Abstract: A system for the production of a blood component composition is provided. The system includes a centrifuge having a blood reservoir for receiving and separating a blood sample into multiple components; a dispenser disposed outside of the centrifuge having a first collection chamber containing an activation agent and a second collection chamber containing one or more medicinal agents; means for removing a first portion at least one separated blood component from the centrifuge to the first container and a second portion to the second collection chamber, wherein the first collection chamber activates the first portion and stores the resulting clot and thrombin; a filter for separating the thrombin from the clot; and a nozzle for entraining and mixing the thrombin with the second portion containing the one or more medicinal components.

Abstract: Methods and apparatuses for the separation a predetermined cellular component from a bodily fluid or tissue by centrifugation are provided. More specifically, this invention provides a method for the separation and isolation of one or more components, such as stem cells, buffy coat, bone marrow cells, erythrocytes, leukocytes, thrombocytes, serum, fluorescently labeled cells, and magnetically labeled cells, from whole blood, bone marrow, buffy coat, fat tissue, muscle tissue, and nerve tissue by centrifugation, wherein the components are isolated while the centrifuge is rotating.

Abstract: A system for automated operation of a blood separation system controlling the input of blood samples, the separation of blood components, and the discharge of the components. The system includes a blood reservoir and centrifuge for receiving blood samples and separating the blood components. A sensor determines when adequate separation has been achieved and a controller receives signals from the sensor to operate a centrifuge drive assembly to achieve desired separation. Separation may be based on a calibrated rotation time for the centrifuge as measured by a timer. An input pump pumps blood samples to the blood reservoir, and an outlet pump removes separated samples from the blood reservoir. The inlet and outlet pumps are operated by the controller, and the inlet pump may be operated to discharge separated components not collected by the blood separation system, whereby additional sample volume is added for ongoing operation.

Abstract: A rotatable rotor for separating components contained in a fluid, comprising an annular base having a first annular channel and an annular cover having a second annular channel for holding a flexible doughnut-shaped centrifuge bag therebetween. The cover has one or more radially spaced apart concentric indicator lines for monitoring the separation of the components. When the base and cover are superimposed, the first and second channels define an annular interior chamber having an off-centered figure eight configuration. The base and cover each comprise a grooved column axially centered and extending from the base top surface and the cover bottom surface, respectively. The flexible bag comprises inner and outer tubes extending from the core of the bag and which are seated in the column grooves to ensure that the bag is fixably rotatable with the rotor.

Abstract: A flexible, disposable centrifuge bag for receiving and holding a fluid sample, comprising one or more tubes and upper and lower flexible sheets having doughnut shaped configurations. The upper and lower sheets are superimposed and completely sealed together at their outer perimeters to define an outer perimeter of the centrifuge bag. The inner perimeter of the bag defines a central core. The tubes are sandwiched between the upper and lower sheets and extend from the central core of the centrifuge bag. The upper and lower sheets are sealed together at their inner perimeters such that the tubes are sealed between said upper and lower sheets at the inner perimeter. The bag may be used to harvest platelet rich plasma from whole blood in either a batch method or while simultaneously infusing additional aliquots of whole blood into the bag during centrifugation.

Abstract: A centrifugal method of separating and collecting components from a fluid is provided, comprising providing a centrifuge operable at a plurality of rotation speeds and having a mounting assembly for positioning and retaining a disposable collection assembly relative to the centrifuge at the rotation speeds; mounting a separation assembly comprising a number of collection chambers in the mounting assembly, wherein each of the collection chambers include an outer, conical-shaped collection portion with a port for providing a fluid pathway for the fluid into and out of the collection chambers and wherein the mounting includes fluidically connecting the ports with a fluid tube; connecting a fluid source to the fluid tube; rotating the centrifuge at a fill speed; and operating the fluid source to supply the fluid to the fluid tube, whereby the fluid is concurrently supplied in substantially equal volumetric and component density quantities to each of the collection chambers.

Abstract: A system for automated operation of a blood separation system controlling the input of blood samples, the separation of blood components, and the discharge of the components. The system includes a blood reservoir and centrifuge for receiving blood samples and separating the blood components. A sensor determines when adequate separation has been achieved and a controller receives signals from the sensor to operate a centrifuge drive assembly to achieve desired separation. An input pump pumps blood samples to the blood reservoir, and an outlet pump removes separated samples from the blood reservoir. The inlet and outlet pumps are operated by the controller, and the inlet pump may be operated to discharge separated components not collected by the blood separation system, whereby additional sample volume is added for ongoing operation.

