A gastric drainage device includes a tube with a drainage lumen and a hub to receive an inflation device. The tube includes an intragastric portion having a set of holes to permit gastrointestinal contents to pass from a stomach cavity into the drainage lumen. The gastric drainage device includes a bolster with a cylindrical port to receive the tube and a disc to hold the tube in place on a skin side of a gastrostomy site. The gastric drainage device includes a balloon formed around the intragastric portion of the tube, wherein the balloon and the intragastric portion of the tube may be passed through the gastrostomy site into the stomach cavity while the balloon is deflated. Accordingly, the balloon is inflatable within the stomach cavity using the inflation device to secure the gastric drainage device at the gastrostomy site while the gastrointestinal contents are drained from the stomach cavity.

A medical tube position confirmation system for confirming the position of a medical tube that is used to supply nutrients to the interior of a body by means of tube feeding while an end portion thereof is inserted into (placed in) the stomach includes a light guide that is configured to guide light entering through an incident end portion so that the light exits through an exit end portion, and is configured to be insertable into the medical tube so that the exit end portion is disposed in the interior of the stomach, and a light source for emitting light including a wavelength passing through a living body, the light source being optically connected to the incident end of the light guide so that the light enters the light guide, and a scattering part optically connected to the light guide on the exit end portion of the light guide so as to scatter light emitted by the light guide.

An apparatus for use in tube feeding has a cylindrical body provided with first opening and second openings connected by a flow channel. The body has a reagent, for determining a characteristic of fluid disposed in the body and a transparent window to view the reagent. In use, a first end of an internal feeding tube releasably engages with the first opening. The second, distal end of the feeding tube is disposed inside a patient. A second feeding tube engages with the second opening. The second feeding tube connects the apparatus to a bi-directional pump operable: to pump internal fluid from a reservoir, through the apparatus and into the internal feeding tube; and to pump fluid from the patient into the body of the apparatus. This allows a user to pump fluid from the patient into the body of the apparatus to react with the reagent.

A connector for medical fluid vessels includes a fluid-seal fitting such as a male plug defining a lumen and mating with a cooperating connector, a mechanical fastener such as a screw thread for mating with the cooperating connector, and an outer housing positioned around the plug to form an annular space. A cap can be provided with a fluid-seal fitting such as a male plug for mating with the lumen of the connector. In example embodiments, the male plug is tapered and can comprise one or more projections for sealingly engaging with the lumen of the connector. According to some example embodiments, the cap can be tethered to the connector.

Exemplary embodiments of the disclosure may be drawn to a device having an inlet and a chamber. Immobilized lipase, immobilized protease, and immobilized amylase may be contained within the chamber. The device may also include an outlet, wherein a flow path extends from the inlet, through the chamber, and to the outlet.

A conduit connector for an enteral feeding pump includes a fluid inlet portion that has an inlet axis and a fluid outlet portion that has an outlet axis that is parallel to and laterally offset from the inlet axis. The fluid inlet portion defines an elongated side slot extending parallel to the inlet axis for receiving tubing therethrough. The conduit connector further includes a bridge portion that extends between and connects the fluid inlet portion and the fluid outlet portion.

A multifunction oxygen mask comprises a mask body and a gas delivery adapter. A nasal chamber is formed in the upper portion of the mask body. An access aperture is formed through and adjacent to a lower portion of the mask body. The access aperture permits access to the mouth of a patient. The gas delivery adapter includes a first end coupled to a gas delivery adapter aperture of the mask body. An oxygen supply port radially extends outward from the gas delivery adapter. The oxygen supply port includes an external inlet portion, an outlet portion positioned within the gas delivery adapter, and a diverter member adjacent to the outlet portion. The diverter member is configured to direct a flow towards the first end of the gas delivery adapter. A meter-dose inhaler port radially extends outward from the gas delivery adapter. The gas delivery adapter includes a nebulizer port.

A container for feeding a patient includes a deformable receptacle having a cavity for holding a flowable food product and a rigid cover attachable to the upper end of the deformable receptacle. The rigid cover may have a male feeding tube connector that is uniquely connectable to a female feeding tube connector of a feeding tube or may have a female feeding tube connector that is uniquely connectable to a male feeding tube connector of a syringe. With the male and female feeding tube connectors connected, the deformable receptacle and the feeding tube or syringe are in fluid tight fluid communication to allow the flowable food product to be forced out of the opening of the deformable receptacle and into the feeding tube or syringe when the deformable receptacle is squeezed.

Air-in-line sensor systems and methods of using same are provided. The system includes an adapter (60) including first and second cylindrical portions defining a fluid flow channel, the first cylindrical portion comprising two adjacent wedge-shaped protrusions (68). Each wedge-shaped protrusion is infrared transmittive and defines an outer surface and an inner surface. The system further includes a tube and an infrared reflective sensor having an infrared light emitter (42,52) and an infrared light detector (44,54). The infrared light emitter and the infrared light detector are positioned at or near an adapter so that an infrared light can be transmitted to the adapter and at least a portion of the infrared light reflected off the adapter can be detected by the infrared light detector.

A heated patient tube assembly that carries and gradually warms fluids to a desired temperature and maintains the desired temperature until the fluids are delivered to a patient includes an elongated hollow tube; a heating assembly at least partially embedded within the tube for heating the tube and fluids carried in the tube; and a control assembly for controlling the heating assembly such that the fluids exit the tube at a desired and consistent temperature.