Described are embodiments that include methods and devices for separating components from multi-component fluids. Embodiments may involve use of separation vessels and movement of components into and out of separation vessels through ports. Embodiments may involve the separation of plasma from whole blood. Also described are embodiments that include methods and devices for positioning portions, e.g., loops, of disposables in medical devices. Embodiments may involve use of surfaces for automatically guiding loops to position them into a predetermined position.

A portable arm support can be secured to an arm of a patient, for instance during a medical procedure (e.g., filtration of blood of the patient). The arm support can inhibit movement of the arm of the patient in one or more degrees of freedom (e.g., elevation, abduction, adduction, flexion, or the like). In some examples, the arm support includes a cuff and abase. In another example, the arm support includes an elongated member. In yet another example, the arm support includes a constricting band. The arm support can help maintain blood flow in the arm of the patient, and can help protect a catheter inserted into the arm of the patient (or protect other medical equipment proximate to the patient).

The specification discloses a portable dialysis machine having a detachable controller unit and base unit. The controller unit includes a door having an interior face, a housing with a panel, where the housing and panel define a recessed region configured to receive the interior face of the door, and a manifold receiver fixedly attached to the panel. The base unit has a planar surface for receiving a container of fluid, a scale integrated with the planar surface, a heater in thermal communication with the planar surface, and a sodium sensor in electromagnetic communication with the planar surface. Embodiments of the disclosed portable dialysis system have improved structural and functional features, including improved modularity, ease of use, and safety features.

Provided is a filter apparatus, comprising two or more filter cartridges having a first end with an inlet and screen and a second end with an outlet and screen, and walls to contain a filter media held in a housing for holding the two or more filter cartridges in about the same orientation, and an attachment clamp connected to the housing. Also provided is a housing for holding two or more filter cartridges in about the same orientation and a method of using the filter apparatus and housing.

The invention relates to a medical treatment device comprising a fluid system, which has a monitoring apparatus 27 for monitoring the treatment device, wherein the monitoring apparatus 27 is configured such that monitoring is based on the evaluation of the pressure in the fluid system of the medical treatment device. The invention further relates to a method for monitoring a medical treatment device, in which monitoring is based on the evaluation of the pressure in the fluid system. The treatment device is characterised by a compliance-determining apparatus 28 for determining the compliance in the fluid system, part of the fluid system or parts of the fluid system, wherein the compliance-determining apparatus 28 cooperates with the monitoring apparatus 27 in such a manner that the pressure-based monitoring takes place depending on the compliance of the fluid system.

A device and method are described for the treatment of blood, which device may be used in conjunction with or in place of a failed Kidney. The device includes an ultrafiltration unit to remove proteins, red and white blood cells and other high molecular weight components, a nanofiltration unit to remove glucose, at least one electrodeionization unit to transport ions from the blood stream, and a reverse osmosis unit to modulate the flow of water, to both the blood and urine streams. In one embodiment, a specialized electrodeionization unit is provided having multiple chambers defining multiple dilute fluid channels, each channel filled with an ion specific resin wafer, and electrodes at the extremity of the device and proximate each of the resin filled dilute channels. By selective application of voltages to these electrodes, the ion transport functionality of a given dilute channel can be turned on or off.

The present disclosure relates to a pressure measuring line, with a connector to connect the pressure measuring line to a blood treatment apparatus, and to a membrane. In some embodiments, the pressure measuring line comprises at least two consecutive lumen sections, namely the first lumen section and the second lumen section. The first lumen section comprises a first lumen geometry and the second lumen section comprises a second lumen geometry, whereby the first lumen geometry and the second lumen geometry differ from each other in at least their diameters. Further, a monitoring method and devices are described.

Described are embodiments that include methods and devices for separating components from multi-component fluids. Embodiments may involve use of separation vessels and movement of components into and out of separation vessels through ports. Embodiments may involve the separation of plasma from whole blood. Also described are embodiments that include methods and devices for positioning portions, e.g., loops, of disposables in medical devices. Embodiments may involve use of surfaces for automatically guiding loops to position them into a predetermined position.

Intravascular blood pumps and methods of use. The blood pump include a pump portion that includes a collapsible blood conduit defining a blood flow lumen between an inflow and an outflow. The pump portion includes a distal collapsible impeller axially spaced from a proximal collapsible impeller, at least a portion of each of the distal and proximal collapsible impellers disposed between the inflow and the outflow.

The present disclosure relates to an intravascular catheter with sensor systems that can measure intravascular pressure using MEMS sensors. Devices of the present disclosure can also be used to administer intravenous therapies, such as drug delivery or hemodialysis. Exemplary devices can be equipped with multiple MEMS sensors to measure pressure in multiple locations throughout the cardiovascular system. The intravascular catheter can communicate with a receiver and monitor to display sensor data.