An intravascular blood pump has an intake filter that reduces risk of heart tissue being sucked into an intake port of the pump. The filter defines a plurality of apertures, through which blood flows through the filter. The apertures are sized to prevent ingestion, by the input port, of the heart tissue. The filter includes a plurality of generally helical first struts wound about a longitudinal axis of the filter, and a plurality of second struts. The first and second struts collectively define the plurality of apertures therebetween. The struts may be woven filaments, or the apertures may be defined in a thin film (foil) tube, where remaining material between the apertures form the struts.

An intravascular blood pump has an intake filter that reduces risk of heart tissue being sucked into an intake port of the pump. The filter defines a plurality of apertures, through which blood flows through the filter. The apertures are sized to prevent ingestion, by the input port, of the heart tissue. The filter includes a plurality of generally helical first struts wound about a longitudinal axis of the filter, and a plurality of second struts. The first and second struts collectively define the plurality of apertures therebetween. The struts may be woven filaments, or the apertures may be defined in a thin film (foil) tube, where remaining material between the apertures form the struts.

Apparatus and methods are described including a device configured for insertion into a left ventricle of a heart of a subject. A delivery tube is coupled to the device and configured to traverse an aortic arch of the subject while the device is within the left ventricle. An elongation-resistant fiber runs axially along the delivery tube so as to bias an orientation of the delivery tube while the delivery tube traverses the aortic arch such that the elongation-resistant fiber is disposed inside a curve of the aortic arch, thereby biasing an orientation of the device. Other applications are also described.

Apparatus and methods are described including a left-ventricular assist device that includes a pump-outlet tube shaped to define one or more blood-outlet openings and including a narrower section, and a wider section, which is proximal to and wider than the narrower section, and which is shaped to define at least a portion of each of the blood-outlet openings such that a normal vector to the portion has a distally-facing component. The pump-outlet tube is inserted, through the subject's aorta, into the subject's left ventricle such that the pump-outlet tube traverses an aortic valve of the subject with the blood-outlet openings being disposed within the aorta. An impeller is disposed within the narrower section of the pump-outlet tube and is configured to pump blood of the subject, through the blood-outlet openings, from the left ventricle into the aorta. Other applications are also described.

Apparatus and methods are provided, including inserting a drive-cable-bearing tube, which includes one or more inwardly-facing ceramic portions, into a body of a subject and through an aorta of the subject, such that the inwardly-facing ceramic portions are within an aortic arch of the subject, while a drive cable, which is coupled to an intracorporeal device at a distal end of the drive-cable-bearing tube and includes one or more outwardly-facing ceramic portions, passes through the drive-cable-bearing tube such that the outwardly-facing ceramic portions are aligned with the inwardly-facing ceramic portions. The drive cable is rotated within the drive-cable-bearing tube, thereby rotating the intracorporeal device, while the outwardly-facing ceramic portions are aligned with the inwardly-facing ceramic portions. Other applications are also described.

Apparatus and methods are described including inserting a drive-cable end of a drive cable, which includes a plurality of coiled wires, and a hollow-shaft end of a hollow shaft, which hollow-shaft end is shaped to define multiple shaft pores, into opposing ends of a coupling tube having a wall shaped to define multiple tabs. The drive cable is coupled to the shaft by pushing at least some of the tabs into the shaft pores, respectively. Other applications are also described.

Apparatus and methods are described including an axial shaft configured for insertion into, and rotation within, a subject's body. A delivery tube extends to the axial shaft, from outside the subject's body, while the axial shaft is within the subject's body. An impeller is coupled to the axial shaft such that, as the axial shaft rotates, the impeller pumps blood of the subject. Proximal and distal radial bearings surround the axial shaft, proximally and distally to the impeller respectively, the proximal and distal radial bearings being configured to radially stabilize the axial shaft while the axial shaft rotates. A proximal bearing housing houses the proximal radial bearing and is coupled to the delivery tube. A drive cable rotates the axial shaft while extending through the delivery tube, and is coupled to the axial shaft within the proximal bearing housing. Other applications are also described.

Apparatus and methods are described including an axial shaft and an impeller configured for rotation within a subject's body. A coupling element includes a first portion, which is disposed around the axial shaft, is shaped to define one or more slits that facilitate a radial expansion of the first portion such that the first portion is placeable around the axial shaft, and is shape-set to have an inner diameter that is smaller than a diameter of the axial shaft such that, following placement of the first portion around the axial shaft, the first portion becomes radially contracted around, and thus locked in place with respect to, the axial shaft. A second portion of the coupling element is coupled to a bushing of the impeller. Other applications are also described.

A catheter for intravascular use has a blood inlet and a blood outlet, and includes a membrane arranged in the catheter in such a way that at least one part of the blood flowing into the catheter via the blood inlet during operation comes into contact with the membrane. The membrane allows an exchange of at least one substance between a carrier medium and the blood. The carrier medium is a carrier fluid in which the substance to be exchanged can be dissolved, and the catheter includes a delivery device that is designed to at least partially compensate for a pressure difference between the blood inlet and the blood outlet during operation. A method for removing at least one substance from venous blood for diagnostic purposes uses a device of this type.

Apparatus and methods are described including a left-ventricular assist device that includes a pump-outlet tube shaped to define one or more blood-outlet openings and configured for insertion, through an aorta of a subject, into a left ventricle of a heart of the subject such that the pump-outlet tube traverses an aortic valve of the subject with the blood-outlet openings being disposed within the aorta. A blood pump is disposed at least partly within a distal portion of the pump-outlet tube and is configured to pump blood of the subject proximally through the pump-outlet tube. A proximal end of the pump-outlet tube is folded inwardly so as to define one or more surfaces configured to direct the blood through the blood-outlet openings by virtue of being oblique with respect to a longitudinal axis of the pump-outlet tube. Other applications are also described.