CA2103914A1 - Centrifugal processing system with direct access drawer - Google Patents

Centrifugal processing system with direct access drawer

Info

Publication number
CA2103914A1
CA2103914A1 CA002103914A CA2103914A CA2103914A1 CA 2103914 A1 CA2103914 A1 CA 2103914A1 CA 002103914 A CA002103914 A CA 002103914A CA 2103914 A CA2103914 A CA 2103914A CA 2103914 A1 CA2103914 A1 CA 2103914A1
Authority
CA
Canada
Prior art keywords
chamber
centrifuge
base
assembly
drawer
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Abandoned
Application number
CA002103914A
Other languages
French (fr)
Inventor
Warren P. Williamson, Iv
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Baxter International Inc
Original Assignee
Individual
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Individual filed Critical Individual
Publication of CA2103914A1 publication Critical patent/CA2103914A1/en
Abandoned legal-status Critical Current

Links

Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B04CENTRIFUGAL APPARATUS OR MACHINES FOR CARRYING-OUT PHYSICAL OR CHEMICAL PROCESSES
    • B04BCENTRIFUGES
    • B04B5/00Other centrifuges
    • B04B5/04Radial chamber apparatus for separating predominantly liquid mixtures, e.g. butyrometers
    • B04B5/0407Radial chamber apparatus for separating predominantly liquid mixtures, e.g. butyrometers for liquids contained in receptacles
    • B04B5/0428Radial chamber apparatus for separating predominantly liquid mixtures, e.g. butyrometers for liquids contained in receptacles with flexible receptacles
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B04CENTRIFUGAL APPARATUS OR MACHINES FOR CARRYING-OUT PHYSICAL OR CHEMICAL PROCESSES
    • B04BCENTRIFUGES
    • B04B5/00Other centrifuges
    • B04B5/04Radial chamber apparatus for separating predominantly liquid mixtures, e.g. butyrometers
    • B04B5/0442Radial chamber apparatus for separating predominantly liquid mixtures, e.g. butyrometers with means for adding or withdrawing liquid substances during the centrifugation, e.g. continuous centrifugation
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B04CENTRIFUGAL APPARATUS OR MACHINES FOR CARRYING-OUT PHYSICAL OR CHEMICAL PROCESSES
    • B04BCENTRIFUGES
    • B04B7/00Elements of centrifuges
    • B04B7/02Casings; Lids
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B04CENTRIFUGAL APPARATUS OR MACHINES FOR CARRYING-OUT PHYSICAL OR CHEMICAL PROCESSES
    • B04BCENTRIFUGES
    • B04B5/00Other centrifuges
    • B04B5/04Radial chamber apparatus for separating predominantly liquid mixtures, e.g. butyrometers
    • B04B5/0442Radial chamber apparatus for separating predominantly liquid mixtures, e.g. butyrometers with means for adding or withdrawing liquid substances during the centrifugation, e.g. continuous centrifugation
    • B04B2005/045Radial chamber apparatus for separating predominantly liquid mixtures, e.g. butyrometers with means for adding or withdrawing liquid substances during the centrifugation, e.g. continuous centrifugation having annular separation channels
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B04CENTRIFUGAL APPARATUS OR MACHINES FOR CARRYING-OUT PHYSICAL OR CHEMICAL PROCESSES
    • B04BCENTRIFUGES
    • B04B5/00Other centrifuges
    • B04B5/04Radial chamber apparatus for separating predominantly liquid mixtures, e.g. butyrometers
    • B04B5/0442Radial chamber apparatus for separating predominantly liquid mixtures, e.g. butyrometers with means for adding or withdrawing liquid substances during the centrifugation, e.g. continuous centrifugation
    • B04B2005/0492Radial chamber apparatus for separating predominantly liquid mixtures, e.g. butyrometers with means for adding or withdrawing liquid substances during the centrifugation, e.g. continuous centrifugation with fluid conveying umbilicus between stationary and rotary centrifuge parts

Abstract

A drawer-mounted (36) centrifuge (12) provides easy access for loading and unloading disposable processing elements (22). The centrifuge also includes an umbilicus holder (86) that moves between an operating position and an out-of-way position as the drawer opens and closes.

