A medicine temperature control device which is attachable to or detachable from a medicine pressure injection system and a driving method thereof are provided. A medicine temperature control device which is attachable to or detachable from a medicine pressure injection system includes a pressurization module which includes an expansion unit which expands to pressurize a container containing a medicine, a controller which supplies and pressurizes a fluid to the expansion unit and controls a temperature of the medicine, and a power source which supplies a power to drive the controller; and a temperature control module which includes a temperature control chamber to control a temperature of the medicine.

An infusion pump system is disclosed. The infusion pump system includes an infusion pump and a controller device in wireless communication with the infusion pump, wherein the controller including instructions for controlling the infusion pump, wherein the instructions may be synchronized with a secure web portal.

A device for preparation of infusion fluid including: a first portion including: a fluid conduit comprising electrically conductive material; electrical circuitry electrically connected to the fluid conduit; a second portion selectively couplable to the first portion and including: at least one sensor for sensing fluid within the fluid conduit; a power supply and/or connectivity to a power supply; wherein mechanical coupling of the first portion to the second portion electrically connects the electrical circuitry to the power supply and/or connectivity to the power supply.

Various exemplary liquid drug pumps with a flexible drug reservoir are provided. In general, a pump includes a flexible reservoir configured to contain a liquid drug therein for delivery to a patient wearing the pump. The reservoir is configured to be filled with the drug from a drug storage container, which can either be external to the pump or disposed within the pump.

A device may be configured with a housing having a reservoir and an outlet separated by a heat rupturable membrane. The membrane may serve to separate a material held within the reservoir from the outlet until the membrane is ruptured. The membrane may include a heater configured to selectively rupture the membrane when actuated. The heater may be physically removed and/or thermally insulated from at least one of an environment surrounding the device and the reservoir.

Systems and methods include a heat transfer body with opposing major surfaces formed from a thermally conductive substrate in intimate thermal interaction with an alumina exterior surface that extends across the major surfaces of the body. In an illustrative example, the heat source may be a substantially planar, silicone-based heater source (P-SBHS). The heat transfer body may be configured to thermally interact, for example, heat from a heat source proximate a first of the major surfaces to a second of the major surfaces. A temperature sensor module may be located, for example, proximate to the first major surface such that a temperature sensor thermally interacts with the first major surface. The temperature sensor module may, for example, insulate the temperature sensor from the P-SBHS.

An intravenous fluid conditioning system includes a housing having a first chamber and a second chamber. A volume of heat transfer medium is located in the first chamber and the second chamber. A first intravenous fluid line extends through the first chamber and a second intravenous fluid line extends through the second chamber. One or more thermoelectric devices are located in the housing, such that a first side of each of the one or more thermoelectric devices is in thermal communication with the first chamber and a second side of each of the one or more thermoelectric devices opposite the first side is in thermal communication with the second chamber. The one or more thermoelectric devices exchange thermal energy with a volume of intravenous fluid selectably flowed through the first intravenous fluid line or the second intravenous fluid line to condition the intravenous fluid.

A warming device and system for warming medical gel to a comfortable temperature prior to application to a patient. A warming chamber configured to receive one or more gel containers (e.g., packets or bottles) disposed in a horizontal orientation with a cover sealing the chamber. Multiple protrusions and/or depressions disposed on an inside surface of the chamber can be used to soften thermal conduction of heat to the gel containers and inhibit hot spots. A flexible heating element and an intermediate thermal conducting member can extend up one or more sides of the warming chamber. Multiple buttons can be used to set different gel temperature settings.

An injector for delivering a therapeutic product may include a base having a flexible surface that conforms to various body contours of a patient and defines one or more an injection chambers. The injector may have a height that is substantially less than its width, thereby defining a low profile, which provides a larger more stable base that can pinch or stretch the skin in a controlled manner. The larger base can also accommodate larger volumes via multiple injection chambers and/or large combined primary containers.

A mixing and/or reconstitution system reduces the possibility of user error and provides a well mixed and/or reconstituted drug in a short time. The system comprises a device containing a first material within a first chamber, a housing, and a plunger, the plunger comprising a second chamber containing a second material, wherein one of the first and the second material is a fluid, and a movable element with an electric, magnetic, or paramagnetic characteristic, wherein the second chamber is initially closed; and a base unit comprising a recess for accommodation of the device, a control unit, and an electromagnetic unit which is adapted to produce an electromagnetic field penetrating the recess, wherein the control unit can electrically operate the electromagnetic unit such that the element contained in the second chamber moves in a direction of the device determined by the electromagnetic field and fluidly communicates the first and second chambers.