An apheresis system includes a chamber configured to receive a centrifuge assembly and a moving loop holder. The moving loop holder includes a loop holder that has a loop connection that is configured to interact with a flexible loop received by the centrifuge assembly. The moving loop holder is configured to move between a first position and a second position, where in the first position, the moving loop holder is a first distance from the centrifuge assembly, and in the second position, the moving loop holder is a second distance from the centrifuge assembly. The centrifuge assembly is prevented from moving from an operating state to a loading state when the moving loop holder is in the first position, and the centrifuge assembly is allowed to move from the operating state to the loading state when the moving loop holder is in the second position.

A medication delivery device having a lock element. The device is connectable to an electrical plug of a conduit. The device includes an external housing with an opening that ports to a plug receiving hollow within an interior volume. An electrical circuit connected to at least one of a rechargeable battery and a memory controller includes a connection element within the plug receiving hollow. The lock element travels within the plug receiving hollow when a dose delivery assembly of the device operates for forcing medication from the device. The lock element is sized and positioned to have its travel halted by abutment with the plug, when the plug is within the plug receiving hollow and electrically interfacing with the connection element, to thereby halt the dose delivery assembly from further operating for forcing medication from the device.

A load cell assembly includes a load cell and a deflection portion. The load cell includes a fixed end and a free end. The free end is configured to receive a force in a first direction. The deflection portion includes a first component and a second component. The first component is coupled to the free end of the load cell. The first component defines a first cam surface. The second component is configured to support the vessel. The second component defines a second cam surface. The second cam surface is configured to engage the first cam surface. In an engaged state, the second cam surface is in continuous direct contact with the first cam surface. In a disengaged state, at least a portion of the second cam surface is disengaged from the first cam surface. The load cell assembly includes a central axis.

A fluid collection loop includes a flexible tube having a first end and a second end, a connector, and a fluid component collection bladder. The connector is configured to couple the first end of the flexible loop and the fluid component collection bladder. The fluid component collection bladder includes a first chamber defined between a top end and a flow chamber separator, and a second chamber defined between a bottom end and the flow chamber separator. The flow chamber separator extends from a first end of the fluid component collection bladder towards a second end of the fluid component collection bladder and a gap exists between the fluid component collection bladder and the second end of the fluid component collection bladder.

A method includes detecting a beginning of a donation process; in response to detecting the beginning of the donation process, providing an output; determining an amount of time remaining for the donation process; in response to detecting the amount of time remaining for the donation process, updating the output; detecting a loss in pressure; in response to detecting the loss in pressure, updating the output; detecting an ending of the donation process; and in response to detecting the ending of the donation process, updating the output. The donation process may include a plasma donation using an apheresis machine. The detecting the beginning of the donation process may include detecting a flow of fluid. The output may include one or more of a light and a sound. The output may be provided on a side of an apheresis machine.

An apheresis system at least partially defines a chamber and includes centrifuge that is movable between lock and unlock states. The centrifuge includes a base, cover, lock assembly, and latch assembly. The cover engages the base and defines slots. The lock assembly is coupled to the base and rotates between latched and unlatched states. The lock assembly includes tabs and a protrusion. The tabs are in the slots of the cover. The protrusion at least partially defines a receptacle. The latch assembly is coupled to the base and includes a lever and engagement component attached thereto. In the latched state, the protrusion engages the engagement component to reduce or prevent rotation of the lock assembly. In the unlatched state, the lock assembly can rotate. In the lock state, the tabs are at least partially within the slots. In the unlock state, the cover is movable with respect to the base.

A device and method for delivering a fluid as an ejected stream of droplets during inhalation uses inertial filtering to cause a first plurality of droplet particles generated by an ejector mechanism to pass through an airflow exit while a second plurality of droplet particles having a greater mass mean aerodynamic diameter than the first plurality of droplet particles fails to pass through the airflow exit.

Systems and methods for automatically delivering medication to a user. A sensor coupled to a user can collect information regarding the user. A controller can use the collected information to determine an amount of medication to provide the user. The controller can instruct a drug delivery device to dispense the medication to the user. The drug delivery device can be a wearable insulin pump that is directly coupled to the user. The controller can be part of or implemented in a cellphone. A user can be required to provide a confirmation input to allow a determined amount of insulin to be provided to the user based on detected glucose levels of the user. The sensor, controller, and drug delivery device can communicate wirelessly.

A nebulizer for a fluid, includes a container containing the fluid; a housing part which can be detached from the nebulizer for replacing the container; an inner part; a retaining element connected with and not detachable from the inner part, where the housing part is releasable fixed to the inner part by the retaining element; a delivery mechanism for dispensing the fluid; a manually depressible actuator member, which is a separate part from the retaining element and acts on the retaining element, and wherein the actuator member is depressed to elastically deform or flex the retaining element to allow detachment of the housing part.

A breathing assistance apparatus is configured with features that improve serviceability of the apparatus. The apparatus can include animations to provide instruction regarding correcting easily-identified fault conditions and to provide instruction regarding routine maintenance routines. The apparatus also can be configured with top level control menus that are obscured in a manner to limit manipulation of the top level control elements by unauthorized users.