The present invention provides materials and methods for forming an interface between an appliance and living tissue using a foamed elastomeric material which contacts the tissue or similar surfaces. The elastomeric material is in the form of a durable and washable material that when applied to living tissue or similar surfaces displaces and flows in to non-conforming areas creating an air and/or water tight seal that substantially returns to an original shape when removed from the contact surface. The appliance may also include structural elements designed to optimize comfort, compliance and seal achieved through minimizing the pressure variation along the contact surface of the therapy device.

A device (100) and method for adhering by suction to a target surface (200). The device has a substrate (20) with a contact surface (20a) for contacting the device (100) to the target surface (200). A plurality of pocket (10) are formed by respective pocket surfaces (10a) concavely extending into the contact surface (20a). The pockets (10) have an open side (10b) facing and being closed off by the target surface (200). A flexible membrane (15) forms at least part of the pocket surface (10a). An actuator (40) is configured to actuate the flexible membrane (15). A one-way valve (30) through the pocket surface (10a) is configured to direct a contents of the pocket (10) via the one-way valve (30) to an environment (300).

A multipart, non-uniform patient contact interface and method of use are disclosed.

This disclosure provides isolation for a medical amplifier by providing a low impedance path for noise across an isolation barrier. The low impedance path can include a capacitive coupling between a patient ground, which is isolated from control circuitry, and a functional ground of an isolation system that is isolated from earth ground. The low impedance path can draw noise current from an input of an amplifier of patient circuitry.

A wireless Electrocardiogram (ECG) device for wirelessly capturing heart activity of a patient. The device includes wireless suction electrodes for placement on the skin of the patient, the electrodes are configured to wirelessly transfer the recorded ECG activity in real time to the device, a monitor of the device displays the ECG data, and a wireless transceiver of the devices enables the device to transmit the ECG data to one or more remote devices. The device includes an amplifier for amplification and noise reduction, a signal processing unit to transform analog signals into digital data, a software to interpret data and provide recommendations. The device includes a drawer for storing the electrodes and includes UV disinfecting light for sanitizing the electrodes.

A wireless Electrocardiogram (ECG) device for wirelessly capturing heart activity of a patient. The device includes wireless suction electrodes for placement on the skin of the patient, the electrodes are configured to wirelessly transfer the recorded ECG activity in real time to the device, a monitor of the device displays the ECG data, and a wireless transceiver of the devices enables the device to transmit the ECG data to one or more remote devices. The device includes an amplifier for amplification and noise reduction, a signal processing unit to transform analog signals into digital data, a software to interpret data and provide recommendations. The device includes a drawer for storing the electrodes and includes UV disinfecting light for sanitizing the electrodes.

Medical devices are described for performing mapping, ablating, and/or pacing procedures on one or more layers of the cardiac wall via an epicardial approach in a minimally invasive (e.g., orthoscopic) surgical procedure. One of the medical devices described includes a main support member and one or more secondary support members extending outwardly from the main support member having electrodes configured to receive electrical impulses. The secondary support member may include a support pad configured to be removably attached to a corresponding area of the epicardium for holding the medical device in place during a procedure, such as through application of vacuum pressure via a containment dome provided on each secondary support member. Further, an ablating electrode may be slidably disposed along the main support member for transmitting energy to a target site proximate the electrode. Associated methods are also described.

A device for impedance measurements on body segments. Outputs of a current source are connected to inputs of current changeover switches. Each current changeover switch has outputs that are interconnectable with the input of the respective current changeover switch. The outputs of the current changeover switches are connected to electric feed lines of current electrodes. Measuring electrodes detect voltage signals, which are used with the current supplied by the current source for the impedance measurements of the body segments. Switching devices are incorporated into the electric feed lines near the current electrodes. By switching the current changeover switches and switching devices, the device respectively connects only two current electrodes to the current source and disconnects all other current electrodes from the electric feed line by switching the switching device and the electric feed line from the current source by switching the current changeover switches.

This disclosure provides isolation for a medical amplifier by providing a low impedance path for noise across an isolation barrier. The low impedance path can include a capacitive coupling between a patient ground, which is isolated from control circuitry, and a functional ground of an isolation system that is isolated from earth ground. The low impedance path can draw noise current from an input of an amplifier of patient circuitry.

Medical devices are described for performing mapping, ablating, and/or pacing procedures on one or more layers of the cardiac wall via an epicardial approach in a minimally invasive (e.g., orthoscopic) surgical procedure. One of the medical devices described includes a main support member and one or more secondary support members extending outwardly from the main support member having electrodes configured to receive electrical impulses. The secondary support member may include a support pad configured to be removably attached to a corresponding area of the epicardium for holding the medical device in place during a procedure, such as through application of vacuum pressure via a containment dome provided on each secondary support member. Further, an ablating electrode may be slidably disposed along the main support member for transmitting energy to a target site proximate the electrode. Associated methods are also described.