A wall of a catheter (a) includes a braided portion having an outer surface, an inner surface, and a braided interior between the outer and inner surfaces, and (b) is shaped to define first and second longitudinally-running channels therethrough. A distal portion of the catheter is shaped to define first and second lateral openings. An angle between (a) a first line running between the first and second lateral openings, and (b) a second line that is parallel to a central longitudinal axis of the catheter when the catheter is straight, is between 30 and 150 degrees. A flexible longitudinal member passes from a proximal portion of the catheter to the distal portion via the first channel, out of the first channel via the first lateral opening, into the second channel via the second lateral opening, and from the distal portion to the proximal portion via the second channel.

The invention provides an intraventricular pulsating blood pump fixedly disposed at the ventricularapex inside the ventricle to generate pulsation action. The pulsating blood pump is substantially jellyfish-shaped and includes a bell-shaped pump body and a driving source, an opening of the bell-shaped pump body faces to the outlet of the ventricle, the driving source drives the bell-shaped pump body to contract or relax, and the contraction or relaxation of the bell-shaped pump body drives the blood in the ventricle to eject directionally to the artery and form a convoluted blood flow field between the inner wall of the bell-shaped pump body and the inner wall of the ventricle. The invention not only provides assist to ventricular by pulsating blood flow, but also optimizes the flow field and pressure distribution in the ventricle, the blood pump of the invention is better in biocompatibility than the blood pumps in prior art.

A transseptal catheter delivery system includes an elongate first tubular member and an elongate second tubular member receivable within the first tubular member. The first tubular member includes an adjustable portion adjacent a distal end. The second tubular member is adapted to receive an instrument to be placed in the left ventricle, and includes a curved portion adjacent its distal end in a relaxed state. The adjustable portion is deflectable toward the atrial septum to guide a puncturing tool and/or guide insertion of the second tubular member through a septal puncture into the left atrium. Within the left atrium, the curved portion is oriented toward the left ventricle to guide insertion of a guide wire, and subsequently the second tubular member, into the left ventricle. Methods of transvenously accessing a left ventricle are also provided.

An endovascular catheter has an elongate catheter body having a distal portion, a proximal portion, multiple transition portions and a central lumen extending longitudinally through the catheter body. The catheter has a hybrid reinforcement, an angulated radiopaque marker and an angulated distal tip to improve the catheter’s ability to navigate vasculature and to improve clot aspiration.

Delivery devices, systems, and methods may be configured to define a barrier region at a treatment site to deliver one or more therapeutic materials. A device for delivering one or more therapeutic materials to a treatment site may include a body; one or more members that are movable with respect to the body and that are configured to define a barrier region at the treatment site; and one or more delivery lumens configured to deliver one or more therapeutic materials to the barrier region.

A device for administration of substances onto an epicardial surface of a heart includes a frame structure for at least partially encircling a circumference of the heart which is able to assume shaping, positioning, guiding and stabilizing functions. The frame structure may be coupled to a heart-shaped sleeve. A substance carrier for accommodating the substances to be administered may be coupled to the device.

The present disclosure relates to a saccular cavopulmonary assist device, including a shell, an inflow tube (6) and an outflow tube (4), wherein a blood storage cavity (A) and a power cavity (B) are arranged in the shell, and the power cavity (B) is used for providing contraction and relaxation power for the blood storage cavity (A); the inflow tube (6) is arranged at a position corresponding to the power cavity (B) on the shell, an outer end is used for communicating with the vena cava, and an inner end communicates with the blood storage cavity (A) after passing through the power cavity (B); the outflow tube (4) is arranged at a position corresponding to the blood storage cavity (A) on the shell, an outer end is used for communicating with the pulmonary artery, and an inner end communicates with the blood storage cavity (A). This device can assist the cavopulmonary circulation of the single ventricle, realize repeated blood drawing and pumping actions, provide the required power for the pulmonary circulation of the patient, and restore the biventricular blood flow in the human body; and because the arrangement of the inflow tube in the power cavity, the internal structure of this device is more compact, the overall shape is smaller, and the energy of the power cavity can be fully utilized.

A medical method of accessing a site in or at a heart of a patient through the vasculature of the patient from a radial or cubital vessel comprises navigating a unilateral catheter to an endocardial site, lungs, or abdominal organs, comprising: advancing the catheter through an opening punctured in a radial access opening or in a cubital vein towards the desired site, when reaching a curve or bifurcation in a blood vessel with a distal end of the catheter, pulling a pull wire of the catheter until a bend of a distal end of the catheter is detectable, rotating the catheter by rotating a handle of the catheter for aligning the radial orientation of the bend of the distal end of the catheter to correspond to a radial orientation of the curve or bifurcation in the blood vessel, pulling the pull wire by manually operating the handle of the catheter until the radius of the bend in the distal end of the catheter corresponds to a radius of the curve or bifurcation in the blood vessel, and pushing the handle for advancing the catheter through the curve or bifurcation.

A method is provided. The method includes pacing, by electrodes of a catheter, a heart tissue with pulses. The method includes observing, by the electrodes, a period of electrophysiological repolarization for the heart tissue. The period of electrophysiological repolarization is caused by the pacing. The method also includes measuring, by the electrodes, an electrical signal within the heart tissue after the period of electrophysiological repolarization.

The invention relates to a catheter device, having a catheter (1), an actuation device (8) at a first end of the catheter and also a mechanical transmission element (9, 10) for transmitting a movement along the catheter to the actuation device, the actuation device having a coupling element (14) which is connected to the transmission element (9, 10) and can be actuated by the latter relative to the longitudinal direction of the catheter in a first degree of freedom, and also a conversion element (15) which can be actuated by the coupling element and which converts the actuation movement at least partially into a movement in a second degree of freedom. As a result, a combined movement at the distal end of the catheter can be produced particularly simply for compression and release of a functional element.