Disclosed are hypodermic needle devices with a dose dispensing mechanism and methods of using those hypodermic needle devices. The dose dispensing mechanism, which may be an electronically-controlled pump, may be used to measure out a specific dosage amount of a drug while compensating for environmental factors, such as temperature and pressure. This allows the device to be used by patients for self-administration since a specific dosage amount of the drug may be precisely delivered regardless of the environmental conditions at the time of delivery. The specific dosage amount may be set using the device or remotely, and a fingerprint sensor may be used to prevent injecting the drug into the wrong patient.

A portable medical apparatus for administering a fluid drug in doses, including a first housing including a reservoir unit with an outlet into a fluid path for conducting the drug, a second housing including a conveying unit for dispensing the drug from the reservoir unit in doses and a suitable controller for controlling the conveying unit, an adaptor including a coupling structure for receiving the first housing and the second housing and an attaching structure for extra-corporeally carrying the adaptor on a patient, wherein the conveying unit and the reservoir unit can be joined together to form an integrated mechanical and fluidic unit, and coupled to and decoupled from at least two differently configured adaptors, wherein at least one of the adaptors is configured to be directly attached to the surface of the skin and at least one of the adaptors is configured to be worn on or carried by an article of clothing or a wearing system (e.g., a belt).

Methods and devices for accurately pumping small quantities of liquid to a patient with a broad range of flow and low cost.

A delivery system configured to be secured on a patient skin which comprises a first container having a first variable volume; a second container having a second variable volume; and a skin adherable unit configured to secure the first container and the second container to the patient skin. The medical device may further comprise a containers' interface configured to operatively couple the first container and the second container such that a volume increase of the second variable volume may induce a volume decrease of the first variable volume. Preferentially, the system further comprises a vent device configured to prevent any unintended pressure increase in the first storage compartment.

Infusion pump control unit keypad assemblies are provided, and include a cover assembly having an outer surface and an inner surface and a perimeter gasket disposed within a raised perimeter on the outer surface of the cover assembly. A lens and a circuit assembly are coupled to the outer surface of the cover assembly. A switch assembly is coupled to the circuit assembly, a shield assembly is coupled to the switch assembly, a light assembly is coupled to the shield assembly and an overlay assembly is coupled to the light assembly. Methods of making infusion pump control unit keypad assemblies are also provided.

A self-compensating chucking device may be provided. The chucking device may form a portion of a latching door handle of a door of an infusion pump. The door and a housing of the infusion pump may form a clam-shell clamp that secures infusion tubing to pumping mechanisms of the infusion pump. The latching door handle may include a latching door mechanism that includes a tapered pin. The tapered pin may extend through an outer portion of a door housing, an opening in a handle of the door, and into an opening in an inner portion of the door housing. The opening in the handle of the door may have a tapered inner surface that corresponds to the taper the tapered pin to form the chucking device. The pin may include a groove configured to accept an E-clip that retains the tapered pin within the door housing.

Some embodiments are directed to portable devices for transferring fluids from an external source and controllably infusing the fluids into a patient, particularly portable infusion pump devices, and protective housings for such devices, which include a pump unit, a computer, a portable fuel source, and a seal for securing the contents substantially within the protective housings of the device. Some embodiments may be formed as a single infusion pump unit or may be formed when two infusion pump units are engaged. Some embodiments also relate to methods of use of portable devices and method for the manufacture of portable devices and protective housings for such devices.

A portable medical apparatus for administering a fluid drug in doses, including a first housing including a reservoir unit with an outlet into a fluid path for conducting the drug, a second housing including a conveying unit for dispensing the drug from the reservoir unit in doses and a suitable controller for controlling the conveying unit, an adaptor including a coupling structure for receiving the first housing and the second housing and an attaching structure for extra-corporeally carrying the adaptor on a patient, wherein the conveying unit and the reservoir unit can be joined together to form an integrated mechanical and fluidic unit, and coupled to and decoupled from at least two differently configured adaptors, wherein at least one of the adaptors is configured to be directly attached to the surface of the skin and at least one of the adaptors is configured to be worn on or carried by an article of clothing or a wearing system (e.g., a belt).

An infusion pump assembly includes an enclosure assembly. A reservoir assembly is positioned at least partially within the enclosure assembly and is configured to contain an infusible fluid. A pump assembly is positioned at least partially within the enclosure assembly and is configured to effectuate the dispensing of the infusible fluid contained within the reservoir assembly. Processing logic is positioned at least partially within the enclosure assembly and is configured to control the pump assembly. A removable cover assembly is configured to releasably engage the enclosure assembly. A combination of the removable cover assembly and at least a portion of the enclosure assembly defines a power supply cavity configured to prevent a removable power supply assembly from being reverse-polarity electrically coupled to the processing logic.

The present invention relates to a medical device protection assembly and to a respective medical device. The protection assembly comprises at least one reorientation member being connectable with a medical device and being operable to orient the medical device into a predefined orientation in the event the medical device is subject to a free-fall.