The present disclosure is generally directed to a delivery device housed within an outer cartridge and useful for delivering a fluid to the IO space of a subject at a relatively constant volumetric flow rate over an extended period of time. The delivery device may be fluidly coupled to an existing IO access device or IV line positioned in the IO space of the subject or may be coupled to an IO access device disposed within the outer cartridge.

Various systems and methods for detecting air in a chamber of an infusion system are disclosed. In one embodiment, a determination is made that air is contained in the chamber on the basis of a change in the average force exerted against the plunger utilizing a derivative spike for event detection and a systematic reduction in the average force to confirm the nature of the change. In another embodiment, a determination is made that the chamber contains air when a difference between the current force profile and a baseline force profile crosses a threshold. In an additional embodiment, a force profile is classified as being an air force profile or a liquid force profile based on extracted features of the force profile.

Bubble traps for use in medical fluid lines and medical fluid bubble trap systems are disclosed herein. In some embodiments, the bubble trap is configured to trap gas (e.g., air) that flows into the bubble trap from a fluid line. In some embodiments, the bubble trap includes an inlet and an outlet and a chamber between the inlet and the outlet. For example, in some embodiments, the bubble trap is configured to inhibit gas from flowing into the outlet once gas flows into the chamber from the inlet. In some embodiments, the bubble trap is in fluid communication with a source container, a destination container, and/or a patient.

Bubble traps for use in medical fluid lines and medical fluid bubble trap systems are disclosed herein. In some embodiments, the bubble trap is configured to trap gas (e.g., air) that flows into the bubble trap from a fluid line. In some embodiments, the bubble trap includes an inlet and an outlet and a chamber between the inlet and the outlet. For example, in some embodiments, the bubble trap is configured to inhibit gas from flowing into the outlet once gas flows into the chamber from the inlet. In some embodiments, the bubble trap is in fluid communication with a source container, a destination container, and/or a patient.

An infusion device includes an infusion pump and an infusion tube assembly. The infusion tube assembly includes a first tube body connected to the infusion pump, a tube joint structure having first, second and third tube joints, a second tube body, and a clamping device on the second tube body. The clamping device is to clamp the second tube body. An infusion method includes instructing the infusion pump to perform an infusion operation. When bubbles are detected in a liquid in the infusion tube assembly, the infusion pump is instructed to stop the infusion operation and a bubble alarm is generated. After the infusion pump stops the infusion operation, it is determined whether a pressure of the liquid first drops to a first pressure value and then rises to a second pressure value. If yes, a rinsing operation is performed.

An infusion pump (10) includes a fluid chamber (28) having an outlet valve (34) and a piezo-stack actuator (36) comprising a stack of piezo-electric layers (38). An electronic processor (18) is programmed to operate the outlet valve and the piezo-stack actuator to pump fluid through the fluid chamber at a programmed flow rate.

An air removal apparatus for an autoinjector is disclosed. The air removal apparatus can remove or trap air within the autoinjector, preventing the removed or trapped air from displacing medicament or being injected into the patient. The air removal apparatus removes or traps air by creating a vacuum. The vacuum can remove air from the medicament and can trap air within a section of the auto injector that is separated from the medicament.

An air removal apparatus for an autoinjector is disclosed. The air removal apparatus can remove or trap air within the autoinjector, preventing the removed or trapped air from displacing medicament or being injected into the patient. The air removal apparatus removes or traps air by creating a vacuum. The vacuum can remove air from the medicament and can trap air within a section of the auto injector that is separated from the medicament.

A self-righting device is disclosed having a support body for supporting a medicament delivery device, where the support body has a mass, a center of gravity (G) and a shape such that the self-righting device, when positioned on a substantially horizontal surface, moves from an unbalanced position to an upright position. The self-righting device can also have a mechanical adaptor configured for attachment to the support body and for holding an elongated medicament delivery device at an angle less than 30 degrees from a vertical axis when the self-righting device is in the upright position. An assembly of a self-righting device and an elongated medicament delivery device is also provided.

There is provided a medicinal liquid injection port to be implanted subcutaneously. A housing main body is provided with a medicinal liquid storage portion therein, an opening portion that opens the medicinal liquid storage portion, and a discharge hole that communicates with the medicinal liquid storage portion and configured to be connected with a tube. A septum attached to the opening portion of the housing main body and provided with a puncturable region that can be punctured with a puncture needle. A contrast portion is disposed in the septum over a thickness direction of the septum so as to detect the puncturable region of the septum with the ultrasonic wave. The contrast portion is provided in the septum within a thickness region of the septum and all of the contrast portion is positioned at an inner side of the septum in the thickness direction of the septum.