Method for 3D printing, comprising the following steps: providing a packaging (2′) having at least one recess (3′) for receiving a product (1′), wherein the shape of the recess (3′) corresponds at least in part to the shape of the product (1′) and wherein the recess (3′) forms a protuberance at the other side of the packaging (2′); providing a 3D printer with a print base (5′) having at least one recess (6′) for receiving the protuberance formed by the recess (3′) of the packaging (2′); inserting the packaging (2′) in the print base (5′) such that the protuberance formed by the recess (3′) of the packaging (2′) is received by the recess (6′) of the print base (5′); filling a print head (7′) of the 3D printer with at least one material for printing the product (1′); 3D printing the product (1′) inside the recess (3′) of the packaging (2′), wherein the part of the recess (3′) corresponding to the shape of the product (1′) serves as the mold and print support, resp., for those layers of the product (1′) which are 3D printed first. The method is performed with a system for 3D printing, comprising a packaging (2′) having at least one recess (3′) for receiving a product (1′), wherein the shape of the recess (3′) corresponds at least in part to the shape of the product (1′) and wherein the recess (3′) forms a protuberance at the other side of the packaging (2′); and a 3D printer with a print head (7′) and a print base (5′); characterized in that the print base (5′) has at least one recess (6′) for receiving the protuberance formed by the recess (3′) of the packaging (2′) to support the packaging (2′) with the recess (3′) such that the product (1′) can be 3D printed inside the recess (3′) of the packaging (2′), wherein the part of the recess (3′) corresponding to the shape of the product (1′) serves as the mold and print support, resp., for those layers of the product (1′) which are 3D printed first.

Various aspects of the subject disclosure relate to a compounder system having a cartridge that includes fluid pathways controllable by valves of the cartridge. A pump component within the cartridge is actuable to move fluid through the controllable fluid pathways. The cartridge includes a backpack for management of tubing to couple the cartridge to a receiving container. A disposable waste container is contained by the cartridge and the backpack. A syringe holder is provided for use of a syringe as a receiving container to receive a compounded medication.

Phyto material tablets, tablet vaporizers, methods and apparatus for forming phyto material tablets. The tablets are formed to increase vaporization efficiency. Tablets can include break regions to facilitate fracturing into multiple pieces for vaporization. The tablets can also include multiple layers of different phyto material mixtures. Compression molds are used to shape the tablets. The compression molds can be provided on a rotational assembly to facilitate rapid manufacturing of multiple tablets. The vaporizers include heating chambers that are configured to increase the surface area of the tablets exposed for vaporization. The heating chambers include compression or fracture members that compress and/or encourage fracturing of the tablets to assist vaporization.

Phyto material tablets, tablet vaporizers, methods and apparatus for forming phyto material tablets. The tablets are formed to increase vaporization efficiency. Tablets can include break regions to facilitate fracturing into multiple pieces for vaporization. The tablets can also include multiple layers of different phyto material mixtures. Compression molds are used to shape the tablets. The compression molds can be provided on a rotational assembly to facilitate rapid manufacturing of multiple tablets. The vaporizers include heating chambers that are configured to increase the surface area of the tablets exposed for vaporization. The heating chambers include compression or fracture members that compress and/or encourage fracturing of the tablets to assist vaporization.

A granulated nutritional supplement dispensing machine extracts single-serving doses from a multi-serving supplements cartridge for delivery as a drinkable solution. A lead serving chamber is pierced so that its powered contents drain into a mixing cup together with a metered quantity of water from an integrated water tank. A vibrator unit assists drainage of the granulated materials from the lead serving chamber. The mixing cup is rotated at high speed to blend the water and supplements into a slurry. The supplements cartridge is indexed after (or before) use so that an unopened serving chamber is presented each time for extracting its supplements. This enables partially-used supplements cartridges to be used in the machine, as is conducive in multiple-user households. The supplements cartridge is configured with read-write data capability to indicate whether or not the contents of each serving chamber have been emptied.

Various aspects of the subject disclosure relate to a compounder system having a cartridge that includes controllable fluid pathways. The cartridge may include a syringe pump for moving fluid and/or gas, and one or more syringe valves or rotary valves for controlling which of the controllable fluid pathways is open for flow of the fluid and/or gas.

A manifold for control of fluid and/or vapor flow between a container and a pump cartridge for a compounder system is provided. One or more manifolds may be disposed in a magazine configured to secure and align the manifolds with a plurality of ports in the cartridge. Each manifold may include a needle having forward and rear openings to a central bore. A needle housing may include a slot configured to receive a push rod for actuating the needle forward and backward. In a forward, engaged position, the openings in the needle may be disposed on opposite sides of a sealing member of the manifold to form a fluid pathway through the manifold. In a rearward, disengaged position, both the forward and rear openings in the needle may be disposed on the same side of the sealing member to prevent fluid and vapor from flowing through the manifold.

The present disclosure relates generally to manufacturing pharmaceutical products using additive manufacturing technology. An exemplary printing system comprises: a material supply module for receiving a set of printing materials; a flow distribution module comprising a flow distribution plate, wherein the material supply module is configured to transport a single flow corresponding to the set of printing materials to the flow distribution plate; wherein the flow distribution plate comprises a plurality of channels for dividing the single flow into a plurality of flows; a plurality of nozzles, wherein the plurality of nozzles comprises a plurality of needle-valve mechanisms; one or more controllers for controlling the plurality of needle-valve mechanisms to dispense the plurality of flows based on a plurality of nozzle-specific parameters; and a printing platform configured to receive the dispensed plurality of flows, wherein the printing platform is configured to move to form a batch of the pharmaceutical product.

A method and apparatus for pharmacy fulfillment and verification of non-sterile compounding. A system includes an entry node, the entry node including at least a processor, a memory and an input/output device, the memory including at least an operating system and an order entry process, and a pharmacy fulfillment and verification of non-sterile compounding system, the entry node communicatively linked to the pharmacy fulfillment and verification of non-sterile compounding system, the pharmacy fulfillment and verification of non-sterile compounding system including a set of components, the set of components including at least a formulating component, a fabrication component and a dispensing component.

The system of the present invention includes a conductive element, an electronic component, and a partial power source in the form of dissimilar materials. Upon contact with a conducting fluid, a voltage potential is created and the power source is completed, which activates the system. The electronic component controls the conductance between the dissimilar materials to produce a unique current signature. The system can be used in a variety of different applications, including as components of ingestible identifiers, such as may be found in ingestible event markers, e.g., pharma-informatics enabled pharmaceutical compositions.