Disclosed are various embodiments for illuminated medical infusion including, for example, a medical infusion system which includes a source of illumination and an illuminating infusion line and wherein the illuminating infusion line includes an integrated fluid transmission channel and light transmission channel.

A clamp includes a housing, a fixed gripper, a moveable gripper, a driven member, and an actuator. The housing includes first and second tracks. The fixed gripper is coupled to the housing. The driven member is configured to slide within the first and second tracks of the housing. The moveable gripper is operatively coupled to the driven member. The actuator is configured to move the driven member towards a first position to thereby move the moveable gripper towards the fixed gripper. The actuator is further configured to move the driven member towards a second position to thereby move the moveable gripper away from the fixed gripper.

An infusion height warning and blocking device for an infusion stand is provided. The infusion height warning and blocking device includes a communication module for receiving at least one sensing signal from at least one gravity sensor; and a processing unit for calculating an infusion height difference between a start position and a usage position according to the at least one sensing signal, and generating at least one height indication signal according to the infusion height difference and at least one height difference threshold.

A securing device for securing an infusion appliance to an infusion container includes a first fastening element, which is designed in such a way that it is connectable to a fastening region of the infusion container, and a second fastening element, which is arranged at a distance from the first fastening element and which is designed in such a way that it is connectable to a fastening region of the infusion appliance. At least one connection element connects the first fastening element and the second fastening element to each other. The securing device can be used for medical infusion and transfusion arrangements.

A waste collection unit for collecting waste material. A reservoir is supported on a portable cart for storing a liquid on the portable cart when positioned away from a docking station. A sprinkler may be coupled to the waste container and in fluid communication with the reservoir. The sprinkler is configured to direct the liquid from the reservoir towards the waste container. The reservoir is configured to receive additional liquid from the docking station to urge the liquid from the reservoir towards the sprinkler. A prefill pump may be supported on the portable cart and in fluid communication with the waste container and operable to convey the liquid from the reservoir to the waste container. A controller may be in electronic communication with a valve assembly to control flow of the liquid from the docking station into at least one of the reservoir and a second waste container.

Anti-snagging components for use in infusion sets are provided. The anti-snagging component includes a sliding surface that guides an infusion set component past an obstruction when the infusion set is moved during manufacture or use. An anti-snagging structure may be integrally formed as a portion of an infusion set component or the anti-snagging structure may be a separate component that connects or attaches to an infusion set component. Some anti-snagging structures include a covering portion to cover a needleless connector and a tail portion to connect to a length of tubing. The covering portion may include an anti-microbial coating.

Fluid supply systems and methods for therapeutic fluid delivery systems, including those used for negative pressure wound therapy (NPWT) systems and methods.

A system for delivering a fluid to tissue and a method of using same are provided. The system includes a tissue clip for securing a tissue fold and a tissue puncturing device attachable to the tissue clip. The system further includes a mechanism for sensing the tissue fold and releasing a safety mechanism in the tissue puncturing device so as to enable manual deployment of a tissue puncturing element from the tissue puncturing device.

A system and method for self-aligning and connecting a device to a modular rack. The system includes a device comprising a connector receptacle configured to receive a connector plug, a connector seal and a bracket fixed to the device, a modular rack comprising the connector plug, a connector shell seal and a shelf configured to receive the bracket and guide the shelf in a plurality of directions. When the bracket of the device is inserted into the shelf of the modular rack, the shelf travels in the plurality of directions to self-align the connector plug of the modular rack to the connector receptacle of the device to ensure engagement of the connector plug to the connector receptacle. The connector seal is biased towards the connector shell seal to create a seal and ensure engagement of the connector plug relative to the connector receptacle.

An intradermal fluid delivery device that uses a processor controlled electromechanical delivery mechanism is provided. An air pump pushes fluid containing medication or saline from a fluid compartment through a microneedle array into a person's skin. The processor repeatedly turns the air pump on or off, for the fluid to gradually be injected into the person's skin. The processor may be configured to control the total fluid delivery time as well as the granularity of the fluid delivery. The total fluid delivery time may be set to T, and the time period T may be divided into smaller periods t.sub.1 to t.sub.n, where the fluid may be administered in a period t1, the fluid delivery may then be stopped for a period t2, followed by another fluid delivery period, etc. The periods t1 to tn may be the same or of different lengths.