Abstract: An extracorporeal blood processing system including a disposable assembly that has integral fluid passageways. A blood removal conduit and a blood return conduit are interconnected with the integral fluid passageways. A diaphragm is mounted in the disposable assembly and is removably attachable to a sensor via a number of connection devices. In one embodiment, the sensor may include a transducer that is capable of measuring the force exerted on the diaphragm. The corresponding force may be correlated to a pressure of fluid in either the blood removal conduit and/or the blood return conduit.

Abstract: A system for the production of a blood component composition is provided. The system includes a centrifuge having a blood reservoir for receiving and separating a blood sample into multiple components; a dispenser disposed outside of the centrifuge having a first collection chamber containing an activation agent and a second collection chamber containing one or more medicinal agents; means for removing a first portion at least one separated blood component from the centrifuge to the first container and a second portion to the second collection chamber, wherein the first collection chamber activates the first portion and stores the resulting clot and thrombin; a filter for separating the thrombin from the clot; and a nozzle for entraining and mixing the thrombin with the second portion containing the one or more medicinal components.

Abstract: A system for the production of autologous thrombin, comprising a centrifuge including a blood reservoir for receiving and separating an autologous anticoagulated blood sample having multiple inactive blood components and means for removing at least one of said inactive blood components upon separation, and a dispenser having at least two collection chambers for receiving said at least one of said inactive blood components, wherein a first collection chamber activates a first portion of said inactive blood component and stores the resulting coagulated blood component comprising a clot and said autologous thrombin.

Abstract: A centrifuge system with an externally positioned sensor assembly for detecting the separation of components in a fluid sample, such as platelets in a blood sample. The system includes a centrifuge with a drive portion and a rotor portion with a sample reservoir or centrifuge bag for receiving and containing a fluid sample during rotation of the rotor portion. An external sensor assembly is positioned relative to the centrifuge to direct a radiation beam from a radiation source through the rotor portion and the centrifuge bag and to allow a detector to receive the lower-intensity radiation beams at a location external to the rotor portion. In one embodiment, the rotor portion is fabricated from a transparent material and extends radially outward from the sides of the drive portion to allow the radiation source and detector to be positioned externally on opposing sides of the extending rotor portion.

Abstract: A flexible, disposable centrifuge bag for receiving and holding a fluid sample, comprising one or more tubes and upper and lower flexible sheets having doughnut shaped configurations. The upper and lower sheets are superimposed and completely sealed together at their outer perimeters to define an outer perimeter of the centrifuge bag. The inner perimeter of the bag defines a central core. The tubes are sandwiched between the upper and lower sheets and extend from the central core of the centrifuge bag. The upper and lower sheets are sealed together at their inner perimeters such that the tubes are sealed between said upper and lower sheets at the inner perimeter. The bag may be used to harvest platelet rich plasma from whole blood in either a batch method or while simultaneously infusing additional aliquots of whole blood into the bag during centrifugation.

Abstract: A rotatable rotor for separating components contained in a fluid, comprising an annular base having a first annular channel and an annular cover having a second annular channel for holding a flexible doughnut-shaped centrifuge bag therebetween. The cover has one or more radially spaced apart concentric indicator lines for monitoring the separation of the components. When the base and cover are superimposed, the first and second channels define an annular interior chamber having an off-centered figure eight configuration. The base and cover each comprise a grooved column axially centered and extending from the base top surface and the cover bottom surface, respectively. The flexible bag comprises inner and outer tubes extending from the core of the bag and which are seated in the column grooves to ensure that the bag is fixably rotatable with the rotor.

Abstract: A system for automated operation of a blood separation system controlling the input of blood samples, the separation of blood components, and the discharge of the components. The system includes a blood reservoir and centrifuge for receiving blood samples and separating the blood components. A sensor determines when adequate separation has been achieved and a controller receives signals from the sensor to operate a centrifuge drive assembly to achieve desired separation. Separation may be based on a calibrated rotation time for the centrifuge as measured by a timer. An input pump pumps blood samples to the blood reservoir, and an outlet pump removes separated samples from the blood reservoir. The inlet and outlet pumps are operated by the controller, and the inlet pump may be operated to discharge separated components not collected by the blood separation system, whereby additional sample volume is added for ongoing operation.