Description

21 ~591~ ¦

Centri~ug~l Pro~e~si~g 8ystem ~ith Direct Acce~s Drawer Field of the Invention The invention relates to centrifugal pro-cessing systems and apparatus.
Back~round of th~ Invention Today people routinely separate whole blood lOby centrifugation into its various therapeutic compo-nents, such as red blood cells, platelets, and plasma.
Conventional blood processing methods use durable centrifuge equipment in association with single use, sterile processing systems, typically made 15of plastic. The operator loads the disposable systems upon the centrifuge before processing and removes them afterwards.
Conventional centrifuges often do not permit easy access to the areas where the disposable systems 20reside during use. As a result, loading and unloading operations can be time consuming and tedious.
Disposable systems are often preformed into desired shapes to simplify the loading and unloading : process. However, this approach is often counterpro-25ductive, as it increases the cost of the disposables.
~u~mary o~ the Invsntion The invention provides improved centrifugal processing systems that provide easy access to the rotating parts of the centrifuge for loading and un-. .

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W093/t2887 PCT/US92/11216 loading disposable processing components. The inven-tion achieves this objective without complicating or increasing the cost of the disposable components. The invention allows relatively inexpensive and straight-forward disposable components to be used.
One aspect of the inv2ntion provides a sys-tem that includes a centrifuge assembly carried by a frame. The frame encloses an interior area. The cen-trifuge assembly including a chamber and a mechanism for rotating the chamber about an axis.
According to this aspect of the invention, a base supports the centrifuge assembly on the frame.
The base incl~des a mechanism for moving the base and, with it, the entire centrifuge assembly on the frame.
The movable base allows user to locate the entire cen-trifuge assembly within the interior area of the frame, thereby blocking access to the centrifuge as-sembly during a processing procedure. The movable base also allows the user to locate the entire centri-fuge assembly outside the interior area of the frame, thereby permitting access to the centrifuge assembly at the end of a processing procedure.
This arrangement fully encloses the centri-fuge assembly when necessary during processing opera-tions. Still, the centrifuge assembly can be made readily accessible to the user after the processing operations are over. For example, once the centrifuge assembly is located outside the frame, the user can quickly and easily handle the disposable processing elements that must be installed and then removed be-fore and after each processing operation. This elimi-nates the need for expensive processing elements spe-cially design to be fitted into tight and awkward quarters.
In a preferred embodiment, the base moves in .-W093/12887 PCI/US9~/11216 21~391 i a direction generally perpendicular to the rotation axis of the chamber in a drawer that can be opened and closed. The drawer carries the centrifuge assembly, allowing the user to locate the centrifuge assembly in its first position when the drawer is closed and to locate the centrifuge assembly in its second position when the drawer is opened.
In a pref~rred embodiment, force dampening mounts isolate the base from vibration and oscillation caused by the rotating chamber. In this arrangement, the entire isolated mass of the centrifuge assembly is accessible to the user.
Another aspect of th~ invention provides movable centrifuge assembly as just described having a processing element that is removably insertable into the processing chamber. An umbilicus conveys fluid into the processing element to undergo centrifugal separation during rotation of the chamber.
According to this aspect of the invention, the centrifuge assembly includes a holder that releasably receives the umbilicus. The holder assumes an operating position that orients the umbilicus in a prescribed relationship with the centrifuge assembly t during processing operations. The holder also as-sumes an nonoperating position spaced away from cen-trifuge assembly that allowing user access to the chamber.
In this arrangement, as the base and, with it, the centrifuge assembly and holder means are moved to the enclosed position within the f_ame, the holder moves toward its operating position, ready for pro-cessing operations. Likewise, as the base moves to - its exposed position outsïde the frame, the holder moves toward its nonoperating position, opening up access to the chamber.

