A catheter calibration system includes a calibration chamber, a receiver and a processor. The calibration chamber is configured to generate a calibration magnetic field that oscillates at a first frequency. The calibration chamber includes a cavity for inserting a distal end of a catheter having one or more magnetic-field sensors. The receiver is configured to be connected to the catheter, to receive from the catheter one or more signals, which are generated by the one or more magnetic-field sensors in response to the calibration magnetic field, and to convert the one or more signals into one or more respective intermediate frequency (IF) signals having a second frequency that is lower than the first frequency. The processor is configured to receive the one or more IF signals from the receiver and to calculate catheter navigation calibration data from the one or more IF signals.

A system and method for assisting medical professionals while controlling catheters/probes is provided. The device generally comprises an attachment device, top piece, bottom piece, hinge, locking element, and friction producing pads. A medical professional may manipulate the device in a way that allows for better control of a catheter/probe in at least one direction. The device is configured to be contained within a sterile packaging until ready for use. In some embodiments, the device may be attached to a patient's drape during a procedure so that the catheter/probe may be properly aligned with a sheath used during a procedure.

Systems and methods for delivering a drug or other therapy over an extended period of time (e.g., several hours, days, weeks, months, years, and so forth) are disclosed herein, as are systems and methods for monitoring various parameters associated with the treatment of a patient. Systems and methods are also disclosed herein that generally involve CED devices with various features for reducing or preventing backflow.

The present application relates to a cannula, comprising a cannula body with a cannula tube and a body part attached to the proximal end of the cannula tube, a control clip having a mounting body with at least one control element, said control clip being attachable laterally on the body part to form a first configuration. In addition, the present applications relates to a cannula body, a contact clip and a control clip of a cannula.

A system for facilitating instrument delivery through a peripheral intravenous catheter may include a catheter adapter having a proximal end, a distal end, and a lumen extending there through. The catheter adapter may include a side port. The system may include an extension tube extending from the side port. The system may include a blood control valve disposed in the lumen of the catheter adapter. The system may include a peripheral intravenous catheter extending distally from the catheter adapter.

The subject of this disclosure is devices, systems, and uses thereof to treat a plurality of patients for paroxysmal atrial fibrillation. The solution can include delivering a multi-electrode radiofrequency balloon catheter and a multi-electrode diagnostic catheter to one or more targeted pulmonary veins; ablating tissue of the one or more targeted pulmonary veins using the multi-electrode radiofrequency balloon catheter; diagnosing the one or more targeted pulmonary veins using the multi-electrode diagnostic catheter; and achieving at least one of a predetermined clinical effectiveness and acute effectiveness of the method or use based on use of the multi-electrode radiofrequency balloon catheter and the multi-electrode diagnostic catheter in the isolation of the one or more targeted pulmonary veins.

A dilator used in performing a transseptal puncture; it has a hub with an opening at a proximal end; a shaft, connected to a distal end of the hub, comprising a lumen miming along a length of the shaft defining an inner wall within the shaft; an optical fiber for insertion into the lumen of the shaft, the optical fiber comprising a proximal end portion for sealing the opening of the hub, the optical fiber having a length for running along a length of the lumen; wherein the optical fiber is configured to, in a simultaneous or alternating fashion: propagate a laser beam with an ultrafast pulse duration that is generated by an ultrafast laser; and propagate light for obtaining visualization information from the light interacting with neighboring surfaces in the heart using optical coherence tomography.

Disclosed herein are impedance-determining medical systems. An impedance-determining medical system can include an impedance interrogator and an impedance-sensing medical device. The impedance interrogator can include instructions configured to instantiate one or more processes in random-access memory upon processing by one or more processors that determine impedance from electrical signals corresponding to electrical currents passed through a biological or non-biological material. The impedance-sensing medical device can include two or more longitudinal conductors distributed among one or more pieces of the impedance-sensing medical device and separated by one or more longitudinal insulators. The two-or-more conductors can be configured to emit, detect, or alternately emit and detect via two or more electrodes thereof the electrical currents passed through the biological or non-biological material. The impedance-sensing medical device can be configured to form a direct or indirect connection to the impedance interrogator and provide the electrical signals to the impedance interrogator.

A process and a device determine an indicator of an intrinsic end-expiratory pressure in the lungs of a patient. Embodiments are based on the device, ventilator with the device, and the process using the device that includes an interface arrangement configured for an exchange of information with a ventilation device and a control unit that determines first information on a first breathing pressure generated by muscles of the patient, at a first time, at which an inhalation attempt of the patient is present and determines second information on a second breathing pressure generated by the muscles of the patient, at a second time, at which breathing gas flow towards the patient starts. The control unit further determines the indicator of the intrinsic end-expiratory pressure based on the first information and based on the second information.

Disclosed are various examples and embodiments of systems, devices, components and methods configured to estimate the action potential wave propagation in a patient's heart, and subsequently to detect at least one location or type of at least one source of, or rotational phenomenon associated with, at least one cardiac rhythm disorder using intracardiac electrodes and a modified multi-frame Horn-Schunck algorithm to generate a map corresponding to a spatial map, the map being configured to reveal on a monitor or display to a user the at least one location of the at least one source of the at least one cardiac rhythm disorder.