The disclosure provides for an isovolumetric pump system for the removal of a thrombus and a method of use thereof. The isovolumetric pump system includes at least one inflow container connected to an output of the treatment region, at least one outflow container connected to an input of the treatment region, and a drawbar connecting the inflow container and the outflow container. As the drawbar is drawn back, the same quantity of fluid is drawn from the treatment region into the inflow container and injected into the treatment region from the outflow container.

A medical device is adapted for use in assisting with mechanical thrombectomy. The medical device may include a housing that is adapted to be held within a user's hand and a pump that is secured within the housing. A fluid inlet is adapted to receive fluid that is pulled towards the pump and is fluidly coupled with the pump. A fluid outlet is adapted to expel fluid away from the pump and is fluidly coupled with the pump. As the pump is operated by the user, fluid is alternatively pulled into the fluid inlet and expelled through the fluid outlet. In some cases, the fluid may be blood or other bodily fluids.

An extracorporeal circulation blood pump and a method thereof are provided. A driving motor is driven to operate, and a rotating head rotates, thereby driving a rotator in a pump to rotate, an electromagnet is controlled to produce an axial upward attractive force on the rotator, so that the attraction force is matched with a coupling between driving permanent magnets and driven permanent magnets, and the rotator can rotate without contact in the axial direction. A first radial support permanent magnet and a second radial support permanent magnet are configured to interact with each other to generate a repulsive force, and the rotator can rotate without contact in the radial direction, achieving complete non-contact rotation with a pump housing, so as to enable a complex impeller to rotate without bearing support.

A disposable fluid pump is provided with a housing including first and second faces, with a sidewall extending between the first and second faces. The housing defines a chamber, with an inlet and an outlet in fluid communication with the chamber. An impeller is rotatably mounted within the chamber and includes a plurality of flexible vanes. Such a pump may be incorporated into a disposable fluid flow circuit that is adapted to be mounted on a durable hardware for processing a fluid. In such a fluid flow circuit, the fluid pump may be integrated into a cassette of the circuit or, alternatively, the inlet and outlet of the fluid pump may be directly connected to fluid flow conduits of the circuit.

A blood pump for causing blood to flow in one direction is used for a blood oxidation system that circulates blood in a body to an oxidizer so as to supply oxygen into the body from outside the body. The blood pump includes an outer wall having a gas outlet port formed through a lateral surface thereof; a blood chamber having a pouch which is inserted into the outer wall and of which opposite ends are connected to opposite ends of the outer wall, respectively; a pump injection valve fluid-communicably coupled to one end of the blood chamber and blocking blood from flowing to the blood chamber; and a pump discharge valve fluid-communicably coupled to the other end of the blood chamber and blocking blood from flowing from the blood chamber.

A system for regulating blood flow in extracorporeal circulation, and including a blood reservoir to receive blood from a patient, an oxygenator to condition the blood, a centrifugal pump to pump the blood from the blood reservoir to the oxygenator and back to the patient, an electronic remote clamp to regulate flow of the blood, and a controller to operate in a flow control mode and a speed control mode. The controller includes an operational element to set a blood flow value in the flow control mode and to set a speed of the centrifugal pump in the speed control mode. The controller to automatically switch between the flow control mode and the speed control mode in response to one or more trigger conditions and to automatically switch between the speed control mode and the flow control mode in response to opening the electronic remote clamp.

A blood ultrafiltration system comprises a blood filter with first and second compartments separated by a semipermeable membrane. Blood input and blood output lines are connected in fluid communication with the first compartment. An effluent line is connected in fluid communication with the second compartment. A peristaltic pump is arranged for repeated engagement with first and second line segments. In a first arrangement, the first line segment is part of the blood input line or the blood output line and the second line segment is part of the effluent line. In a second arrangement, the first line segment is part of the blood input line and the second line segment is part of the blood output line. The system is operable, by the peristaltic pump, to pump blood through the blood filter and control the extraction of ultrafiltrate in the blood filter.

Provided is an extracorporeal circulator capable of judging a timing suitable for detachment with high accuracy. The extracorporeal circulator includes a blood removal side catheter with a part that can be inserted into a patient and guide the blood taken from the patient; a pump that can take the blood from the patient and return the blood to the patient; a blood transfer side catheter provided downstream of the pump, and that has a part that can be inserted into the patient and guide the blood sent out from the pump back into the patient; a pump rotation speed detection unit that can detect a rotation speed of the pump; and a control system including at least one of an extracorporeal circulation management system that can judge stability of the extracorporeal circulation and a cardiac function measurement system that can judge stability of a heart function of the patient.

Provided is an extracorporeal circulator capable of judging a timing suitable for detachment with high accuracy. The extracorporeal circulator includes a blood removal side catheter with a part that can be inserted into a patient and guide the blood taken from the patient; a pump that can take the blood from the patient and return the blood to the patient; a blood transfer side catheter provided downstream of the pump, and that has a part that can be inserted into the patient and guide the blood sent out from the pump back into the patient; a pump rotation speed detection unit that can detect a rotation speed of the pump; and a control system including at least one of an extracorporeal circulation management system that can judge stability of the extracorporeal circulation and a cardiac function measurement system that can judge stability of a heart function of the patient.

An integrated flow source is a limiting factor in numerous microfluidic applications. In addition to precise gradients and controlling molecular transports, a built-in source of stable and accurate flow can enable novel shear stress modulations for long-term cell culturing studies. The Tesla turbine, when used as a pump on the microfluidic regime, produces stable and accurate fluid gradients by utilizing laminar flow between its rotating discs Utilizing a stereolithography based 3D printer, a tesla pump (Ø10 cm) and associated housing capable of driving a microfluidic gradient is provided having a printed rotor surface topology of the pump in order to enhance pumping of biological fluids like blood at elevated viscosities. The surface topology is tuned via 3D pixilation, and this modulation completely recovered the pressure loss between pumping water at 1 cP versus glycerol solution at 3 cP. As a result, increased fluid viscosities, and even Non-Newtonian viscosities, can be used.