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W093t12887 PCT/US92/11216 2~ 0391~

In a preferred embodiment, a locking mecha-nism retains the holder in its operating position when the base is in its enclosed position. ~he locking mechanism is freed in response to movement of the base from its enclosed position toward its exposed posi-tion.
In a preferred embodiment, the holder, like the centrifuge assembly itself, is carried on the force dampening mounts, thereby forming a part of the is~lated mass of the centrifuge.
The features and advantages of the invention will become apparent from the following descrlption, the drawings, and the claims.
8rief De3cription of the Drawings Fig. l is a side ele~ation view of a pro-cessing system that embodies the features of the in-vention, with the drawer carrying the rotating components of the centrifuge assembly shown in its open position for loading the associated fluid processing chamber;
Fig. 2 is a front perspective view of the processing system shown in Fig. l, with the drawer closed as it would be during normal processing operations;
Fig. 3 is an exploded perspective view of the drawer and rotating components of the centrifuge assembly;
Fig. 4 is an enlarged perspective view of the rotating components of the centrifuge assembly shown in its suspended operating position;
Fig. 5 is a side sectional view of the ro-tating components of the centrifuge assembly taken generally along line 5-5 in Fig. 4;
Fig. 6 is a side elevation view, with por-tions broken away and in section, of the rotating com-.:. : ~ : . . ;: . .
- . . ~: . :. :
.. . - , ... . . .. . . .

-: 2~3~1'1 ponents of the centrifuge assembly housed within the drawer, which is shown closed;
Fig. 7 is an enlarged side elevation view of the umbilicus mounts associated with the centrifuge assembly;
Fig. 8 is an enlarged perspective view of the zero omega holder and associated upper umbilicus mount;
Fig. BA is an enlarged perspective view of 10an alternative embodiment of the zero omega holder, with the associated latch member in its upraised posi-tion;
Fig. 8~ is an enlarged perspective view of the alternative embodiment of the zero omega holder 15shown in Fig. 8A, with the associated latch member in its lowered position;
Fig. 9 is a top section view of the upper umbilicus block taken generally along line 9-9 in Fig.
7;
20Fig. lr ~s a schematic view of the drive controller for th~ otating components of the centri-fuge assembly;
Fig. 11 is a side elevation view, with por-tions broXen away and in section, of the rotating com-25ponents of the centrifuge assembly housed within the drawer, which is shown in a partially opened condi-tion;
Fig. 12 is a side elevation view, with por-tions broken away and in section, of the rotating com-30ponents of the centrifuye assembly housed within the drawer, which is shown in a fully opened condition;
Fig. 13 is a side elevation view, with por-tions broken away and in section, of the rotating com-ponents of the centrifuge assembly housed within the 35drawer, which is shown in a fully opened condition, . .

., W093/1~87 PCT/US92/1 1216 with the centrifuge assembly upright and opened for loading and unloading the associated processing cham-ber;
Fig. 14 is a schematic view of the drawer interlocks associated with the centrifuge assembly;
Fig. 15 is an enlarged perspective view of the rotating components of the centrifuge assembly shown in its upraised position for loading and unload-ing the associated processing chamber;
Fig. 16 is a perspective exploded view of the locking pin component of the swinging lock assem-bly that pivots the rotating components of the centrifuge assembly between operating and upraised positions;
Fig. 17 is a perspective exploded view of ~ the entire the swinging lock assembly that pivots the ; rotating components of the centrifuge assembly between its operating and upraised positions;
Figs. 18A; 18B; and 18C are a series of side section views showing the operation of the swinging lock assembly;
Fig. 19 is a side sectional view of the ro-tating components of the centrifuge assembly when in its upraised position, taken generally along line 19-19 in ~ig. 15;
Fig. 20 is a side sectional view of the ro-tating components of the centrifuge assembly when in its upraised and open position;
Fig. 21 is an enlarged and exploded perspec-tive view, with portions broken away and in section, of a mechanism for mo~ing and securing the centrifuge assembly in its open and closed positions, as well as clamping the umbilicus near the processing chamber;
Fig. 22 is a side section view, taken gener-ally along line 22-22 in Fig. 21~ of the latch member . .
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, WO93/12~7 PCT/US92/11216 - 21~391 1 associated wi~h the mechanism show~ in Fig. 21;
Figs. 23 and 24 are side section views show-ing the operation of the latch member associated with the mechanism shown in Fig. 21;
Fig. 25 is an enlarged and exploded perspec-tive view, with portions broken away and in section, of an alternative mechanism for moving and securing the centrifuge assem~ly in its open and closed positions, as ~ ll as clamping the umbilicus near the processing ch~ or;
Fig ~6 and 27 are side sectional views showing the c ation of the mechanism shown in Fig.
25;
Fis 3 is a perspective view of the pro-cessing chamb~ as it is being wrapped onto the cen-trifuge spool prior to use;
Fig. 29 is a perspective view of the pro-cessing chamber wrapped on the centrifuge spool for use;
Fig. 30 is a perspective view, with portions broken away, of the centrifuge spool holding the pro-cessing chamber and in position within the centrifuge bowl for use;
Fig. 31 is a top section view, taken gener-ally along line 31-31 of Fig. 30, of the centrifuge spool holding the processing cham~er and in position within the centrifuge bowl for use; and Fig. 32 is an exploded perspective view of an interchangeable centrifuge spool assembly on which a processing chamber can be mounted;
Description of the Preferred Embodiments Figs. 1 and 2 show a centrifugal processing system 10 that embodies the features of the invention.
The system 10 can be used for processi~g various flu-~5 ids. The system 10 is particularly well suited for . .

