Disclosed is a cannula (CA1 to CA7) for endovascular and/or jugular blood circuit support, comprising: —a proximal portion (PP1 to PP6), —a distal portion (DP1 to DP7) that comprises at least one distal opening (DO1 to DO7), —a lumen portion (LP) that extends from the proximal portion (PP1 to PP6) to the at least one distal opening (DO1 to DO7), and—at least one intermediate portion (IP1 to IP7) that is arranged between the proximal portion (PP1 to PP6) and the distal portion (DP1 to DP7), wherein the intermediate portion (IP1 to IP7) comprises at least one intermediate opening (IO1 to IO7), and wherein the intermediate portion (IP1 to IP7) is configured such that more than 90 volume percent of the fluid flow are drained from the intermediate opening (IO1 to IO7) if a fluid flow within the proximal portion (PP1 to PP6) is directed proximally and such that more than 90 volume percent of the fluid flow are delivered through the at least one distal opening (DO1 to DO7) if a fluid flow within the proximal portion (PP1 to PP6) is directed distally.

Disclosed is a cannula (CA1 to CA7) for endovascular and/or jugular blood circuit support, comprising: —a proximal portion (PP1 to PP6), —a distal portion (DP1 to DP7) that comprises at least one distal opening (DO1 to DO7), —a lumen portion (LP) that extends from the proximal portion (PP1 to PP6) to the at least one distal opening (DO1 to DO7), and—at least one intermediate portion (IP1 to IP7) that is arranged between the proximal portion (PP1 to PP6) and the distal portion (DP1 to DP7), wherein the intermediate portion (IP1 to IP7) comprises at least one intermediate opening (IO1 to IO7), and wherein the intermediate portion (IP1 to IP7) is configured such that more than 90 volume percent of the fluid flow are drained from the intermediate opening (IO1 to IO7) if a fluid flow within the proximal portion (PP1 to PP6) is directed proximally and such that more than 90 volume percent of the fluid flow are delivered through the at least one distal opening (DO1 to DO7) if a fluid flow within the proximal portion (PP1 to PP6) is directed distally.

An arrangement (200 to 1200) is provided for transporting a liquid (B) through a cannula system (CS), comprising: a liquid guiding system (LGS) comprising at least three separated portions (SP2a, SP2b, SP3c) which define separate liquid guiding portions of the liquid guiding system (LGS), and a connecting portion (CP2 to CP12) which fluidically connects the at least three separated portions (SP2a, SP2b, SP3c) and which comprises a lumen that branches out into at least two lumens, wherein the liquid guiding system (LGS) is configured to be connected to a pump arrangement (Arr2 to An12) which drives a flow of the liquid (B), and wherein the liquid guiding system (LGS) is configured to be connected to a cannula system (CS) which is adapted to be inserted into a body of a human or of an animal and which comprises an inflow opening and an outflow opening of the liquid guiding system (LGS).

Devices and methods for providing localized pressure to a region of a patient's heart to improve heart functioning, including: (a) a jacket made of a flexible biocompatible material, the jacket having an open top end that is received around the heart and a bottom portion that is received around the apex of the heart; and (b) at least one inflatable bladder disposed on an interior surface of the jacket, the inflatable bladder having an inelastic outer surface positioned adjacent to the jacket and an elastic inner surface such that inflation of the bladder causes the bladder to deform substantially inwardly to exert localized pressure against a region of the heart.

Devices and methods for providing localized pressure to a region of a patient's heart to improve heart functioning, including: (a) a jacket made of a flexible biocompatible material, the jacket having an open top end that is received around the heart and a bottom portion that is received around the apex of the heart; and (b) at least one inflatable bladder disposed on an interior surface of the jacket, the inflatable bladder having an inelastic outer surface positioned adjacent to the jacket and an elastic inner surface such that inflation of the bladder causes the bladder to deform substantially inwardly to exert localized pressure against a region of the heart.

A device for reducing pressure within a lumen includes a reservoir structured for holding a fluid therein, an injection port in fluid communication with the reservoir, a compliant body structured to expand and contract upon changes in pressure, and a conduit extending between and fluidly coupling the reservoir and the compliant body. The fluid may be a compressible or a noncompressible fluid.

A cardiac assist device including a sleeve configured to externally wrap around a native, intact heart; a motor, and a drive shaft that connects the motor to the sleeve, wherein, actuation of the motor and the drive shaft provides a synchronized assisting force to a pumping force of the native, intact whole heart, thereby helping contraction and expansion of the heart located within an internal volume defined by the sleeve. Some embodiments relate to a system for synchronizing the cardiac assist device with a heart including the cardiac assist device; a power supply connected to the motor; and an electrical connector-relay configured to receive electrical signals from the pacemaker and to generate actuating signals that are relayed to the motor and the drive shaft, wherein, during operation of the system in a subject, the heart is assisted in contracting synchronously with the pacemaker signal rhythm.

An inflow cannula assembly intended for connecting a ventricular assist device (VAD) to a heart chamber without suturing anastomosis is provided. The inflow cannula assembly includes a deformable flow cannula with funnel-shaped bellmouth intake at a first end and a second end interfaced to the inlet of a VAD with minimal interface discontinuity; also includes is a pair of male and female fasteners that can be screw locked to fix and seal the cannula bellmouth against the endocardium for hemostasis purpose; as well as a VAD coupler and a VAD inlet adapter that enable a quick connection of the cannula with the VAD.

A para-aortic blood pump device includes a blood pump, an aortic adapter, a driveline, and a driver. The blood pump includes a blood sac, a pump housing and a pressure sensor, whereas the pressure sensor is installed in the pump housing for monitoring the blood pressure inside the blood pump. The aortic adapter is a T-manifold shaped conduit connected to the blood pump and is used for connecting the blood pump with human aorta to facilitate circulatory support. The driveline allows a pneumatic communication to the blood pump in addition to transmitting the electrical blood pressure signal to the driver. The driver receives and processes the electrical blood pressure signal, decides the timing, speed and duration of blood pump fill and eject actions so as to provide counter-pulsatile circulatory support to assist human circulation.

An implantable circulatory support system, configured to connect a ventricular chamber of a heart, including a valveless displacement blood pump, a deformable polymeric flow cannula, a pair of male and female fasteners, a coupler, a driveline assembly, and a co-pulsatile driver. Forward and backward flow communication between the blood pump and the heart chamber is accomplished using the present flow cannula invention which is anastomosed to the heart chamber in a sutureless manner. When providing circulatory support, the co-pulsatile driver ejects blood out of the blood pump during systolic ventricular contraction and fills the blood pump with blood during diastolic ventricular relaxation.