Device (1) for filling blood products (12) into at least two administration containers (2), comprising at least one receptacle (3) for dispensing the blood product (12) into the device (1), a channel system (4, 7, 8, 17) connected to carry fluid to the administration containers (2), and an air exhaust assembly (10, 11, 15), where the device (1) further comprises a plate-shaped component (6) in which the channels (7, 8, 17) of the channel system run, through which the administration containers (2) can be filled in parallel with equal volumes of the blood product (12).

A combinatorial drug delivery device is provided for delivering a predetermined selection of drug components, each of the drug components being contained in a drug vial. The device includes a plurality of modules, wherein each of the modules includes: a body having an interior volume formed to accommodate a drug vial; a cannula protruding into the interior volume, the cannula terminating at a free end, first and second openings being formed in the free end with first and second lumens extending therefrom and through the cannula; a socket located on an exterior portion of the body; a first passageway extending between, and in communication with, the socket and the first lumen; a boss protruding from an exterior portion of the body; and, a second passageway extending from, and in communication with the second lumen, the second passageway extending through the boss to terminate at an exit opening formed therein.

In one aspect, a combinatorial drug delivery device is provided for delivering a predetermined selection of drug components. The device includes a plurality of modules, each including: a body having an interior volume; a spike plate movably disposed in the interior volume, the spike plate having a protruding cannula and first and second ports. The device also includes a base tray which includes: a framework defining a plurality of wells, each of the wells formed to insertingly receive one of the modules; for each of the wells, first and second inlet ports formed to interface with the first and second ports of the module being received in the respective well; passageways to connect certain wells with adjacent wells to permit fluid flow therebetween. For each of the wells, the spike plate of the respective module being maintained in a stationary position with the module being inserted into the well.

A save-and-draw capping system may be snapped or otherwise attached/connected to the top of a liquid medicine bottle having a rubber surface that may be punctured using a syringe to draw medicine. Using the save-and-draw capping system, the rubber surface may be sealed after it has been punctured. A secondary seal may be used to apply pressure to the cap of the liquid medicine bottle. A draw attachment, such as a draw needle, may be attached to the save-and-draw cap so that a hose may be connected to the liquid medicine bottle when multiple injections are needed. The save-and-draw capping system may be removed from one liquid medicine bottle to be used on another liquid medicine bottle.

Drug delivery safety devices comprise a safety needle device comprising a needle hub, a needle cannula, and a safety feature; and a cap comprising a cap body having a proximal end attached to the safety needle device and a distal end having an access opening that is in fluid communication with the needle cannula. The safety needle device allow for an integrated device for both filling and injection that do not interfere with passive safety features. The caps may have a fill feature that engages with a safety feature of the safety needle device to keep it in a fill state.

An evacuated bottle system including a bottle defining a hollow interior, the bottle having a neck defining an opening that provides fluid communication with the interior; a cap assembly including a funnel having a first portion and a second portion, where the second portion extends radially outward from the first portion to form a floor on an interior thereof and a shoulder on an exterior thereof, the first portion defining a first bore and the second portion defining a second bore fluidly connected to the first bore; a self serum stopper having a self sealing membrane that extends radially outward to overlie at least a portion of the floor of the funnel; and a cap having a cap wall sized to fit over the funnel and a cover portion extending radially inward from the cap wall.

An evacuated bottle system including a bottle defining a hollow interior, the bottle having a neck with a rim defining an opening; a cap assembly supported on the bottle, the cap assembly including a funnel having a first portion and a second portion, the first portion being insertable within the interior of the bottle and the second portion engaging a portion of the bottle to support the funnel above the rim, the funnel defining a bore that fluidly communicates with the hollow interior of the bottle; a self-sealing membrane that covers the bore formed by the funnel to selectively seal the hollow interior of the bottle; a cap attachable to the bottle, the cap including a cover portion that extends at least partially over the self-sealing membrane to restrain movement thereof, the cover portion being axially spaced from the self-sealing membrane to define a gap that permits axial movement of the self-sealing membrane to selectively open the bottle to fluid communication outside of the bottle.

A save-and-draw capping system may be snapped or otherwise attached/connected to the top of a liquid medicine bottle having a rubber surface that may be punctured using a syringe to draw medicine. Using the save-and-draw capping system, the rubber surface may be sealed after it has been punctured. A secondary seal may be used to apply pressure to the cap of the liquid medicine bottle. A draw attachment, such as a draw needle, may be attached to the save-and-draw cap so that a hose may be connected to the liquid medicine bottle when multiple injections are needed. The save-and-draw capping system may be removed from one liquid medicine bottle to be used on another liquid medicine bottle.

An example of a method of enabling medical fluid transfer between a source container and a destination container can comprise the steps of providing a closed-system fluid transfer module comprising a first closeable, resealable medical connector and a second closeable, resealable medical connector, a multidirectional fluid control valve with a driving interface configured to interface with an electromechanical driver of an electronic medical fluid transfer device, and an intermediate container or an intermediate pumping region; and instructing a user to couple the closed-system fluid transfer module to the electronic medical fluid transfer device.

In one aspect, a combinatorial drug delivery device is provided for delivering a predetermined selection of drug components. The device includes a plurality of modules, each including: a body having an interior volume; a spike plate movably disposed in the interior volume, the spike plate having a protruding cannula and first and second ports. The device also includes a base tray which includes: a framework defining a plurality of wells, each of the wells formed to insertingly receive one of the modules; for each of the wells, first and second inlet ports formed to interface with the first and second ports of the module being received in the respective well; passageways to connect certain wells with adjacent wells to permit fluid flow therebetween. For each of the wells, the spike plate of the respective module being maintained in a stationary position with the module being inserted into the well.