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WO 93f 12887 PCT/US92/11216 , , 2 ~ ~ 3 9 1~ - 8 -processing whole blood and other suspensions of cellu-lar materials that are subject to trauma. Ac-cordingly, the illustrated embodime~t shows the system I0 used for this purpose.
The system 10 includes a centrifuge assembly 12 and an associated fluid processing assem~ly 14.
The centrifuge assembly 12 is a durable equipment item. The fluid processing assembly 14 is a single use, disposable item that the user loads on the cen-trifuge assembly 12 before beginning a processing pro-cedure (as Fig. 1 generally shows) and removes from the centrifuge assembly 12 upon the completing the procedure.
The centrifuge assembly 12 comprises a centrifuge 16 mounted for rotation within a cabinet 18. The user maneuvers and transports the cabinet 18 upon the associated wheels 20. It should be appreci-ated that, due to its compact form, the centrifuge as-sembly 12 also could be made as a tabletop unit.
As Figs. 1 and 2 show, the cabinet 18 includes a sliding drawer 36 that holds the centrifuge 16. As Fig. 1 shows, the user opens the drawer 36 to enter the centrifuge 16 for inserting and removing the processing chamber 22. As Fig. 2 shows, the user ; 25 closes the drawer 36 when conducting a processing op-- eration.
The processing assembly 14 comprises a pro-cessing chamber 22 mounted on the centrifuge 1~ for rotation (as Fig. 1 shows). An associated fluid cir-cuit 24 conveys fluids to and from the processing chamber 22. The fluid circuit 24 has several fluid containers 26. As Fig. 2 shows, in use, the contain-ers 26 hang from a support pole outside the cabinet 18~ The ~luid circuit 24 transits several peristaltic pumps 28 and clamps 30 on the face of the cabinet 18.

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:' 2la3sl4 The fluid circuit 24 enters an access opening l00 leading to the processing chamber 22 mounted within the cabinet l~. In the illustrated environ~ent, the fluid circuit 24 preconnects the processing chamber 22 with the containers 26, forming an integral, sterile unit closed to communication with the atmosphere.
The centrifuge assembly 12 includes a pro-cessing controller 32, various details of which are shown in Figs. lO and 14. The processing controller 32 coordinates the operation of the centrifuge 16.
~he processing controller 32 preferably uses an in-put/output terminal 34 to receive and display informa-tion relating to the processing procedure.
The following sections disclose further de-tails of construction of the centrifuge assembly 12, the processing assembly 14, and processing controller 32.

