Abstract: A telemetry port for providing an open space in which an antenna may transmit and receive signals free from interference from the metal shell of an implantable medical device, the telemetry port includes a housing defining a void space for receiving an antenna. The void space is configured to provide the antenna with sufficient space such that the antenna does not contact the housing. The housing further includes a periphery positioned along a bottom edge capable of being integrated to an implantable medical device, and forming a hermetic seal with the implantable medical device.

Abstract: Methods and systems of patient treatment are disclosed. The methods and systems include use of medical device informatics to modify and validate therapies and drugs used in those therapies. In certain embodiments, a medical device, such as a medical infusion pump, interfaces with a server to administer the patient treatments. In one aspect, a method of synchronizing clocks between a medical device and a medical device server is disclosed. The method includes maintaining a server time value on a medical device server communicatively connected to a medical device, and transmitting the server time value from the medical device server to the medical device, the medical device maintaining a device time value. The method further includes replacing the device time value with the server time value.

Abstract: Methods and systems of patient treatment are disclosed. The methods and systems include use of medical device informatics to modify and validate therapies and drugs used in those therapies. In certain embodiments, a medical device, such as a medical infusion pump, interfaces with a server to administer the patient treatments. In one aspect, a method of deploying information to a medical device is disclosed. The method includes storing information in a data package on a server, the information intended to be delivered to a medical device. The method also includes receiving a message from the medical device, and in response to receiving the message, indicating to the medical device that information intended for the medical device resides on the server. The method further includes receiving a request for the information, and upon receiving the request, delivering the data package to the medical device.

Abstract: In a programmer for an implantable medical device, a method for operating and controlling a implantable medical device, and in a computer software product, a graphical representation of a quantity influenced by the operation of the medical device is displayed, and parameters relating to the control of the device are associated with portions of the graphical representation. When an operator selects and alters the shape of the displayed graphical representation to illustrate a desired operational effect of the medical device on the quantity, a value associated with the altered shape is automatically modified and communicated to the implanted medical device. The operator thus is able to select parameters on the basis of the intended effect, rather than setting parameter values and then observing the effect.

Abstract: An implantable medical device communication unit bi-directionally communicates with an external device. The communication unit includes a receiver arranged to receive communication signals, having a signal strength, from the external device. The receiver includes a discriminator that is provided with a discriminator threshold such that the receiver means only accepts received signals having a signal strength higher than said discriminator threshold to activate the medical device. The discriminator threshold is adapted to be adjusted in response to control signals from a control unit in the medical device.

Abstract: A device for filtering signals emitted by a medical device, principally an active implanted medical device. The device (26) receives an input that is a signal delivered by a circuit (16-24) that receives signals emitted by a medical device (10) in the form of a magnetic induction, in which the medical device has a metallic housing or case. A compensation stage (42) also is provided, having in the frequency domain a transfer function in the form: ##EQU1## where f.sub.c is a chosen parameter according to the geometry and the material of the metallic case of the medical device (10), and where j=.sqroot.-1. The device is useful with medical devices that emit sequences of messages formed by symbols belonging to an alphabet of n symbols (n.gtoreq.2), the compensation stage being able to reduce the rate of inter-symbol interference of collected signals that are applied to it.

Abstract: An implantable medical device comprises a hermetically sealed housing having a housing wall with an interior surface, and an ultrasonic acoustic transducer, the transducer comprising one or more piezoelectric discs fixed to the interior surface of the housing wall, such that the housing wall acts as a diaphragm in response to induced movement by the one or more piezoelectric material discs.

Abstract: An implantable medical device comprises a hermetically sealed housing having a housing wall with an interior surface, and an ultrasonic acoustic transducer, the transducer comprising one or more piezoelectric discs fixed to the interior surface of the housing wall, such that the housing wall acts as a diaphragm in response to induced movement by the one or more piezoelectric material discs.

Abstract: An implantable medical device has a housing having a first housing surface side, a second housing surface side opposing the first housing surface side, and an intermediate surface side extending between the first and second housing surface sides. The implantable medical device has an antenna device arranged at the first housing surface side, continuing at the intermediate surface side and further at the second housing surface side. Improved radiation characteristics are obtained in a desired direction.

Abstract: An implantable medical device communication unit bi-directionally communicates with an external device. The communication unit includes a receiver arranged to receive communication signals, having a signal strength, from the external device. The receiver includes a discriminator that is provided with a discriminator threshold such that the receiver means only accepts received signals having a signal strength higher than said discriminator threshold to activate the medical device. The discriminator threshold is adapted to be adjusted in response to control signals from a control unit in the medical device.

Abstract: An implantable medical device comprises a hermetically sealed housing having a housing wall with an interior surface, and an ultrasonic acoustic transducer, the transducer comprising one or more piezoelectric discs fixed to the interior surface of the housing wall, such that the housing wall acts as a diaphragm in response to induced movement by the one or more piezoelectric material discs.

