Some embodiments of a system or method for treating heart tissue can include a control system and catheter device operated in a manner to intermittently occlude a heart vessel for controlled periods of time that provide redistribution of blood flow. In particular embodiments, the system and methods may be configured to monitor at least one input signal detected at a coronary sinus and thereby execute a process for determining a satisfactory time period for the occlusion of the coronary sinus. In further embodiments, after the occlusion of the coronary sinus is released, the control system can be configured to select the duration of the release phase before the starting the next occlusion cycle.

A medical device comprises a control system, processing modules, and a wire bundle connecting the control system to the processing modules, the wire bundle comprising control lines and data lines. Each processing module is coupled to a respective set of sensors arranged to interface with a biological tissue site, the sensors being configured to capture analog physiological signals generated from the biological tissue site. The control system is configured to generate a control signal on the control lines to initiate a data collection cycle by the processing modules. In response to the control signal, each processing module is configured to perform a respective data collection process which comprises (i) capturing and processing an analog physiological signal on each enabled sensor to generate a data sample for each analog physiological signal captured on each enabled sensor, and (ii) outputting data samples to the control system on the data lines.

A method of processing cardiac ultrasound data for determining information about a mechanical wave in the heart. The method comprises receiving data representative of a time series of three-dimensional data frames, generated from ultrasound signals from a human or animal heart, each frame comprising a set of voxels, each voxel value representing an acceleration component of a respective location in the heart at a common time. The method also comprises identifying, for each voxel, a frame of the series in which the voxel value is at a maximum. A three-dimensional time-propagation data set is generated by assigning each voxel a value representative of the time of the respective frame in the time series for which the corresponding voxel is at a maximum. The method then comprises generating data representative of a three-dimensional velocity vector field by calculating time derivatives from the three-dimensional time-propagation data set.

Systems and methods are described herein for evaluation and configuration cardiac therapy. The systems and methods may monitor electrical activity using a plurality of external electrodes and may utilize multiple-electrode cardiac metrics such as electrical heterogeneity information, single-electrode cardiac metrics, and vectorcardiographic metrics to determine and select one or more paced settings from a plurality of different paced settings.

A first responder dispatch system is disclosed comprising a sensing wearable configured to be worn by a first responder. The sensing wearable can comprise a wrist-worn electronic device. The sensing wearable can comprise a plurality of biometric sensors configured to measure a plurality of vital signs of the first responder. The system can comprise a server programmed to receive biometric data concerning a plurality of vital signs of the first responder measured by the sensing wearable. The server can also transmit alerts to a plurality of dispatch client devices over a plurality of secured real-time bidirectional connections concerning a status of the first responder. At least one dispatch client device can transmit a response to the server and the server can, in turn, transmit additional biometric data concerning the first responder to the dispatch client device.

Methods of treating a valvular heart disease are provided. Methods for treating valvular heard disease include administering to a subject a therapeutically effective amount of at least one hedgehog pathway inhibitor. Also provided are methods for reducing fibrosis in a subject, which comprise administering to the subject a therapeutically effective amount of at least one hedgehog pathway inhibitor.

Methods of treating a valvular heart disease are provided. Methods for treating valvular heard disease include administering to a subject a therapeutically effective amount of at least one hedgehog pathway inhibitor. Also provided are methods for reducing fibrosis in a subject, which comprise administering to the subject a therapeutically effective amount of at least one hedgehog pathway inhibitor.

Disclosed apparatuses and methods apply electric fields deep in a body by selectively actuating multiple magnetic modules about the body sequentially in time. The electric field induced in regions of the body from such actuations may have a different frequency, depending on the depth of the region.

A stimulation system may include a sensor configured to detect a physiological signal of a user, the physiological signal having a biomarker therein associated with a disorder of the user; a stimulator configured to deliver electrical stimulation to the user; and a hub device configured to receive the physiological signal from the sensor and to output a control signal to the stimulator. The control signal may cause the stimulator to deliver electrical stimulation to the user according to a stimulation protocol, the stimulation protocol treating the disorder. The hub device may be configured to output the control signal based on the biomarker of the received physiological signal. The hub device may be configured to generate another control signal for treating another disorder based on a biomarker not included in the physiological signal received from the sensor.

A sensor apparatus configured to detect at least one physiological parameter of a subject includes a sensor that detects at least one physiological parameter of the subject as sensor data. An energy harvesting circuit includes a plurality of energy harvesting devices configured to harvest ambient energy from an environment of the subject. The energy harvesting devices generate power at a plurality of voltage potential levels from ambient energy. A conditioning circuit is configured to adjust the plurality of voltage potential levels to a bus voltage supplied to a supply bus. A controller receives operating power via the supply bus and controls the activation of the sensor and the wireless communication circuit.