I. T~E CENTRIF~GR_ASBEMB~Y
; 20 A. ~he one Omeq~ Platform an~ Two Omeqa Chamber As Fig. 3 shows, the centrifuge 16 includes a base 42 that supports a plate 45 mounted upon flexible isolation mounts 44. The flexible mounts 44 structur-ally isolate the components mounted on the plate 45 ~; 25 from the rest of the centrifuge 16, by dampening vi-bration and oscillation caused by these plate-mounted components. The components mounted on the plate 45 make up the isolated mass of the centrifuge 16.
A nonrotating outer housing or bucket 46 is mounted on the plate 45. The bucket 46 encloses a stationary platform 48, which in turn supports the rotating components of the centrifuge 16.
As Figs. 4 and 5 show in greater detail, the ro-tating components include a centrifuge yoke assembly 50 and a centrifuge chamber assembly 52. The yoke : - : :: :, , , , . : : ,:: . .: : :

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W093/t2X87 PCT/US92/11216 2~03914 ~ 1 assembly 50 rotates upon the platform 48 on a first drive shaft 54. The chamber assembly 52 rotates on the yoke assembly 50 on a second drive shaft 5~. The rotating chamber assembly 52 carries the processing s chamber 22.
The yoke assembly 50 includes a yoke base 58, a pair of upstanding yoke arms 60, and a yoke cross mem-ber 62 mounted between the arms 60. The base 58 is attached to the first drive shaft 54, which spins on a beari~g element 64 about the stationary platform 48.
A first electric drive 66 rotates the yoke assembly 50 on the first drive shaft 54.
The chamber assembly 52 is attached to the second drive shaft 56, which spins on a bearing element 68 in the yoke cross member 62. ~he second drive shaft 56 and the bearing element 68 spin as a unit on ball bearings 70. A second electric drive 72 rotates the centrifuge chamber assembly 52 on the second drive shaft.
The first electric drive 66 and the -second ; electric drive 72 each comprises a permanent magnet, ; brushless DC motor. As Fig. 5 shows, the stationary platform holds the field coils 74 of the first motor ` 66, while the yoke base 58 comprises the armature or rotor of the first motor 66. The yoke cross member 62 holds the field coils 74 of the second motor 72, while the chamber assembly 52 comprises the associated ar-mature or rotor.
- In the illustrated and preferred embodiment, the first electric motor 66 spins the yoke assembly 50 at a predetermined speed of rotation (which will be called "one omega"). The second electric motor 72 spins the chamber assembly 52 at the same speed of rotation as the first electric motor 66 in the same direction and about the same axis as the spinning yoke .: - :. : . .
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assembly 50. As a result, when viewed from a station-ary (i.e., non-rotating or "zero omega"~ position, the chamber assembly 52 spins at twice the rotational speed of the yoke assembly 50 (which will be called s "two omega").

B. ~he ~bilicus Mounts at Zoro, ODe. an~ Two ~me~a As Figs. 6 to 9 show, the fluid circuit 24 join-ing the processing chamber 22 and the processing con-tainers 26 comprises separate tubes 74 joined to form an umbilicus 76. Fluids pass to and from the proces-sing chamber 22 through these tubes 74.
As Figs. 6 and 7 best show, the centrifuge 16 in-cludes several umbilicus mounts 78, 80, 82, and 84 positioned at spaced apart zero omega, one ome~a, and two omega positions on the centrifuge 16. The mounts 78, 80, 82, and 84 secure the upper, middle, and lower portions of the umbilicus 76, holding it in an in-verted question mark shape during processing operations.
The first umbilicus mount 78 is part of a holder 86 mounted at a zero omega position above and aligned with the rotational axis of the centrifuge 16. The mount 78 holds the upper portion of the umbilicus 76 against rotation at this position.
As Figs. 3 and 6 best show, the zero omega holder 86 includes a support frame 88, which is itself at-tached to the isolation plate 45. The zero omega holder 86 therefore forms a part of the isolated mass of the centrifuge 16.
A pin 90 attaches one end of the zero omega hold-er 86 to the support frame 88. The holder 86 pivots on this pin 90 along the rotational axis of centrifuge 16 ~as generally shown by arrows in Fig. 3). A spring :

