Abstract: A modular external defibrillator system in embodiments of the teachings may include one or more of the following features: a base containing a defibrillator to deliver a defibrillation shock to a patient, (b) one or more pods each connectable to a patient via patient lead cables to collect at least one patient vital sign, the pods operable at a distance from the base, (c) a wireless communications link between the base and a selected one of the two or more pods to carry the at least one vital sign from the selected pod to the base, the selection being based on which pod is associated with the base.

Abstract: A plurality of co-operative and complementary software programs are implemented in a web-enabled high speed computer system to remotely monitor, manage and modify the operational and functional parameters of a plurality of implanted medical devices (IMDs). The system utilizes virtual electrophysiologist module (VEM), chronic monitoring module (CMM) and prescription program module (PPM) programs to effect specific therapeutic and diagnostic methods for managing the IMDs, remotely on a conditions and real-time basis. The modules enable remote and continuous monitoring, management and maintenance of the IMDs by identifying critical medical events, determining optimal clinical settings and upgrading performance parameters based on prescriptive data. The modules are implemented in a data center having high-speed computers operating in a web-enabled environment. The modules and the IMDs communicate through wireless communications system via a programmer or an interface medical unit (IMD).

Abstract: Techniques for routing event data from a field device, such as an external defibrillator, to a selected subset of a plurality of possible destinations are described. The event data may include physiological data of the patient, such as a 12-lead electrocardiogram (ECG). The destinations may be associated with one of a plurality of patient treatment centers, and may include, as examples, computing device, printers, displays, personal digital assistants, or web-accessible accounts. In some examples, a server maintains user-configurable information or rules for at least some of the destinations, and uses the information or rules for determining whether event data received from a field device is routed to the destination. In some examples, the server may also make the routing determination based on an analysis of event data, such as a determination as to whether the event data indicates that the patient is suspected to be experiencing an acute myocardial infarction.

Abstract: In general, the invention is directed to management of information from a plurality of emergency medical devices, such as automated external defibrillators, and associated docking stations. The medical devices and docking stations may communicate with one another and with a remote unit. The managed information includes information pertaining to authorized access and maintenance, inspection indications and inspection certifications. In general, an authorized user can access the emergency medical device without activating alarms that would accompany an emergency. The authorized user can further use the user input interface to enter an inspection certification, which records the inspection, the maintenance performed, the date the device is returned to service, and so forth.

Abstract: In general, the invention is directed to management of information from a plurality of emergency medical devices, such as automated external defibrillators, and associated docking stations. The medical devices and docking stations may communicate with one another and with a remote unit. The managed information includes information pertaining to authorized access and maintenance, inspection indications and inspection certifications. In general, an authorized user can access the emergency medical device without activating alarms that would accompany an emergency. The authorized user can further use the user input interface to enter an inspection certification, which records the inspection, the maintenance performed, the date the device is returned to service, and so forth.

Abstract: A modular external defibrillator system in embodiments of the teachings may include one or more of the following features: a base containing a defibrillator to deliver a defibrillation shock to a patient, (b) one or more pods each connectable to a patient via patient lead cables to collect at least one patient vital sign, the pods operable at a distance from the base, (c) a wireless communications link between the base and a selected one of the two or more pods to carry the at least one vital sign from the selected pod to the base, the selection being based on which pod is associated with the base.

Abstract: A plurality of co-operative and complementary software programs are implemented in a web-enabled high speed computer system to remotely monitor, manage and modify the operational and functional parameters of a plurality of implanted medical devices (IMDs). The system utilizes virtual electrophysiologist module (VEM), chronic monitoring module (CMM) and prescription program module (PPM) programs to effect specific therapeutic and diagnostic methods for managing the IMDs, remotely on a conditions and real-time basis. The modules enable remote and continuous monitoring, management and maintenance of the IMDs by identifying critical medical events, determining optimal clinical settings and upgrading performance parameters based on prescriptive data. The modules are implemented in a data center having high-speed computers operating in a web-enabled environment. The modules and the IMDs communicate through wireless communications system via a programmer or an interface medical unit (IMD).

Abstract: In general, the invention provides techniques for remotely controlling an external medical device with a remote device via a wireless communication session. The remote device sends one or more commands to the external medical device via the wireless communication session, and the external medical device carries out the commands. The commands may pertain to various functions such as changing a display, applying a therapy, configuring the therapy, initiating data transmission to a remote location and updating medical event information.

Abstract: Techniques are described for detecting removal of a medical device from a station and activating an alarm in response to the detected removal. More specifically, the station includes a detector that detects removal of the medical device and causes the alarm to activate upon detecting the removal. For example, the station may include an optical detector that receives an optical signal from a light transmitter on the medical device. When the optical detector does not receive a signal from the medical device, the optical detector sends a signal to activate the alarm. The optical detector may, for example, not receive an optical signal when the medical device is too far from the optical detector or oriented in an improper direction. The sensitivity of the detector may further be calibrated to allow different detection ranges to be defined for the station.

Abstract: A plurality of co-operative and complementary software programs are implemented in a web-enabled high speed computer system to remotely monitor, manage and modify the operational and functional parameters of a plurality of implanted medical devices (IMDs). The system utilizes virtual electrophysiologist module (VEM), chronic monitoring module (CMM) and prescription program module (PPM) programs to effect specific therapeutic and diagnostic methods for managing the IMDs, remotely on a conditions and real-time basis. The modules enable remote and continuous monitoring, management and maintenance of the IMDs by identifying critical medical events, determining optimal clinical settings and upgrading performance parameters based on prescriptive data. The modules are implemented in a data center having high-speed computers operating in a web-enabled environment. The modules and the IMDs communicate through wireless communications system via a programmer or an interface medical unit (IMD).

Abstract: A plurality of co-operative and complementary software programs are implemented in a web-enabled high speed computer system to remotely monitor, manage and modify the operational and functional parameters of a plurality of implanted medical devices (IMDs). The system utilizes virtual electrophysiologist module (VEM), chronic monitoring module (CMM) and prescription program module (PPM) programs to effect specific therapeutic and diagnostic methods for managing the IMDs, remotely on a conditions and real-time basis. The modules enable remote and continuous monitoring, management and maintenance of the IMDs by identifying critical medical events, determining optimal clinical settings and upgrading performance parameters based on prescriptive data. The modules are implemented in a data center having high-speed computers operating in a web-enabled environment. The modules and the IMDs communicate through wireless communications system via a programmer or an interface medical unit (IMD).

Abstract: A data communication system is provided which permits of communication between a deployed implantable medical device (IMD) and a computing resource capable of storing and distributing patient and device data. A deployed IMD may be polled by a programmer device external to the host patient, and data may be transmitted to the programmer by wireless communication. This data may be transmitted to a central computer for storage and distribution. The data may be distributed to business system computers affiliated or connected to the central computer, for example. The data may also be distributed to third parties for invoicing inventory, and supply consideration.