An implantable medical lead may include an electrode at a distal portion of the lead that is configured to monitor or provide therapy to a target site. The lead may include a visible indicator that is visible to the naked eye of a clinician at a medial portion of the lead that is configured to indicate when the electrodes of the lead are longitudinally and radially aligned properly to monitor or treat the target site. A clinician may insert the lead into the patient using an introducer sheath inserted to a predetermined depth into the patient and subsequently aligning the distal portion of the lead by orienting the indicator at an entry port of the introducer sheath.

An apparatus configured to lock an intrabody implant over a thread passing through the implant includes a lock body configured to advance to the implant over the thread and including at least one rotatable element, the lock body being configured to grip the thread proximally to the implant upon rotation of the rotatable element, and a rotation-maintaining element, configured to inhibit a reversal of the rotation of the rotatable element by engaging with the lock body. Other embodiments are also described.

The present disclosure provides an apparatus including a first clip configured to move between an open position and a closed position. The apparatus also includes a second clip configured to move between an open position and a closed position. The apparatus also includes an elongated connector that is semi-rigid and deformable and that has a first end and a second end. The first end of the elongated connector is coupled to the first clip, and the second end of the elongated connector is coupled to the second clip. The apparatus also includes a sensor coupled to the elongated connector between the first end and the second end.

A sensing device can be used for ambulatory urodynamics. The sensing device can include an elongated outer housing constructed of flexible material that can curve within a patients bladder. At least a portion of the outer housing can be filled with a non-compressible fluid. A flexible printed circuit board can be disposed within the outer housing to curve with the outer housing. The printed circuit board can include a pressure sensor, comprising a diaphragm, to collect pressure data; a microcontroller miming control software; and a wireless transmitter to transmit the pressure data. A battery can be disposed within the outer housing and coupled to the printed circuit board. The flexible material of the outer housing is configured to be displaced by a pressure within the patients bladder, the displacement is transmitted through the non-compressible fluid to the pressure sensor that provides the pressure data based on the displacement.

A method of viewing a patient including inserting a catheter is described for health procedure navigation. A CT scan is carried out on a body part of a patient. Raw data from the CT scan is processed to create three-dimensional image data, storing the image data in the data store. Projectors receive generated light in a pattern representative of the image data and waveguides guide the light to a retina of an eye of a viewer while light from an external surface of the body transmits to the retina of the eye so that the viewer sees the external surface of the body augmented with the processed data rendering of the body part.

Methods and systems for use of the Q-wave to R-wave interval to guide placement of a leadless cardiac pacemaker are disclosed. An implant delivery device is equipped with sensing electrodes to sense R-wave onset in a ventricle of a patient's heart to allow placement at a location of last or latest onset of the R-wave. Guidance tools are provided to assist in determination of the Q-wave to R-wave interval during implantation. For a chronic system, a cooperative approach is disclosed in which an implantable medical device and a leadless cardiac pacemaker exchange data to determine Q-wave to R-wave intervals and enhance cardiac resynchronization therapy delivery by the leadless cardiac pacemaker.

A delivery system for an intracorporeal device includes a sheath defining one or more lumens shaped to receive a delivery catheter or shaft and a guidewire. The system may include a delivery shaft having a distal coupling feature adapted to releasably couple with a proximal coupling feature of the intracorporeal device. The delivery system may further include a hub through which the delivery shaft and guidewire are passed. The delivery shaft may be coupled to a feature, such as a knob, that enables manipulation of the delivery shaft to decouple the distal fixation feature from the proximal fixation feature of the intracorporeal device in order to deploy the intracorporeal device within a patient.

Delivery system for fixation device, including guide catheter with proximal end portion having proximal end port, distal end portion having distal end port, and inner surface defining inner lumen extending in fluid communication between proximal end port and distal end port. Delivery catheter extending through the inner lumen to define annular space between outer surface of the delivery catheter and inner surface of the guide catheter. A pressure sensor proximate the proximal end portion in fluid communication with the annual space to monitor fluid pressure. The distal end portion of the guide catheter includes flow passages in fluid communication between an exterior of the distal end portion and the annular space.

Devices, systems, and methods for remotely monitoring physiologic cardiovascular data are disclosed. At least some of the embodiments disclosed herein provide access to the external surface of the heart through the pericardial space for the delivery of the sensor to the epicardial surface of the heart. In addition, various disclosed embodiments provide for a memory device capable of receiving the physiologic cardiovascular data collected by the sensors and transmitting such data wirelessly to a remote location.

Wireless, variable inductance and resonant circuit-based vascular monitoring devices, systems, methodologies, and techniques, including specifically configured anchoring structures for same, are disclosed that can be used to assist healthcare professionals in predicting, preventing, and diagnosing various heart-related and other health conditions.