The invention relates to an ablation device for delivery of microwave energy to a selected region of tissue, in particular for producing deep endocardial or epicardial ventricular lesions, such as for the treatment or prevention of arrhythmias.

The device includes a microwave radiation antenna electrically connectible via a microwave feedline to an electrical microwave system, the microwave antenna configured to generate a microwave field able to ablate tissue in said selected region of tissue, the antenna positioned within an antenna-receiving portion of an elongated catheter configured to allow fluid flow along the catheter to exit through one or more orifices in the catheter wall, the catheter provided with an electrical sensing system including one or more metal electrodes and being independent of the electrical microwave system, the device configured such that in use the electrical sensing system includes an electric circuit which incorporates an ionic conductivity bridge formed between said one or more metal electrodes and the fluid exiting said one or more orifices, the ionic conductivity bridge traversing said catheter antenna-receiving portion.

The present invention relates to the field of medical monitoring, and in particular non-contact monitoring and communication with other medical monitoring devices. Systems and methods are described for receiving a video signal of a medical monitoring device that is outputting a light signal, identifying the light signal emitted by the medical monitoring device from the video signal, decoding information from the light signal, and determining a communication from the decoded information related to a patient being monitored or the medical monitoring device itself.

A system includes a sensor applicator, a sensor control device arranged within the sensor applicator and including an electronics housing and a sensor extending from a bottom of the electronics housing, and a cap coupled to one of the sensor applicator and the sensor control device, wherein the cap is removable prior to deploying the sensor control device from the sensor applicator.

At least partial function of a human limb is restored by surgically removing at least a portion of an injured or diseased human limb from a surgical site of an individual and transplanting a selected muscle into the remaining biological body of the individual, followed by contacting the transplanted selected muscle, or an associated nerve, with an electrode, to thereby control a device, such as a prosthetic limb, linked to the electrode. Simulating proprioceptive sensory feedback from a device includes mechanically linking at least one pair of agonist and antagonist muscles, wherein a nerve innervates each muscle, and supporting each pair with a support, whereby contraction of the agonist muscle of each pair will cause extension of the paired antagonist muscle. An electrode is implanted in a muscle of each pair and electrically connected to a motor controller of the device, thereby simulating proprioceptive sensory feedback from the device.

Microelectromechanical system are disclosed that include at least one electrode, microelectrode or combination thereof, wherein the at least one electrode comprises a carbon material, a glassy carbon material or a combination thereof. Contemplated systems are suitable for μ-ECoG arrays. Additional microelectromechanical systems are disclosed that include at least one electrode, microelectrode or combination thereof, wherein the at least one electrode comprises a carbon material, a glassy carbon material or a combination thereof; at least one substrate, surface, layer or a combination thereof, wherein the at least one electrode, microelectrode or combination thereof is disposed on, coupled with or otherwise layered on the at least one substrate, surface, layer or a combination thereof; and at least one bump pad, wherein the at least one electrode, microelectrode or combination thereof is coupled with the at least one bump pad via at least one conductive metal. A method of making a microelectromechanical system includes patterning a polymer precursor, a carbon-containing material or a combination thereof onto a surface, a substrate, at least one layer or a combination thereof; and heating or pyrolysing the polymer precursor, a carbon-containing material or a combination thereof in order to form a glassy carbon material. Uses of microelectromechanical systems are also contemplated to measure at least one electrical property in a mammal or for electrocorticography.

A method of monitoring a subject via a photoplethysmography (PPG) sensor configured to detect and/or measure PPG information from the subject includes changing, via a processor, signal analysis frequency of the PPG sensor signals, optical wavelength emission of the PPG sensor, and/or PPG sensor interrogation power at predetermined times. Each predetermined time is associated with measuring at least one different biometric parameter from a plurality of biometric parameters.

A system and method for monitoring the state of an individual. The method includes providing a stimulus to the individual, measuring a response to the provided stimulus, comparing the measured response to an expected response, and diagnosing one or more aspects of disease in accordance with the result of the comparison between the measured response and the expected response. The stimulus may be a predetermined test sequence, such as a visually displayed predetermined sequence of images, or may include observation of the physical response of the individual while performing one or more predetermined activities. Stored images or video of the individual responding to one or more test sequences may be stored in a lossy or lossless state, and thus security and de-identification may be provided to stored data. This stored data may also be de-identified in a manner to allow for the answering of the greatest number of future questions.

A biomedical implant includes a wall enclosing at least a portion of the implant. The wall includes a first stratum and a second stratum conformal with the first stratum. An interlayer is provided between the first and the second strata, and includes a structure that produces capillary pressure in an infiltrating fluid in response to rupture of the first stratum or the second stratum resulting in entry of the infiltrating fluid into the interlayer. A detector is exposed to the interlayer and configured to detect a presence, if any, of the infiltrating fluid and output a detection state indicator. A communication circuit is communicatively coupled to the detector and configured to communicate the detection state indicator to a reader external to the patient.

The present invention relates to the field of medical monitoring, and in particular non-contact monitoring and communication with other medical monitoring devices. Systems and methods are described for receiving a video signal of a medical monitoring device that is outputting a light signal, identifying the light signal emitted by the medical monitoring device from the video signal, decoding information from the light signal, and determining a communication from the decoded information related to a patient being monitored or the medical monitoring device itself.

Example devices are disclosed herein that include a first elongated band coupled to a first housing to be located on a first side of a head of a subject and a second housing to be located near a second side of the head of the subject, the first elongated band comprising a first set of electrodes. The example device also includes a second elongated band coupled to the first housing and to the second housing, the second elongated band comprising a second set of electrodes. In addition, the device includes a third elongated band coupled to the first housing and to the second housing, the third elongated band comprising a third set of electrodes.