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wos3/~87 PCT/U592/11~16 . ' , ~,, 210~91~ ~

92 normally biases the holder 86 nway rom the rotat-ing components 50 and 52 of the centrifuge 16. A so-lenoid operated latch pin 94 normally locks the holder 86 in the operating position shown in Fig. 6. It should be appreciated that, alternatively, the holder 86 can be manually locked in the operating position using a co~ventional over-center toggle mechanism (not shown~ or the like.
The zero omega holder 86 has a roller member 96 ; lO at its opposite end. The roller member 96 rotates on a shaft 98. The roller member 96 is relieved in its mid-portion (see Fig. 8) to receive the umbilicus 76 as it enters the cabinet 18 through an access openiing 100 .
As Figs. 7 and 8 best show, the first umbilicus mount 78 is located next to the roller member 96. The mount 78 comprises a channel in the holder 86 that captures an upper block 102 carried by th~ umbilicus 76. When locked in its operating position (shown in Fig. 6), the zero omega holder 86 applies tension on the umbilicus 76, thereby seating the upper umbilicus block 102 within the mount 78.
In the embodiment illustrated in Figs. 7 to 9, the upper umbilicus block 102 is generally hexagonally shaped. The mount 78 is also configured as a hexagon to mate with the block 102. It should be appreciated that other mating shapes can be used to seat the um-bilicus block 102 within the mount 78.
Figs. 8A and 8B show an alternative embodiment for the zero omega holder 86. Like the holder 86 shown in Figs. 7 and 8, the holder 86' is mounted for pivotal movement on a pin 90' to the support frame 88 (not shown in Figs. 8A and 8B). Also like the holder 86 shown in Figs. 7 and 8, the holder 86' has a roller member 96' and an umbilicus mount 78~ located next to w093/1~7 PCT/US92tll2t6 .-~........................ 21q~lJl it. The functions of these components are as previ-ously described.
Unlike the holder 86' shown in Figs. 7 and 8, the holder 86' includes a mechanism ~or clamping the upper umbilicus block 102 within the mount 78'. While the mechanism can vary, in the illustraSed embodi~ent, it comprises a latch m ber 250 mounted on pins 252 for pivotal movement on ~e holder 86'. Fig. 8A shows the latch member 250 in an upraised position, opening the mount 78' for receiving the upper umbilicus block 102.
Fig. 8B shows the latch member 250 in a lowered posi-tion, covering the mount 78' and retaining the umbili-cus block 102 therein. As Fig. 8B shows, the latch member 250 includes a relieved region that accommo-dates passage of the umbilicus 76 when the latch mem-ber 250 is lowered.
A pair of resilient tabs 256 on the latch member 250 mate within undercuts 258 on the holder 86' to releasably loc~ the latch member 250 in its lowered position. Manually squeezing in the area 260 above the resilient tabs 256 releases them from the under-cuts 258.
The second and third umbilicus mounts 80 and 82 form a part of a one omega holder 104 carried on the yoke cross member 62. The mounts 80 and 82 take the ' form of spaced apart slotted apertures that secure the mid-portion of the umbilicus 76 to the yoke cross mem-ber 62. The mid-portion of the umbilicus 76 carries a pair of spaced apart resilient bushings 106 that snap-fit within the slotted second and third mounts 80 and 82 (see Figs. 4 and 7). The slotted mounts 80 and 82 allow the umbilicus bushings 106 to rotate within them, but otherwise secure the umbilicus 76 as the yoke assembly 50 rotates. The yoke cross member 62 carries a counterweight 103 opposite to the one omega :.,.
: .1 . ~

