A medical device system. The system includes a first medical device, a first remote interface, and a second remote interface in communication with the first remote interface and the first medical device, wherein the first medical device sends a command to the first medical device through the second remote interface, and wherein when the second remote interface receives the command, the command must be confirmed by the second remote interface before the command is send by the second remote interface to the first medical device.

Disclosed is a method of controlling operation of a medical device that regulates delivery of a fluid medication to a user. The method receives meter-generated values that are indicative of a physiological characteristic of the user, and are produced in response to operation of an analyte meter device. The method obtains sensor-generated values that are indicative of the physiological characteristic of the user, and are produced in response to operation of a continuous analyte sensor device, different than the analyte meter device. The medical device is operated in different modes when: a valid meter-generated value is available; a valid meter-generated value is unavailable and a current sensor-generated value satisfies first quality criteria; or a valid meter-generated value is unavailable and the current sensor-generated value satisfies second quality criteria but does not satisfy the first quality criteria.

Disclosed is a computer controlled dosage system, for dosage adjustment for a mobile, hand held, inhaler for delivering a dosage of a medicine, is provided. The system comprises at least one measuring device for measuring at least one parameter; and a handheld mobile computer separate from the inhaler, the computer being configured to communicate with the at least one measuring device and with a remote memory for sending and receiving information to and from patient medical records of the remote memory for storage in a memory of the computer, and the computer being configured to receive a manual input for storage in the memory of the computer. The computer is configured to create a data set for setting a plurality of levels of different dosages of medicine based on the medicine used by the inhaler, the information from the patient's medical records of the remote memory, and the manual input; and the computer is further configured to store the data set in the memory of the computer. The computer is further configured to generate an indication indicating a dosage adjustment for the inhaler, based on the at least one parameter and on one of the plurality of levels of dosage of the data set, the indication indicating one of the plurality of levels of dosage of the data set as the dosage adjustment for the inhaler. A dosage regime generated by the computer controlled dosage system is also disclosed.

Systems and methods are disclosed herein for providing a configuration code for customizing a glucose level control system for at least an initial period. The configuration code can be based on one or more dosing parameters from a tracked medicament therapy administered to a subject over a tracking period by the glucose level control system. The configuration code includes encoded dosing parameters including a correction dosing parameter based on at least some of the correction boluses of medicament administered during the tracking period, a food intake dosing parameter comprising an indication of a food intake bolus size of medicament based on one or more food intake boluses provided during the tracking period, and a basal dosing parameter based on at least some of the basal doses of medicament administered during the tracking period.

A system and a method for management of diabetes are provided. The system includes an infusion pump, glucose sensor, and controller that is programmed to control insulin delivery based upon at least one stored variable. The controller calculates a maximum insulin delivery rate based on the default basal insulin delivery rate, temporary basal insulin delivery rate, extended bolus rate, or a combination thereof.

Medical devices and related patient management systems and methods are provided. A method of presenting information pertaining to operation of a medical device involves obtaining historical glucose measurement data for a patient from a database, identifying, based on the historical glucose measurement data, a first set of event patterns within respective ones of a plurality of monitoring periods, obtaining an adjusted set of glucose measurement data determined based on the historical glucose measurement data and an uncertainty metric associated with the historical glucose measurement data, identifying, based on the adjusted set of glucose measurement data, one or more event patterns within respective ones of the plurality of monitoring periods, and generating a graphical user interface display comprising an event detection region based at least in part on the first plurality and the one or more sets of event patterns.

The disclosed embodiments are directed to an automatic drug delivery (ADD) system device configured to provide bolus dosing of insulin. The embodiments include a system and method for providing an improved meal input interface for the user as well as methods for the use of the information provided by the user to both improve the post-prandial bolus dosing of insulin and to advise the user on meals that will lead to improved blood glucose control for the user.

This invention discloses a method of calculating insulin sensitivity factors for use in calculating insulin doses dynamically as a function of current blood glucose level based on a temporally-weighted average of the patient's total daily insulin dose, the pharmacodynamic and/or pharmacokinetic profile of the insulin used, and the patient's typical ratio of basal insulin to bolus insulin. When average total daily insulin and the other relevant variables are inserted into the equation, the result is a mathematical function that can be used to estimate the effects of each unit of insulin delivered on a patient's blood glucose level. This mathematical equation is valid over a wide range of diabetic conditions and could be widely used throughout the world at very little cost (and at considerable improvement) to the current technology in use for these purposes.

Ambulatory medical devices that provide therapy to a subject, such as blood glucose control, are disclosed. Disclosed systems and devices can transmit a request to modify blood glucose control therapy delivered to a subject. The request can be transmitted via a voice-activated control system, the ambulatory medicament pump can include a medicament reservoir, a pump controller, a wireless data interface, and/or other elements. The device can receive an indication that the request to modify therapy is approved and, in response to the indication that the request to modify the blood glucose control therapy is approved, instruct the pump controller to modify the blood glucose control therapy delivered to the subject.

Infusion devices and related medical devices, patient data management systems, and methods are provided for monitoring a physiological condition of a patient. An exemplary infusion device includes an actuation arrangement operable to deliver fluid to a user, a communications interface to receive measurement data indicative of a physiological condition of the user, a sensing arrangement to obtain contextual measurement data, and a control system coupled to the actuation arrangement, the communications interface and the sensing arrangement to determine a command for autonomously operating the actuation arrangement in a manner that is influenced by the measurement data and the contextual measurement data and autonomously operate the actuation arrangement in accordance with the command to deliver the fluid to the user.