A system is disclosed. The system includes a reservoir for containing a fluidic medium, the reservoir including a front surface, a resilient cylindrical flexure portion connected to the front surface, the resilient cylindrical flexure portion comprising an accordion-like structure that is able to expand and contract to change an interior volume within the resilient cylindrical flexure portion, a central passageway within the resilient cylindrical flexure, and a collection chamber connected to the central passageway. Also, a system including a reservoir, a plunger head located within the reservoir, a plunger arm connected to the plunger head, a driving shaft connected to the plunger arm, and a motor connected to the driving shaft, the motor controllable to move the drive shaft in a first motion and a second motion so as to move the advance plunger head and retract the plunger head within the reservoir.

Systems and methods presented herein relate to a method of sharing therapy data of an ambulatory medical device with a computing system of a networked computing environment. The computing system may be identified using an authorized system list that includes an address of approved computing systems. Using an address of an approved computing system, a direct end-to-end data connection may be established via a wireless wide area network. A public key of the computing system may be received permitting the ambulatory medical device to encrypt data to be transmitted to the computing system. The ambulatory medical device can transmit the encrypted therapy data to the computing system over the direct end-to-end data connection.

Improved automatic chest compression systems which use constricting belts, repeatedly inflating bladders, or reciprocating pistons to compress the chest. A bladder is placed between the chest and the particular mechanism used to compress the chest during CPR. The bladder maximizes the effectiveness of chest compressions.

A system for delivery of a volume of infusible fluid. The system includes a controller configured to calculate a trajectory for delivering infusible fluid, the trajectory comprising at least one volume of fluid, and determine a schedule for delivering the at least one volume of fluid according to the trajectory, wherein the schedule comprising an interval and a volume of infusible fluid for delivery. The system also includes a volume sensor assembly for determining the at least one volume of fluid delivered, wherein the controller recalculates the trajectory based on the volume of fluid delivered.

A filling aid. The filling aid includes a needle housing portion including at least one tab having a starting position and a filling position, and a filling needle cradle including a filling needle, the filling needle cradle slidable connected to the needle housing portion and having a starting position and a filling position, wherein when the at least one tab on the needle housing moves from a starting position to a filling position, the filling needle cradle slides from a starting position to a filling position, and wherein when the at least one tab on the needle housing moves from a filling position to a starting position, the filling needle cradle slides from a filling position to a starting position.

A system for delivery of a volume of infusible fluid. The system includes a controller configured to calculate a trajectory for delivering infusible fluid, the trajectory comprising at least one volume of fluid, and determine a schedule for delivering the at least one volume of fluid according to the trajectory, wherein the schedule comprising an interval and a volume of infusible fluid for delivery. The system also includes a volume sensor assembly for determining the at least one volume of fluid delivered, wherein the controller recalculates the trajectory based on the volume of fluid delivered.

A variety of location-based and/or proximity-based features related to diabetes management systems can be used to improve maintenance compliance and/or to provide important information to PWD designated assistance entities (e.g., family, friends, givers, HCPs, emergency medicine providers) under certain conditions. In some cases, a user's location can be tracked or determined to trigger and/or time alerts about upcoming maintenance tasks in a way that will increase the likelihood that the PWD will immediately perform the designated maintenance task. In some cases, methods, devices, and systems provided herein can use proximity to non-paired mobile computing devices to deliver data to PWD designated assistance entities.

A device for monitoring adherence of a patient to a prescribed regimen is provided. The device has a pulmonary delivery device fluid, an adapter in communication with the delivery device and a dispenser in fluid communication with the adapter. A pressurized drug, contained in the pulmonary delivery device, can be delivered from the pulmonary delivery device to the patient through the adapter and the dispenser. A sensor is mounted to the adapter or the dispenser for detecting a temperature or pressure change caused by the movement of the drug from the pulmonary delivery device to the patient and generating a feedback signal based on the change. The feedback signal is further processed for generating a signal indicating a successful deliver of the drug to the patient.

A portable therapeutic platform for use in a therapeutic procedure including: (a) at least one compartment for holding at least one therapeutically effective item required to conduct the therapeutic procedure; and (b) at least one electronic communications device for receiving and transmitting information about an environment surrounding and including the platform. The use of the platform is conveniently managed by a system which transfers information about the environment surrounding and including the platform between the electronic communications device and a computer system including a processor which processes the information; and initiates a control response to the processed information. The platform and system are suitable for use to address a range of public health issues and as a countermeasure to biosecurity threats.

A wearable infusion pump assembly includes a reservoir for receiving an infusible fluid, and an external infusion set configured to deliver the infusible fluid to a user. A fluid delivery system is configured to deliver the infusible fluid from the reservoir to the external infusion set. The fluid delivery system includes a volume sensor assembly, and a pump assembly for extracting a quantity of infusible fluid from the reservoir and providing the quantity of infusible fluid to the volume sensor assembly. The volume sensor assembly is configured to determine the volume of at least a portion of the quantity of fluid. The fluid delivery system further includes a first valve assembly configured to selectively isolate the pump assembly from the reservoir, and a second valve assembly configured to selectively isolate the volume sensor assembly from the external infusion set.