An acoustic dose meter is provided comprising a housing, and a cylindrical seat for staging a pressurized medicine canister. The housing includes at least one compartment for housing electronics and passageways for connecting electronics for power and data communication. A microprocessor including a transient memory containing machine instruction is also included. Additionally, a power source connected to the microprocessor, a power switch connected to the microprocessor and the power source for booting the microprocessor are added. At least one visual display device connected to the microprocessor for displaying available doses is provided. A first set of acoustic sensors connected to the microprocessor and adapted as acoustic sound generators and a second set of acoustic sensors connected to the microprocessor and adapted as acoustic soundwave recorders are implemented to detect and analyze frequencies enabling determining of dosing count availability.

Methods and systems for monitoring the status and usage of a metered dose inhaler (MDI) and communicating status, usage, and guidance information to a user of the MDI and to a mobile computing device are presented herein. An IMD includes a dosage dispense detection device, an accelerometer, and a visual transducer, an audio transducer, a haptic transducer, or any combination thereof. The dosage dispense detection device detects when a user applies a compressive force across the IMD. The accelerometer measures a shaking of the IMD by a user before self-administering a dose. The IMD determines whether the medicine is adequately shaken by the user, and if so, communicates an indication to the user that the pressurized canister of medicine is ready for dosage. In another aspect, the IMD communicates a sequence of indications that mark each transition of a dosage regimen plan to self-administer a dosage of medicine.

An on-person portable device and/or app that allows for constant location monitoring of dementia patients is disclosed. Such a device and/or app also includes automated communication of facial recognition of persons proximally near such a patient as well as possible generation of certain music in response to patient status and/or location. The patient is provided the device and/or app for handling or wearing, such as a phone or pair of glasses, in order to follow location through GPS monitoring, and a reactive program therein that automatically views another person and provides an identification thereof coupled with a voice modulator within an earpiece or like device for memory stimulation pertaining to loved ones or friends, and the like. The same program may also provide the music response to comments, movement, or any other external stimuli to the subject patient, again, to evoke a memory stimulus, as well.

Embodiments provide an oxygen supply device having multiple operational states including a first state and a second state. In the first state, the oxygen supply device is controllable to a local control instruction such that the oxygen supply device can be operated by a user physically located within a proximity of the oxygen supply device. In the second state, the oxygen supply device is only controllable to a remote-control instruction such that the oxygen supply device can be operated by a user remote to the oxygen supply device. For example, the user can be located in an office remote to a location of the oxygen supply device, which, for example, may be placed at a patient's home. In the second state, the user is enabled to control the oxygen supply device from a device associated with the user in the remote location.

An aerosol delivery device is provided that includes at least one housing structured to retain an aerosol precursor composition. The device includes an atomizer, and a microprocessor configured to operate in an active mode in which the control body is configured to control the atomizer to activate and produce an aerosol from the aerosol precursor composition. And the device includes a heart rate monitor including a plurality of biopotential electrodes affixed to the housing and configured to obtain biopotential measurements from a user, and including signal conditioning circuitry configured to produce an electrocardiogram signal from the biopotential measurements. The microprocessor is coupled to the signal conditioning circuitry and further configured to control operation of at least one functional element of the aerosol delivery device based on the electrocardiogram signal or a heart rate of the user calculated therefrom.

Blood glucose control systems are disclosed. A blood glucose control system can receive a glucose level signal from a glucose sensor operatively coupled to a subject. The system can decode encoded data of the glucose level signal to obtain the glucose level of the subject and the indication of the glucose trend. The system can automatically calculate the dose control signal using a control algorithm configured to calculate regular correction boluses of glucose control agent in response to at least the glucose level of the subject. The system can select a dose control signal encoding profile from a plurality of dose control signal encoding profiles and, based on the dose control signal encoding profile, encode the dose control signal such that the pump controller can read the dose control signal. The system can transmit an encoded dose control signal to the pump controller.

In various embodiments, a caregiver module is provided for use with a patient medical device, including a sensor to obtain a sensor signal related to the use of the patient medical device; an analog-to-digital converter to convert the sensor signal to corresponding sensor data; and a controller to transmit the sensor data to a wearable device, wherein the sensor data is transmitted in the same form as created by the converter. Various embodiments provide a wearable device for processing sensor data received from the caregiver module, including: memory storing processing instructions for interpreting sensor data of multiple types; and a processor to: receive configuration information associated with the caregiver module, receive sensor data of a first type from the caregiver module, and execute the processing instructions based on the configuration information, wherein the configuration information alters the operation of the processing instructions to interpret sensor data of the first type.

Methods for programming an implantable drug delivery device using a mobile computing device that include establishing a connection with a telemetry unit configured for wireless communication with the implantable drug delivery device, displaying user-selectable drug delivery settings for the implantable drug delivery device, receiving at least one selection of a drug delivery setting, translating the received selection into a signal format readable by the telemetry unit, and sending the translated signal to the telemetry unit to program the implantable drug delivery device. Further embodiments include telemetry units for communication with an implantable drug delivery device, and patient programmers and a method for patient modification to a programmed drug delivery regimen.

A system and method to configure a rule set used in connection with a medical monitoring system for monitoring patients and patient care equipment, especially medication delivery pumps, based on a variety of conditions and parameters associated with monitored biometric information and equipment information and for providing user-defined responses to those conditions and parameters.

Provided is a wearable, self-contained drug infusion or medical device capable of communicating with a host controller or other external devices via a personal area network (PAN). The medical device utilizes a PAN transceiver for communication with other devices in contact with a user's body, such as a physiological sensor or host controller, by propagating a current across the user's body via capacitive coupling. The wearable nature of the medical device and the low power requirements of the PAN communication system enable the medical device to utilize alternative energy harvesting techniques for powering the device. The medical device preferably utilizes thermal, kinetic and other energy harvesting techniques for capturing energy from the user and the environment during normal use of the medical device. A system power distribution unit is provided for managing the harvested energy and selectively supplying power to the medical device during system operation.