A pumping device includes a single-use device and a reusable device. The single-use device is to be inserted into the reusable device and includes two pump units in series, one behind the other. Each pump unit includes a rotor for a bearingless motor, and can be magnetically levitated and driven without contact for rotation about an axial direction. The reusable device includes a stator for each rotor which form an electromagnetic rotary drive for rotating the rotor about the axial direction. Each stator is a bearing and drive stator with which the rotor can be magnetically driven and levitated without contact with respect to the stator. An independent control device is provided for each stator, and can independently activate a respective stator.

A ventricular assist device is disclosed. The ventricular assist device may include a centrifugal pump and a controller. The controller may be configured to cause the centrifugal pump to operate at a first speed above a predetermined flow rate. The controller may also be configured to cause the centrifugal pump to operate at a second speed below the predetermined flow rate, wherein the predetermined flowrate is indicative of a crossover point between systole and diastole phases of a person's cardiac cycle.

A ventricular assist device is disclosed. The ventricular assist device may include a centrifugal pump and a controller. The controller may be configured to cause the centrifugal pump to operate at a first speed above a predetermined flow rate. The controller may also be configured to cause the centrifugal pump to operate at a second speed below the predetermined flow rate, wherein the predetermined flowrate is indicative of a crossover point between systole and diastole phases of a person's cardiac cycle.

To provide biotechnological filtration possibilities with which the danger of contamination is low and at the same time an optimum flow profile can be achieved, the use of a filter module 100 is proposed, the latter having, in a filter housing 110, a filter, with a bundle of hollow fibres 114, and a centrifugal pump rotor 132, for a biotechnological production method, and a filter module 100 for the filtration of a biotechnological liquid L, having a filter housing 110, a filter arranged in the filter housing 110 with a bundle of hollow fibres 114, a centrifugal pump rotor 132 arranged in the filter housing 110 such that it is fluidically connected to the interior of the hollow fibres 114, wherein the centrifugal pump rotor 132 is able to be magnetically driven such that it can force a liquid L through the hollow fibres 114, a first port 102 for the supply of a biotechnological liquid L to be filtered, which first port 102 is fluidically connected to the interior of the hollow fibres 114 of the filter, a second port 104 for the removal of a biotechnological liquid L to be filtered, which second port 104 is fluidically connected to the interior of the hollow fibres 114 of the filter, and a third port 107 for the removal of precipitated waste liquid, which third port 107 is fluidically connected to the exterior of the hollow fibres 114, and a filtration device 1100, 1200, 1300 having a filter module 100, which is able to be coupled to a drive unit, and a drive unit for magnetically driving the centrifugal pump rotor 132 of the filter module 100, which drive unit can generate dynamic magnetic fields for magnetically driving and magnetically supporting the centrifugal pump rotor 132 when the filter module 100 is coupled to the drive module.

To provide biotechnological filtration possibilities with which the danger of contamination is low and at the same time an optimum flow profile can be achieved, the use of a filter module 100 is proposed, the latter having, in a filter housing 110, a filter, with a bundle of hollow fibres 114, and a centrifugal pump rotor 132, for a biotechnological production method, and a filter module 100 for the filtration of a biotechnological liquid L, having a filter housing 110, a filter arranged in the filter housing 110 with a bundle of hollow fibres 114, a centrifugal pump rotor 132 arranged in the filter housing 110 such that it is fluidically connected to the interior of the hollow fibres 114, wherein the centrifugal pump rotor 132 is able to be magnetically driven such that it can force a liquid L through the hollow fibres 114, a first port 102 for the supply of a biotechnological liquid L to be filtered, which first port 102 is fluidically connected to the interior of the hollow fibres 114 of the filter, a second port 104 for the removal of a biotechnological liquid L to be filtered, which second port 104 is fluidically connected to the interior of the hollow fibres 114 of the filter, and a third port 107 for the removal of precipitated waste liquid, which third port 107 is fluidically connected to the exterior of the hollow fibres 114, and a filtration device 1100, 1200, 1300 having a filter module 100, which is able to be coupled to a drive unit, and a drive unit for magnetically driving the centrifugal pump rotor 132 of the filter module 100, which drive unit can generate dynamic magnetic fields for magnetically driving and magnetically supporting the centrifugal pump rotor 132 when the filter module 100 is coupled to the drive module.

In some examples, a medical system includes a pump is configured to provide a pulsating blood flow. The pump may provide the pulsating flow to assist the pumping action of a heart. An impeller is configured to impart energy to the blood flow when the impeller rotates around an eye axis extending through an impeller eye defined by the impeller. The pump includes a magnetic bearing configured such that, as the impeller rotates around the eye axis, the eye axis translates around a post axis defined by a post mechanically supported by a pump housing. The medical system may include a controller configured to control a bearing magnetic field and/or a stator magnetic field to control a pressure of the pulsating flow and/or a speed of the pump.

A magnetic levitation centrifugal pump, comprises: one hollow body provided with at least one inlet connector and with at least one outlet connector for blood; one rotor element, housed inside the hollow body and comprising at least one magnetic portion, where the rotor element can be commanded in rotation about an axis of rotation, without contact, by a stator element associable with the hollow body, the rotor element comprising at least one revolving body, which defines an upper surface supporting a plurality of blades which are adapted to convey blood towards the outlet connector; where the upper surface has a substantially concave shape and where the revolving body comprises at least one through hole which is positioned along the axis of rotation.

A magnetic levitation centrifugal pump, comprises: one hollow body provided with at least one inlet connector and with at least one outlet connector for blood; one rotor element, housed inside the hollow body and comprising at least one magnetic portion, where the rotor element can be commanded in rotation about an axis of rotation, without contact, by a stator element associable with the hollow body, the rotor element comprising at least one revolving body, which defines an upper surface supporting a plurality of blades which are adapted to convey blood towards the outlet connector; where the upper surface has a substantially concave shape and where the revolving body comprises at least one through hole which is positioned along the axis of rotation.

An inflow cannula for an implantable blood pump having an impeller defining a plurality of flow channels, the inflow cannula includes a proximal end a distal end proximate the impeller, the distal end including a protuberance extending outward from the inflow cannula.

A blood pump comprises a pump casing having a blood flow inlet and a blood flow outlet, and an impeller arranged in said pump casing and rotatably supported in the pump casing by a bearing so as to be rotatable about an axis of rotation. The impeller has blades for conveying blood from the blood flow inlet to the blood flow outlet. The bearing comprises at least one stationary bearing portion coupled to the pump casing and having a stationary bearing surface that faces radially outwards. The bearing further comprises a rotating bearing surface interacting with the stationary bearing surface to form the bearing, wherein the rotating bearing surface faces radially inwards and is formed on an exposed radially inner edge of the blades. The blades are designed to draw blood deposit on the stationary bearing surface in a radially outward direction.