W093/12X87 PCT/lJS92/11216 21~331~ ~ I

I

holder 104.
The fourth umbilicus mount 84 forms a part of a two omega holder 108 on the processing chamber assem-bly 52. As best shown in Fig 15 and l9, the mount 84 comprises a clamp that captures a lower block ll0 carried by the umbilicus 76. The clamp mount 84 grips the lower block ll0 to rotate the lower portion of the umbilicus 76 as the chamber 22 itself rotates.
In the illustrated embodiment (see Fig. l9), the lower umbilicus block ll0 (like the upper umbilicus block 102) is generally hexagonally shaped. The clamp mount 84 is also configured to mate with the lower block ll0 seated within it. As before pointed out, it ; should be appreciated that other mating shapes can be used to seat the umbilicus block ll0 within the clamp mount 84.
i Further det~ils of the fourth umbilicus mount 84 will be discussed later. ?
The zero omega holder 86 holds the upper portion of the umbilicus in a non-rotating position above the rotating yoke and chamber assemblies 50 and 52. The holder 104 rotates the mid-portion of the umbilicus 76 at the one omega speed of the yoke assembly 50. The -; holder 108 rotates the lower end of the umbilicus 76 at the two omega speed of the chamber assembly 52.
This relative rotation keeps the umbilicus 76 untwist-ed, in this way avoiding the need for rotating seals.
1. ~
C. The One Omeqa/Two Ome~a Driv~ Control The processing controller 32 includes an all-electrical synchronous drive controller 184 for main-taining the desired one omega/two omega relationship between the yoke assembly 50 and the chamber assembly 52~ Fig. l0 shows the details of the drive controller 184.
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W093/12887 PC~/US92~1121$
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As Fig. lO shows, both motors 66 and 72 are three phase motors. Still, double or other multiple phase motors can be used, if desired. In the illustrated three phase arrangement, the drive controller 184 in-cludes a three phase power driver 186. The drive con- j troller 184 also includes a commutation controller 188 for three commutator sensors l90 associated with the first three phase electric ~otor 66.
ThP power driver 186 uses a single slip ring as-sembly 192 that serves the second electric motor 72.
The slip ring assembly 192 includes three slip rings tdesignated RA, RB, and RC in Fig. lO), one associated with each pole of the second ~otor (designated PA, PB, and PC in Fig. lO). The slip rings RA/RB/RC serve as a conducting means for electricity. Alternative con-ducting means, such as a transformer coupling, could be used.
The power driver 186 includes three power feeds (designated FA, FB, and FC in Fig. lO) connected in parallel to the three poles PA/PB/PC of first electric motor 66. The power feeds FA/FB/FC operate the first motor 66 at the preselected constant one omega speed in a closed loop fashion.
The power feeds FA/FBjFC are, in turn, connected in parallel to the three poles PA/PB/PC of the second electric motor 72, each via one slip ring RA/RB/RC.
The slip rings serve as a rotating electrical connec-tor, transferring power between the first motor 66 (operating at constant speed and in a closed loop) and the second motor 72.
Since the poles PA/PB/PC of both motors 66 and 72 are connected directly together in parallel, a phase error will occur whenever the second motor 72 is not synchronous with the first motor 66. The phase error causes $he two motors 66 and 72 to exchange power.
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Depending upon the phase angle between the counter-electromotive force (emf) voltage vector generated by the rotor and the voltage vector of the feed line, the motors 66 and 72 will either transfer power from the feed lines FA/FB/FC to the rotors (through normal mo-tor action) or deliver power from the rotors to a feed line FA/FB/FC (through generator action)~
More particularly, if the rotor of the second motor 72 (spinning the chamber assembly 52) moves ahead of the rotor of the first motor 66 (spinning the yoke assembly 50), the second motor 72 becomes a gen-erator, delivering power to the first motor 66. Be-cause the first motor 66 operates in a closed loop at a constant speed, this power transfer retards the ro-tor of the second motor 72, causing the phase error to disappear.
Similarly, if the rotor of the second motor 72 lags behind the first motor 66, the first motor 66 be-comes a generator, delivering power to the second mo-tor 72. This power transfer advances the rotor of the second motor 72, again causing the phase error to dis-- appear.
This continuous power exchange applies a correc-tive torque on the rotor of the second motor 72 that either advanees or retards the rotor of the second motor 72. In either case, the corrective torque elim-inates any phase error between the first and second motors 66 and 72. This keeps the cecond motor 72 con-tinuously in synch with and operating at the same ro-tational speed as the closed loop, constant speed first motor 66.
This arrangement keeps the chamber assembly 52 spinning, relative to zero omega, at exactly two ome-ga; i.e., twice the one omega speed of the yoke assem-; 35 bly 50.

