Abstract: Clamps and methods are disclosed for clamping portions of fluid containers and displacing fluid from portions of fluid containers. In one embodiment, a clamp has a first jaw having a photopermeable main body portion and a second jaw. The first and second jaws are operatively associated so that at least one jaw, or both jaws, may be moved between clamped and released positions. The clamp is sized to receive a portion of a fluid container and displace fluid in the fluid container from a clamped region of the fluid container when the first and/or second jaw(s) are in the clamped position. The photopermeable main body portion(s) of the first and/or second jaw(s) allow some light to reach the clamped region of the fluid container during photoradiation to inactivate pathogens in the fluid. Various clamp embodiments and assemblies having lock members and interlocks are also disclosed herein.

Abstract: A centrifugal fluid separation system is disclosed for centrifugally separating a composite fluid into components thereof. This centrifugal separation system includes at least a centrifugal rotor which has a composite fluid containment area, a fluid flow channel/tubing and at least one separated component collection area defined therein. A composite fluid to be separated is delivered to the fluid containment area where under centrifugal forces the composite fluid is separated into components and then from which a component travels through an outlet channel to a respective separated component fluids flowing therethrough. A centrally disposed pump is also provided to move the separated component(s) to the collection area(s). Optical sensing of the interface of the separated fluid components may be used with a clamp to stop flow. A disposable bag and tubing system is also disclosed for use with reusable rotor devices.

Abstract: An apparatus for irradiating blood or blood products, preferably with ultra violet or visible light, to reduce contaminants in the blood or blood products. A removable radiometer having light integrating chambers detects the light intensity, allowing the radiation characteristics of the apparatus to be calibrated. A control circuit uses the measurements to control the delivery of an effective dose of illumination to blood or blood products in a bag or container. One or more light integrating optical chambers in the radiometer allow a single light sensor to sense light across an entire field. Thermistors in the irradiating apparatus or the radiometer or both sense the temperature of photo sensors. The control circuit compensates for temperature-dependant variations in the output of the photo sensors.

Abstract: This invention is directed toward a method of pathogen inactivating whole blood. The steps include collecting whole blood from a donor into a bag; illuminating the whole blood with light at a sufficient energy so that an alloxazine photosensitizer present in the whole blood may be photolyzed to inactivate any pathogens which may be present in the whole blood; and storing the pathogen inactivated whole blood. The invention also includes a method of separating the pathogen inactivated whole blood into components.

Abstract: Apparatus and method for balancing a centrifuge having interconnected hydraulic chambers in containers on a rotor, each container being adapted to receive a composite fluid, comprising transferring, by the rotation of the rotor, hydraulic liquid from a source to the interconnected hydraulic chambers to balance the centrifuge.

Abstract: The present invention is related to pre-connected disposable sets including a pre-connected bag containing a photosensitizer for use in a blood separation and pathogen inactivation procedure.

Abstract: Methods and apparatuses are provided for reduction of pathogens in fluids containing blood products. Preferred methods include the steps of adding an effective, non-toxic amount of a photosensitizer such as riboflavin to the blood product and exposing the fluid to light having a peak wavelength.

Abstract: A method for washing multiple units of blood product including providing a centrifuge having a wash cell for each unit of blood product, balancing the centrifuge to accommodate for differences in the wash cells, and transferring supernatant including any wash solution from each unit of blood product on the centrifuge.

Abstract: The present invention provides thermoplastic tubes, thermoplastic melting plates, thermoplastic tube connecting apparatus, and methods for using the same.

Abstract: A method for separating a composite fluid into components in a centrifugal fluid separation system. The system includes a rotor that has a composite fluid containment area, an inlet channel, a peripheral separation channel, outlet channels and separated component collection areas, which together form a processing area. The separation channel may be semi-spiraled. The inlet channel may connect to the center of the separation channel and an outlet channel may connect to each end of the separation channel. The outlet channels have different heights. The ends of the separation channels may have different heights. The separation channels may have extensions. The rotor may have multiple processing areas. The collection areas may be pockets slanted radially outwardly and downwardly. A motor may produce a rotating magnetic field, which co-acts with a magnetically reactive material in the rotor. A disposable bag and tubing system may be used in a processing area of the rotor.

Abstract: The method separates a composite fluid, such as blood, into the components thereof in a centrifugal separation device. The fluid is delivered to a fluid receiving area in a rotor from which area the fluid travels through a radial inlet channel having an inlet channel height to a proximal end of a circumferential fluid separation channel. Near a distal end of the separation channel, fluid components travel into distinct first and second outlet channels. The height of the first channel is greater than the height of the more distal second channel. The inlet channel height is greater than the height of the first channel. The rotor may be balanced by axially symmetrical sets of inlet channels, separation channels and outlet channels or by a balance channel connected to the separation channel but displaced from the outlet channels.

