The present invention provides an adjustable organizer for cords or electrical leads. Advantageously, the position of the organizer can be adjusted without having to disassemble the organizer from the cords or electrical leads and with only one hand. The organizer can remain attached to the cords or electrical leads for the lifetime of the cords or electrical leads. The organizer can be cleaned or sterilized using the techniques that are suitable for cleaning or sterilizing the attached cords or electrical leads.

The present invention provides an adjustable organizer for cords or electrical leads. Advantageously, the position of the organizer can be adjusted without having to disassemble the organizer from the cords or electrical leads and with only one hand. The organizer can remain attached to the cords or electrical leads for the lifetime of the cords or electrical leads. The organizer can be cleaned or sterilized using the techniques that are suitable for cleaning or sterilizing the attached cords or electrical leads.

Disclosed herein is a catheter for delivering an implantable medical lead to an implantation site near an ostium leading to a proximal region of a coronary sinus. The catheter includes a distal end, a proximal end opposite the distal end, a tubular body extending between the distal and proximal ends, an atraumatic fixation structure defining a distal termination of the distal end, and a lead receiving lumen. The atraumatic fixation structure is configured to enter the ostium and passively pivotally anchor with the proximal region of the coronary sinus. The lead receiving lumen extends along the tubular body from the proximal end to an opening defined in a side of the tubular body near the distal end and proximal the atraumatic fixation structure.

The present disclosure relates to the field of electronic engineering. The present disclosure envisages a multifunction modular strap that integrates multiple health monitoring devices. The multifunction modular strap comprises a health sensing module, an activity tracking module, a signal conditioning unit, a processing unit, a notification module, and a communication module. The health sensing module has a plurality of health sensors configured to sense a plurality of health parameters associated with a user. The activity tracking module comprises a pedometer, a sleep detection module, and a gesture detection module. The signal conditioning unit co-operates with the health sensing module and the activity tracking module. The processing unit co-operates with the signal conditioning unit, the health sensing module and the activity tracking module. The notification module co-operates with the processing unit and notifies the user. The communication module receives at least one communication signal from the processor and enables bi-directional communication with communicatively coupled device.

Systems and methods for cardiac pacing during a procedure are disclosed and may include an external pulse generator (EPG) for connecting to a lead. A remote-control module (RCM) wirelessly connected to the EPG may include user inputs to control the EPG. A central processing unit (CPU) with a memory unit for storing code and a processor for executing the code may be included where the CPU is connected to the EPG and RCM. The code may control the EPG in response to user input from the RCM. The CPU may be disposed in the EPG or the RCM, or an interface module (IM) configured to communicate between an otherwise conventional EPG and the RCM. The executable code may perform a continuity test (CT) routine, a capture check (CC) routine, rapid pacing (RP) routine, and/or a back-up pacing (BP) routine, in response to user input from the RCM.

Systems and methods for cardiac pacing during a procedure are disclosed and may include an external pulse generator (EPG) for connecting to a lead. A remote-control module (RCM) wirelessly connected to the EPG may include user inputs to control the EPG. A central processing unit (CPU) with a memory unit for storing code and a processor for executing the code may be included where the CPU is connected to the EPG and RCM. The code may control the EPG in response to user input from the RCM. The CPU may be disposed in the EPG or the RCM, or an interface module (IM) configured to communicate between an otherwise conventional EPG and the RCM. The executable code may perform a continuity test (CT) routine, a capture check (CC) routine, rapid pacing (RP) routine, and/or a back-up pacing (BP) routine, in response to user input from the RCM.

A modular patient monitor has a docking station configured to accept a handheld monitor. The docking station has standalone patient monitoring functionality with respect to a first set of parameters. At least some of the first parameter set are displayed simultaneously on a full-sized screen integrated with the docking station. The handheld monitor also has standalone patient monitoring functionality with respect to a second set of parameters. At least some of the second set of parameters are displayed simultaneously on a handheld-sized screen integrated with the handheld monitor. The docking station has a port configured to accept the handheld monitor. While the handheld monitor is docket in the port, the docking station functionally combines the first set of parameters and the second set of parameters, and at least some of the combined first and second sets of parameters are displayed simultaneously on the full-sized screen.

A modular patient monitor has a docking station configured to accept a handheld monitor. The docking station has standalone patient monitoring functionality with respect to a first set of parameters. At least some of the first parameter set are displayed simultaneously on a full-sized screen integrated with the docking station. The handheld monitor also has standalone patient monitoring functionality with respect to a second set of parameters. At least some of the second set of parameters are displayed simultaneously on a handheld-sized screen integrated with the handheld monitor. The docking station has a port configured to accept the handheld monitor. While the handheld monitor is docket in the port, the docking station functionally combines the first set of parameters and the second set of parameters, and at least some of the combined first and second sets of parameters are displayed simultaneously on the full-sized screen.

Embodiments are directed to systems and methods for determining a metric associated with electrode-skin contact quality. A reference signal is applied to a set of electrodes. The quality of contact between each electrode or subset of electrodes and the skin determines the amplitude of a contact signal that may be measured by processing circuitry of an electronic device. The contact signals for each of the electrodes, and any biological and/or other signals that may be acquired by the electrodes, are measured sequentially in a series of sampling windows. The measured signals associated with each sampling window are digitized and sequentially stored. A composite signal is generated from the sequentially stored samples and demodulated, to provide an output signal. The output signal may be analyzed to determine a metric associated with the contact quality between the set of electrodes and the skin of the user.

Embodiments are directed to systems and methods for determining a metric associated with electrode-skin contact quality. A reference signal is applied to a set of electrodes. The quality of contact between each electrode or subset of electrodes and the skin determines the amplitude of a contact signal that may be measured by processing circuitry of an electronic device. The contact signals for each of the electrodes, and any biological and/or other signals that may be acquired by the electrodes, are measured sequentially in a series of sampling windows. The measured signals associated with each sampling window are digitized and sequentially stored. A composite signal is generated from the sequentially stored samples and demodulated, to provide an output signal. The output signal may be analyzed to determine a metric associated with the contact quality between the set of electrodes and the skin of the user.