Abstract: Methods and apparatus are provided for electrically isolating an ambulatory medical device for infusing treatment materials into a patient when the medical device is connected to a peripheral device via an active communication cable. In one embodiment, the ambulatory medical device include first circuitry controlling infusion of a medicament to the patient by a fluid conduit connectable to the patient and second circuitry controlling communications when an active communication cable is connected to the medical device. The first and second circuitry are electrically isolated using a pair of first and second isolation transceivers, where the first pair of isolation transceivers communicate a control signal and the second pair of isolation transceivers are giant magneto-resistive (GMR) transceivers that communicate at least one data signal.

Abstract: An implantable medical device comprises a hermetically sealed housing having at least one hermetic electrical feed through and an acoustic lead having a proximal end connected to the electrical feed through. One or more acoustic transducers are carried in a distal portion of the acoustic lead and configured for converting energy between electrical energy and acoustic energy, wherein electronics for driving the one or more transducers are carried in the housing.

Abstract: In a system and method for radio communication between an implantable medical device (IMD) and an external base unit, respectively including transceivers for communication therebetween, the external base unit, according to a predetermined criterion, sends a sleep message to the IMD transceiver, requesting the IMD transceiver to switch power-consuming circuitry in the IMD to a sleep, power-down mode of operation for a predetermined sleep time period.

Abstract: An active implantable medical device having an RF telemetry circuit. The device is in particular a stimulation, resynchronization, defibrillation and/or cardioversion device. It includes a principal circuit, an RF telemetry auxiliary circuit and a supply battery for the principal and auxiliary circuits. It is envisaged to have between the supply battery and the auxiliary circuit a regulating circuit including an accumulator of electric power coupled with the auxiliary circuit to deliver a current ready to feed the auxiliary circuit, and a load circuit coupled with the supply battery to maintain the accumulator on a predetermined level of load.

Abstract: An implantable medical device has an electronic circuit and a telemetry circuit both connected to a common ground, and at least one RF telemetry antenna that is formed by a number of parts of the implantable device that are capable of functioning as an antenna. When implanted, these parts are in contact with tissue. For voltage protection, the RF antenna circuit is connected to the parts of the RF telemetry antenna via at least one capacitor. The capacitor is dimensioned to withstand a voltage amplitude of a pulse that would be capable of modifying the state of, or destroying, any component in the RF telemetry circuit or the electronic circuit.

Abstract: An implantable medical device has an electronic circuit and a telemetry circuit both connected to a common ground, and at least one RF telemetry antenna that is formed by a number of parts of the implantable device that are capable of functioning as an antenna. When implanted, these parts are in contact with tissue. For voltage protection, the RF antenna circuit is connected to the parts of the RF telemetry antenna via at least one capacitor. The capacitor is dimensioned to withstand a voltage amplitude of a pulse that would be capable of modifying the state of, or destroying, any component in the RF telemetry circuit or the electronic circuit.

Abstract: Apparatus and associated methods relate to a Self-Validating System (SVS) which includes an Electronic Self-Validating Module (ESVM) that may be employed within a medical device, operable to receive and to transmit wireless transmissions to and from a personal electronic mobile device, the mobile device executing a Self-Validating Medical Device Remote Control (SVMDRC) application, also known as the mobile app, operable to control the ESVM, the mobile device and the ESVM further executing a pre-determined sequence of instructions at a pre-determined frequency, operable to perform a set of safety (validation) checks on the mobile device, and the ESVM. In an illustrative example, changes (updates) to the mobile device's operating system, the app, or the hardware on the mobile device may be detected by the mobile device, and may advantageously re-validate the mobile device automatically.

Abstract: Embodiments of the present invention are directed to apparatus and methods of minimizing current drain of an implantable medical device during wireless communication with the device, thereby reducing battery depletion of the device. In one embodiment, the implantable medical device comprises a wireless receiver configured to communicate wirelessly with an external transmitter of an external device via a plurality of communication channels each having a different frequency within a frequency band. The wireless receiver comprises a wideband receiver circuit configured to detect a signal from any of the plurality of communication channels at the different frequencies within the frequency band simultaneously.

Abstract: An apparatus comprises a communication channel comprising a plurality of disparate sequential communication links configured to facilitate bi-direction communication between an implantable medical device (IMD) and a programmer. A transceiver is configured to communicate with the programmer via a first communication link of the plurality of disparate communication links. A telemetry device is configured to communicate with the IMD via a second communication link of the plurality of disparate communication links. A third communication link communicatively couples the transceiver and the telemetry device. A power source is coupled to the transceiver and to the telemetry apparatus. An operational status of at least the first and second communication links can be individually determined in real-time.