Abstract: A centrifugal method, and corresponding system, for processing blood to collect platelet rich plasma. A separation chamber is filled with blood from a fill syringe by rotating the separation chamber at a fill rotation rate and pumping the blood from the fill syringe. A soft spin is used to initially separate red blood cells from platelets by spinning the separation chamber at a soft spin rate. A percentage of the blood is drawn from the separation chamber back into the fill syringe to remove separated red blood cells. A second portion of the separated blood is drawn from the separation chamber until a red blood cell/platelet interface is detected. A hard spin is performed by spinning the separation chamber at a higher rate and connecting tubing is cleared of red blood cells by drawing a predetermined clearing volume. The platelet rich plasma is then collected in the collection syringe.

Abstract: A centrifugal method of separating and collecting components from a fluid is provided, comprising providing a centrifuge operable at a plurality of rotation speeds and having a mounting assembly for positioning and retaining a disposable collection assembly relative to the centrifuge at the rotation speeds; mounting a separation assembly comprising a number of collection chambers in the mounting assembly, wherein each of the collection chambers include an outer, conical-shaped collection portion with a port for providing a fluid pathway for the fluid into and out of the collection chambers and wherein the mounting includes fluidically connecting the ports with a fluid tube; connecting a fluid source to the fluid tube; rotating the centrifuge at a fill speed; and operating the fluid source to supply the fluid to the fluid tube, whereby the fluid is concurrently supplied in substantially equal volumetric and component density quantities to each of the collection chambers.

Abstract: A blood centrifuge with a drive assembly for transmitting an input rotation speed to a rotor with a sample reservoir at a desired rotation ratio. The drive assembly includes a base and an outer shell mounted to the base to rotate at an input rate. A bottom pulley is rigidly mounted to the base and attached to the outer shell with bearings. A top pulley is mounted to a center shaft of the outer shell to rotate with the outer shell about the central axis of the centrifuge. An internal drive belt is provided to transmit the rotation to the top pulley via a pair of transversely mounted idler pulleys that rotate with the outer shell. The top pulley is thus rotated at twice the input rate but in the same direction. A rotor assembly with the sample reservoir is attached to the top pulley to separate blood components.

Abstract: A method of harvesting platelet rich plasma from whole blood, comprising adding an aliquot of blood via the inlet tube of a rotating flexible centrifuge bag comprising inlet and outlet tubes sandwiched between doughnut shaped flexible sheets sealed together at the outer and inner perimeters. The whole blood separates radially into fractions. The distal end of the outlet tube is in flow communication with a desired fraction. The desired fraction is removed from the rotating bag via the outlet tube and withdrawal is terminated when an undesired fraction is detected to be near the distal end of the outlet tube. An alternative method comprises adding an aliquot of blood via the inlet channel of a rigid centrifuge container, said container having an interior collection chamber for receiving said whole blood and having a generally off-centered figure eight-shaped side cross-sectional configuration.

Abstract: A centrifuge system with a temperature control system for controlling the temperature of fractions removed or output from the centrifuge to a collection chamber. In one embodiment, the centrifuge system provides an integral heater element operable by a temperature controller to control the temperature of the collection chamber or dispenser assembly. A temperature sensor is provided to allow the temperature controller to accurately monitor the temperature of the fraction held in chambers or syringes in the dispenser assembly. In a more particular embodiment, the centrifuge system is utilized to separate and extract platelets from blood samples. The heater element is positioned adjacent collection syringes in the dispenser assembly and selectively operated to maintain the temperature of the platelets in the collection syringes within an activation temperature range to activate the platelets and facilitate creation of autologous platelet gel.

Abstract: A centrifuge rotor for separating components contained in a fluid, comprising an annular base having a first annular channel and an annular cover having a second annular channel for holding a flexible, doughnut-shaped centrifuge bag therebetween. When the base and the cover are superimposed, the first and second channels define an annular interior chamber having an off-centered figure eight configuration. The base and cover each comprise a grooved column axially centered and extending from the base top surface and the cover bottom surface, respectively. The flexible bag comprises inner and outer tubes which extend from the central core of the bag and which are seated in the column grooves to ensure that the bag is fixably rotatable with the rotor.