upper end of the elongated sheath. An inflation tube is in fluid communication with an interior volume of the inflatable ring. A syringe valve is affixed to a distal end of the inflation tube, wherein the syringe valve operably connects to a syringe. Upon depression of a plunger of the syringe, air is dispensed into the inflatable ring.

A system suitable for collecting and transporting urine away from the body of a person or animal may include an assembly having a fluid impermeable casing having a fluid reservoir at a first end, a fluid outlet at a second end, and a longitudinally extending fluid impermeable layer coupled to the fluid reservoir and the fluid outlet and defining a longitudinally elongated opening between the reservoir and the outlet. The assembly can further include a fluid permeable support disposed within the casing with a portion extending across the elongated opening, and a fluid permeable membrane disposed on the support and covering at least the portion of the support that extends across the elongated opening, so that the membrane is supported on the support and disposed across the elongated opening. The assembly can further include a tube having a first end disposed in the reservoir and a second, fluid discharge end.

A collector for fecal discharge is provided comprising a self-expanding resilient collection component, a housing sheath and a transit component. The collection component has an open proximal and distal end and a lumen connecting them. The component comprises interconnected resilient arms circumscribing its contour, wherein adjacent arms are resiliently biased away from each other for exerting outwardly radial pressure for expanding and anchoring the component to rectal walls upon deployment. The housing sheath comprises a flexible and resilient material overlaying at least one of inner or outer contour of collection component without interfering with or blocking its ends or lumen. The transit component provides a conduit for fecal discharge to migrate from collection component to a receptacle and comprises a flexible, tubular sheath having a first open end connected to a second end by a lumen, wherein the first end engages with the proximal end of the collection component.

A chest drainage system including a collection device configured to receive fluid from the pleural cavity of a patient. A sensor is included to detect a pressure differential in the fluid. A display is configured to display a trend in occurrences of changes in pressure of the fluid over time in predetermined time increments based on a number of detections of pressure differentials that exceed a predetermined pressure differential during each of the predetermined time increments. The trend is correlative to the percentage of time that the patient is deemed to have an air leak in the pleural cavity in the predetermined time increments. The trend is derived from a ratio of the quantity of respiratory cycles of the patient for which the predetermined pressure differential is detected (QRC.sub.leak) in the predetermined time increments to the total quantity of respiratory cycles of the patient in respective predetermined time increments (QRC.sub.total).