A method for setting-up a fluid processing medical apparatus, the method includes: a) positioning a disposable component intended to be used for therapy with the fluid processing medical apparatus relative to a reader unit by a user; b) reading component related information provided on the disposable component by the reader unit; c) matching the read component related information with component related data stored in a database; and d) providing a selection of suitable therapies for the disposable component to the user based on the matching.

A system for imploding leukemia cells of a patient includes (a) a first vessel for containing a volume of blood received from the patient, and (b) drive circuitry cooperatively coupled with at least one transducer to produce ultrasound energy that spatially decoheres and disperses throughout the volume, to implode the leukemia cells throughout the volume via absorption of the ultrasound energy by the leukemia cells. The transducer may be an immersible transducer configured to be immersed in the blood. The system may include a second vessel for containing a liquid, within which the ultrasound energy is decohered and dispersed and from which at least a portion of the ultrasound energy is transmitted to the first vessel to implode the leukemia cells.

A medical fluid management assembly includes a pneumatic manifold, a pump and valve engine, and a fluid manifold. The pneumatic manifold includes a plurality of pneumatic passageways and a plurality of pneumatic connectors. The pump and valve engine includes a plurality of valve chambers, at least one pump chamber, and a plurality of pneumatic connectors mated sealingly and releasably with the pneumatic connectors of the pneumatic manifold. The pump and valve engine also includes a plurality of fluid connectors. The fluid manifold includes a plurality of fluid pathways and a plurality of fluid connectors mated sealingly and releasably with the fluid connectors of the pump and valve engine.

The present disclosure relates to a method for determining an actual pump rate and/or for calibrating a blood pump of a blood treatment apparatus connected to an extracorporeal blood circuit. The method includes providing a blood pump of a blood treatment apparatus or establishing a signal communication to a blood pump. The blood pump comprises, or is connected to at least a first source for a fluid and at least a first line of an extracorporeal blood circuit which is connected to the first source downstream. Furthermore, the blood pump comprises, or is connected to, a reception unit for receiving fluids of the first source wherein the reception unit is in fluid communication with the first line. The reception unit is arranged on or at a first weighing device such that the weight of the reception unit or of its content is determined using the weighing device.

Systems and methods for the treatment of a bodily fluid, for example, using a cartridge that may include a cartridge body configured to retain an adsorptive material and an end segment configured to cover a first end of the cartridge body. The end segment may include a circular face comprising an outwardly truncated conical shape and defining an internal conical space, a cylindrical wall joined to a periphery of the circular face, and an inlet configured to provide fluid connection to a source of the bodily fluid. The inlet may be disposed tangential to the circular face at the cylindrical wall so as to direct bodily fluid entering the cartridge into the internal conical space tangentially so as to decelerate the bodily fluid within the internal conical space prior to contact with the adsorptive material disposed within the cartridge body.

A medical system includes a reusable apparatus and a disposable fluid circuit, the disposable fluid circuit being coupled to the reusable apparatus and the reusable apparatus being configured to move a fluid through the disposable fluid circuit to perform a procedure. The medical system also includes a controller coupled to the reusable apparatus and configured to control the reusable apparatus to move the fluid through the disposable circuit according to the procedure, to store a procedure record in a memory, to await a procedure termination input, and if the procedure termination input is received, to request at least one input corresponding to a procedure termination reason and to add the procedure termination reason corresponding to the input to the procedure record if received.

A method may include accessing a terminal branch of an ophthalmic artery through a face of a subject. Additionally, the method may include positioning a device within the ophthalmic artery of the subject and treating at least one of a blockage, a stenosis, a lesion, plaque or other physiology in at least one of the ophthalmic artery or a junction between an internal carotid artery and the ophthalmic artery.

Described are methods and systems for transcervical access of the cerebral arterial vasculature and treatment of cerebral occlusions, including ischemic stroke. The methods and devices may include methods and devices which may provide aspiration and passive flow reversal, those which protect the cerebral penumbra during the procedure to minimize injury to brain, as well as distal catheters and devices to remove an occlusion. The methods and devices that provide passive flow reversal may also offer to the user a degree of flow control. Devices and methods which provide a way to securely close the access site in the carotid artery to avoid the potentially devastating consequences of a transcervical hematoma are also described.

The present technology relates to methods and devices for the removal of toxins and pathogens from infected blood of patients. In particular, devices are designed to be portable, wearable, disposable and self-contained extracorporeal devices that can be easily assembled from a kit.

A control system controlling the line pressure in a blood supply system (1) in which a pump (14) pumps blood from a reservoir (10) via a primary passage (18) toward a plurality of outlets (16, 26, 26a), wherein one or more outlets are openable to permit flow and closable to block flow, said control system comprises a monitoring arrangement to determine a line pressure in the primary passage, and a controller responsive to the monitoring arrangement and controlling the pump (14) to maintain the line pressure in the primary passage (18) above a pre-set level. The control system practically eliminates the risk of a momentary reduction in blood supply line pressure when an outlet is opened.