Systems and methods for controlling fill media in a balloon catheter are disclosed. The system comprises a catheter having an inflatable balloon, a reservoir for fill media, and a first conduit for delivering fill media from the reservoir to the balloon. The system includes a second conduit for returning fill media from the balloon to the reservoir and a pump configured to circulate fill media through the conduits. The system also includes a valve assembly configured for placement in at least three positions. In the first position, fill media is delivered from the reservoir to the balloon to inflate the balloon. In the second position, fill media is drawn out of the balloon and returned to the reservoir. In the third position, fill media circulates through the conduits between the pump and the balloon and is prevented from flowing back to the reservoir.

A medical device and use thereof provide percutaneous access to a targeted site within a living body, for example the left ventricle of the heart. The device includes an inner tubular member, outer tubular member, and an adjustable control handle. The control handle can precisely control the relative position of the inner tubular member relative to the outer member by providing feedback to the operator. This feedback provided by the control handle allows the operator to precisely maneuver the catheter within a body and change the shape of the catheter system without taking his/her eyes off the task that he/she is performing. The control handle is designed to precisely change the catheter system from one tip shape to another tip shape and back.

A medical device used to percutaneously gain access to a targeted site within a living body, for example the left ventricle of the heart. The device is comprised of an inner tubular member, outer tubular member, and an adjustable control handle. The control handle can precisely control the relative position of the inner tubular member relative to the outer member by providing feedback to the operator. This feedback provided by the control handle allows the operator to precisely maneuver the catheter within a body and change the shape of the catheter system without taking his/her eyes off the task that he/she is performing. The control handle is designed to precisely change the catheter system from one tip shape to another tip shape and back. Described herein are methods to use such devices.

An absorbable, biocompatible barbed microcatheter for delivering therapeutic fluids to a patient includes a hollow tube having an elongated lumen that extends between proximal and distal ends of the hollow tube, a plurality of barbs projecting from the hollow tube, and a plurality of fluid egress openings formed in the hollow tube that are in fluid communication with the elongated lumen. The fluid egress openings are evenly spaced from one another along the length of the hollow tube. An anchor is secured to the proximal end of the hollow tube, and a surgical needle is secured to the distal end of the hollow tube. Two or more of the fluid egress openings formed in the hollow tube have different sizes so that a first fluid egress opening located adjacent the anchor is larger than a second fluid egress opening adjacent the surgical needle.

A multi-lumen catheter for monitoring uterine contraction pressure having an elongated body configured and dimensioned for insertion into a bladder of a patient, the catheter having a first lumen, a second lumen, and a first balloon at a distal portion, the first lumen communicating with the first balloon. The second lumen communicates with the bladder to remove fluid from the bladder. The first balloon is filled with a gas to form along with the first lumen a gas filled chamber to monitor pressure within the bladder to thereby monitor uterine contraction pressure of the patient.

A medical device used to percutaneously gain access to a targeted site within a living body, for example the left ventricle of the heart. The device is comprised of an inner tubular member, outer tubular member, and an adjustable control handle. The control handle can precisely control the relative position of the inner tubular member relative to the outer member by providing feedback to the operator. This feedback provided by the control handle allows the operator to precisely maneuver the catheter within a body and change the shape of the catheter system without taking his/her eyes off the task that he/she is performing. The control handle is designed to precisely change the catheter system from one tip shape to another tip shape and back. Described herein is a method to perform a catheter tip shape change without the need to observe manipulations of a control system to change catheter tip configurations.

A medical device used to percutaneously gain access to a targeted site within a living body, for example the left ventricle of the heart. The device is comprised of an inner tubular member, outer tubular member, and an adjustable control handle. The control handle can precisely control the relative position of the inner tubular member relative to the outer member by providing feedback to the operator. This feedback provided by the control handle allows the operator to precisely maneuver the catheter within a body and change the shape of the catheter system without taking his/her eyes off the task that he/she is performing. The control handle is designed to precisely change the catheter system from one tip shape to another tip shape and back. Described herein are methods to use such devices.

A device includes a handle, an expandable structure including a plurality of splines extending from a proximal hub to a distal hub, a first electrode on a first spline of the plurality of splines, an outer tube extending from the handle to the proximal hub, and a shaft extending through the outer tube from the handle to the distal hub. The expandable structure has a collapsed state and a self-expanded state. The handle is configured to retract the shaft. Retracting the shaft may expand the expandable structure outward of the self-expanded state.

A guide wire for biological pressure measurement includes a tube extending along a longitudinal axis of the guide wire; and a pressure sensor for biological pressure measurement, at least a portion of the pressure sensor being mounted within the tube. The pressure sensor comprises a pressure sensor membrane facing a top side of the tube. A circumferential wall of the tube includes at least six openings: a first distal opening, a second distal opening located on a right side of the tube, a third distal opening located on a left side of the tube, a first proximal opening, a second proximal opening located on a right side of the tube, and a third proximal opening located on a left side of the tube. The first distal opening is larger than the second and third distal openings, and the first proximal opening is larger than the second and third proximal openings.

A multi-lumen catheter for monitoring uterine contraction pressure having an elongated body configured and dimensioned for insertion into a bladder of a patient, the catheter having a first lumen, a second lumen, and a first balloon at a distal portion, the first lumen communicating with the first balloon. The second lumen communicates with the bladder to remove fluid from the bladder. The first balloon is filled with a gas to form along with the first lumen a gas filled chamber to monitor pressure within the bladder to thereby monitor uterine contraction pressure of the patient.