The invention relates to a passive pressure sensor (501) for being introduced into the circulatory system of a human being and for being wirelessly read out by an outside reading system. The pressure sensor comprises a casing (502) with a diffusion blocking layer for maintaining a predetermined pressure within the casing and a magneto-mechanical oscillator with a magnetic object (508) providing a permanent magnetic moment. The magneto-mechanical oscillator transduces an external magnetic or electromagnetic excitation field into a mechanical oscillation of the magnetic object, wherein at least a part of the casing is flexible for allowing to transduce external pressure changes into changes of the mechanical oscillation of the magnetic object. The pressure sensor can be very small and nevertheless provide high quality pressure sensing.

A sensor implant device includes a shunt structure comprising a flow path conduit and a plurality of arms configured to secure the shunt structure to a tissue wall, and a pressure sensor device attached to one of the plurality of arms of the shunt structure. The pressure sensor device comprises one or more sensor elements, an antenna, control circuitry electrically coupled to the one or more sensor elements and the antenna, and a housing that houses the control circuitry.

Systems comprising expandable devices for making wireless measurements at a target tissue of a patient are disclosed herein. Configurations of expandable devices addressing potential negative consequences of mechanical loading of sensors and circuitry of the expandable devices during delivery and expansion at a target location are disclosed. Systems can comprise an external device configured to provide electrical power to the expandable device and to communicate data wirelessly with the expandable device.

The present technology relates to intracardiac pressure monitoring devices, and associated systems and methods. In some embodiments, the present technology includes an intracardiac pressure monitoring device including a pressure sensor configured to measure pressure within a heart chamber of a patient. The device further includes a barrier structure operably coupled to the pressure sensor and configured to prevent tissue overgrowth over the pressure sensor.

Auxiliary components for medical devices, and more specifically, sensing constructs that may be added to a medical device such as an implantable medical device to provide the medical device with sensing functionality. The auxiliary component is not a part of the medical device, but rather is associated with an existing medical device in a secure manner, and provides information about the medical device and/or the environment around the medical device when the device is implanted in a patient, and then transmits that information to a location outside of the patient for evaluation. Delivery systems for delivering the auxiliary components.

A prosthetic heart valve can comprise a stent frame radially movable between a contracted configuration and a maximum expanded configuration. The stent assembly can comprise a plurality of longitudinally extending jack strut assemblies, wherein each jack strut assembly comprises a proximal jack strut comprising a distal surface, a distal jack strut comprising a proximal surface, and a jack screw connecting the proximal jack strut and the distal jack strut. The proximal surface of each distal jack strut does not contact the distal surface of each respective proximal jack strut when the stent assembly is in the contracted configuration. The proximal surface of each distal jack strut contacts the distal surface of each respective proximal jack strut when the stent assembly is in the maximum expanded configuration.

A computer system is disclosed comprising a processor arrangement communicatively coupled to a data storage arrangement storing a digital model of a section of a lumen system of a patient; and a communication module communicatively coupled to said processor arrangement and arranged to receive sensor data pertaining to an internal parameter of said lumen system from a sensor within said section of the lumen system. The processor arrangement is arranged to receive said sensor data from the communication module; retrieve said digital model from the data storage arrangement; simulate an actual physical condition of said lumen system by developing said digital model based on the received sensor data; and generate an output relating to said simulated actual physical condition for updating an electronic device. Also disclosed is a method of monitoring a patient with such a computer system, a computer program product for implementing such a method and a patient monitoring system.

A locator assembly (100) for determining a location of an arrhythmogenic foci (632) in or near a heart (101). The locator assembly (100) includes a device body (112) and a plurality of electrodes (102). The plurality of electrodes (102) receive electrical signals from the heart (101) to determine the location of the arrhythmogenic foci (632). The plurality of electrodes (102) can be coupled to the device body (112). At least two of the plurality of electrodes (102) can positioned circumferentially about the device body (112). The plurality of electrodes (102) can be positionable so that the plurality of electrodes (102) are in electrical communication with the heart (101).

A method for determining a location of an arrhythmogenic foci (632) in or near a heart (101) includes the steps of positioning a locator assembly (100) within the heart (101), the locator assembly (100) including a plurality of electrodes (102) that receive electrical signals from the heart (101), generating a first signal array (733) from the electrical signals received by the plurality of electrodes (102) to determine an actual location of the arrhythmogenic foci (632), artificially stimulating the heart (101) based on the actual location determined by the first signal array (733) to generate a second signal array (733), and confirming the actual location of the arrhythmogenic foci (632) by comparing the first signal array (733) with the second signal array (735). In some embodiments, the locator assembly (100) includes a plurality of bipolar electrodes (102).

Devices, methods and systems for transmitting signals through a device located in a blood vessel of an animal for stimulating and/or sensing activity of media proximal to the devices. The media can include tissue and/or fluid. A method of controlling an apparatus in communication with a brain machine interface. The method can include measuring a first neural activity in a first neural area and measuring a second neural activity in a second neural area. The first neural activity can be associated with a first intent. The method can include creating and delivering, via the processor, one or more first control signals to the apparatus upon comparing the second neural activity with the first neural activity, and confirming, based on this comparison, that the second neural activity is associated with the first intent.