Abstract: A mixing system, apparatus and/or method. Pathogen reduction of and/or mixing storage solutions into blood or blood components are useful purposes for these. Squeezing or clapping devices may be used to activate the mixing process, as may rotational devices or laterally movable, rotational and/or orbital devices. Constriction elements may also be used to create useful vortex mixing actions. Photoradiation may be provided while the components continue to be mixed together for pathogen reduction of blood or blood components.

Abstract: A centrifugal fluid separation system is disclosed for centrifugally separating a composite fluid into components thereof. This centrifugal separation system includes at least a centrifugal rotor which has a composite fluid containment area, a fluid flow channel/tubing and at least one separated component collection area defined therein. A composite fluid to be separated is delivered to the fluid containment area where under centrifugal forces the composite fluid is separated into components and then from which a component travels through an outlet channel to a respective separated component fluids flowing therethrough. A centrally disposed pump is also provided to move the separated component(s) to the collection area(s). Optical sensing of the interface of the separated fluid components may be used with a clamp to stop flow. A disposable bag and tubing system is also disclosed for use with reusable rotor devices.

Abstract: Methods and apparatuses are provided for inactivation of pathogens in fluids containing blood products. Preferred methods include the steps of adding an effective, nontoxic amount of a photosensitizer such as riboflavin to the blood product and exposing the fluid to light having a peak wavelength.

Abstract: A method for separating a composite fluid into components in a centrifugal fluid separation system. The system includes a rotor that has a composite fluid containment area, an inlet channel, a peripheral separation channel, outlet channels and separated component collection areas, which together form a processing area. The separation channel may be semi-spiraled. The inlet channel may connect to the center of the separation channel and an outlet channel may connect to each end of the separation channel. The outlet channels have different heights. The ends of the separation channels may have different heights. The separation channels may have extensions. The rotor may have multiple processing areas. The collection areas may be pockets slanted radially outwardly and downwardly. A motor may produce a rotating magnetic field, which co-acts with a magnetically reactive material in the rotor. A disposable bag and tubing system may be used in a processing area of the rotor.

Abstract: The method separates a composite fluid, such as blood, into the components thereof in a centrifugal separation device. The fluid is delivered to a fluid receiving area in a rotor from which area the fluid travels through a radial inlet channel having an inlet channel height to a proximal end of a circumferential fluid separation channel. Near a distal end of the separation channel, fluid components travel into distinct first and second outlet channels. The height of the first channel is greater than the height of the more distal second channel. The inlet channel height is greater than the height of the first channel. The rotor may be balanced by axially symmetrical sets of inlet channels, separation channels and outlet channels or by a balance channel connected to the separation channel but displaced from the outlet channels.

Abstract: A centrifugal fluid separation system separates a composite fluid into components. The system includes a rotor that has a composite fluid containment area, an inlet channel, a peripheral separation channel, outlet channels and separated component collection areas, which together form a processing area. The separation channel may be semi-spiraled. The inlet channel may connect to the center of the separation channel and an outlet channel may connect to each end of the separation channel. The outlet channels have different heights. The ends of the separation channels may have different heights. The separation channels may have extensions. The rotor may have multiple processing areas. The collection areas may be pockets slanted radially outwardly and downwardly. A motor may produce a rotating magnetic field, which co-acts with a magnetically reactive material in the rotor. A disposable bag and tubing system may be used in a processing area of the rotor.

Abstract: A centrifugal separation device separates a composite fluid, such as blood, into the components thereof. The fluid is delivered to a fluid receiving area in a rotor from which area the fluid travels through a radial inlet channel having an inlet channel height to a proximal end of a circumferential fluid separation channel. Near a distal end of the separation channel, fluid components travel into distinct first and second outlet channels. The height of the first channel is greater than the height of the more distal second channel. The inlet channel height is greater than the height of the first channel. The rotor may be balanced by axially symmetrical sets of inlet channels, separation channels and outlet channels or by a balance channel connected to the separation channel but displaced from the outlet channels.

Abstract: This invention provides methods and compositions for using nitric oxide in a photoradiation pathogen inactivation process for whole blood and blood components to improve pathogen kill and to improve preservation of the quality of the blood components. This invention provides methods for using nitric oxide in combination with oxygen, photosensitizers, quencher and/or glycolysis inhibitor, and compositions comprising blood components decontaminated by these methods. Nitric oxide is provided using nitric oxide gas, or nitric oxide generators such as L-arginine, and/or N-acetyl-cysteine. This invention also provides compositions suitable for photoradiation pathogen inactivation that include fluid comprising a blood component, a photosensitizer, and dissolved nitric oxide. This invention provides decontamination systems useful for performing the methods of this invention and methods for making the decontamination systems.

Abstract: Methods and apparatuses are provided for inactivation of pathogens in fluids containing blood products. Preferred methods include the steps of adding an effective, nontoxic amount of a photosensitizer such as riboflavin to the blood product and exposing the fluid to light having a peak wavelength.