An apparatus including a hollow body, an inlet fluidly coupled to the hollow body, a piston slidably engaged within the hollow body, and a filter module arranged within the hollow body between the inlet and piston. The piston and hollow body cooperatively generate a negative pressure, relative to ambient, within the hollow body during distal piston translation from a first position to a second position, thereby drawing a fluid, such as blood, through the filter module into the hollow body. The piston and hollow body cooperatively generate a positive pressure, relative to ambient, within the hollow body during piston translation from the second position to the first position to egress the filtered fluid from the hollow body. The filter module may include a filter housing, a filter medium disposed within the housing, and a body valve configured to seal an open distal face of the filter housing.

Provided herein are compositions and kits including a pathogen-inactivated cryoprecipitate suitable for infusion into a subject at least 1 day after thawing. The methods are useful in the efficient preparation of cryoprecipitates with desirable characteristics, including pathogen-inactivated cryoprecipitates that are suitable for infusion into a subject at least 1 day after thawing.

Certain embodiments of the invention are directed to methods of adjusting the concentration of one or more electrolytes in a patients blood using a counter current electrolyte solution.

Provided herein are bedside systems and methods for performing customized cell-based therapies and treatments in a patient-connected, closed-loop continuous-flow manner, including cellular modifications and treatments, e.g., to produce chimeric antigen receptor-T (CAR-T) cells among other cellular modifications and treatments.

A device for controlling the temperature of and thawing a temperature-controlled product, with a housing containing the temperature-controlled product, a heating module for introducing heat at least at one side of the temperature-controlled product and an actuating member, using which movement can be introduced into the temperature-controlled product. The actuating member is designed as a mechanical actuating element which extends along and ideally makes direct contact with the temperature-controlled product, and which can be controlled such that it executes a periodic and/or non-periodic movement.

A filter assembly comprising a prefiltering support layer (84) is disclosed, wherein the prefiltering support layer (84) comprises a non-woven fabric of fibers, the non-woven fabric having a pore size. A first mesh filter layer (85) is arranged downstream the prefiltering support layer (84), wherein the first mesh filter layer (85) has a first mesh size, wherein the pore size of the prefiltering support layer (84) is equal to or bigger than the first mesh size of the first mesh filter layer (85). A container for collecting a body fluid comprising such a filter assembly as well as a method for manufacturing such a filter assembly are also disclosed.

Device (1) for filling blood products (12) into at least two administration containers (2), comprising at least one receptacle (3) for dispensing the blood product (12) into the device (1), a channel system (4, 7, 8, 17) connected to carry fluid to the administration containers (2), and an air exhaust assembly (10, 11, 15), where the device (1) further comprises a plate-shaped component (6) in which the channels (7, 8, 17) of the channel system run, through which the administration containers (2) can be filled in parallel with equal volumes of the blood product (12).

Disclosed herein is a syringe-integrated platelet extraction device including: a housing having a longitudinal inner space for receiving collected blood, open at a top thereof, and formed at a bottom thereof with an orifice to which a syringe needle is coupled; a cap coupled to the orifice of the housing; a collector press-fitted into the housing from above the housing; a connector detachably coupled to an upper portion of the collector; and a plunger detachably coupled to the connector.

A sample processing unit (SPU)-equipped drone for transporting and processing biological materials and method of using same is disclosed. In some embodiments, the presently disclosed SPU-equipped drone and method provide a drone equipped to carry an SPU and wherein the SPU may include a centrifuge arranged inside a temperature-controlled chamber and wherein the centrifuge may be used to process biological materials at the same time that the SPU-equipped drone is in flight. Further, a method of using the presently disclosed SPU-equipped drone for transporting and processing biological materials is provided.

A cost-effective, single use bag or container is provided for storing biological substances that incorporates on its inner wall an electronic device that is configured to measure physiological and/or physical parameters of the enclosed biological substances, such as source history, identification, demographics, time stamping, temperature, pH, conductivity, glucose, O.sub.2, CO.sub.2 levels etc. The electronic device of the disclosed bag comprises a sensor configured to measure physiological and/or physical parameters of the biological substances enclosed within the bag, and a radio-frequency (RF) device communicably coupled to the sensor and configured to: (a) acquire from the sensor data associated with the measured parameters, (b) store the acquired sensor data in nonvolatile memory, and (c) communicate the stored data wirelessly to a RF reader.