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WO 9~/12887 PCI~/US92/11216 `~` 21 ~391~1 ~

As the following Table illustrates, a drive controller 184 ~mbodying the above features can be used to maintain virtual any speed ratio between two or more motors.
~3LE 1 N~H~ER OF POLE~ 8P~ED RATIO ~AINTATNED
Motor 1 Motor 2 (Motor 2:Motor 1 2 2 2:1 4 4 2:1 6 6 2:1 8 8 2:1 2 4 3:2 2 6 4:3 4 8 3:2 4 6 5:2 6 2 4:1 ~: 6 4 5:3 The drive controller 184 continuously maintains the desired speed ratio without noisy and heavy geared or belted mechanical mechanisms or without complicat-ed, sensitive electronic feedback mechanisms. The drive controller 184 allows the centrifuge 16 to be small and lightweight, yet reliable and accurate.
:
D. The Centr~fuge Drawer The centrifuge drawer 36 moves the entire iso-lated mass of the centrifuge 16 (carried on the plate 45) across the axis of rotation. The drawer 36 moves the isolated mass between an operating enclosed posi-tion (shown in Figs. 2 and 6) and an opened position accessible to the user (shown in Figs. 1 and 12).
When in its enclosed position, the cabinet 18 shields all sides of the i~olated mass of the centri-fuge 16 during operation. When in its opened posi-tion, the isolated mass of the centrifuge 18 is with-~: . . ,: : , , ' " , .
.

w093tl2~X7PCT/US92/11216 2 1 ~

drawn from the cabinet 18. The user can access all sides of the centrifuge 16 either for maintenance or to conveniently and quickly load and unload the dis-posable processing assembly 14.
5The centrifuge drawer 36 can be constructed in various ways. In the illustrated embodiment (a~ best shown in Fig. 3), the centrifuge ba~e 42 (which 6Up-ports the plate 45 upon the flexible isolation mounts 44) rides on tracks 38 within the cabinet 18. The 10drawer 36 includes a housing 34 attached to the iso-lated base 42 for movement on the tracks ~8. The housing 34 has a front handle 40 that the user can grasp to move the entire isolated mass of the centri-fuge 16 along the tracks 38 between the enclosed and 15opened positions.
The controller 32 includes a user-accessible switch 114 (see Fig. 1) that operates a latch solenoid 116 for the drawer 36. The solenoid 116 normally locks the drawer 36 to keep the centrifuge 16 in its ZOenclosed operating position (as Fig. 6 shows). Pref-erable, the processing controller 32 includes an in-terlock 118 (see Fig. 14) that prevents operation of the solenoid 196 to unlock the drawer 36 whenever pow-er is supplied to the centrifuge motors 66 and 72.
;25The interlock 118 also preferably retains the latch pin 94 in its engaged position with the zero omega holder 86 (as Fig. 6 also shows), keeping the holder 86 in its operating position during processing ;` operations.
30~hen power is not being supplied to the centri-fuge motors 66 and 72, operation of the switch 114 moves the solenoid 116 to its unlocked position (as Fig. 11 shows). This frees the drawer 36, allowing the user to enter the centrifuge 16. Also, the latch-35ing pin 94 withdraws, freeing the ~ero omega holder 86 :`
. ` .

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W093/128~7 PCr/US92/11216 : 21~3~1A i-for pivotal movement on the support frame 88.
As Figs. 11 and 12 show, as the user opens the drawer 36, moving the isolated mass of the centrifuge 16 to its accessible position, the roller member 96 on the zero omega holder 86 travels along an interior ramp 112 within the cabinet 18. As the drawer 36 opens, the ramp 112 urges the zero omega holder 86 down against the biasing force of the spring 92, guid-ing the roller member 96 into and through the access lo opening 100.
Once the isolated mass of the centrifuge 16 is in its opened position (as Fig. 12 shows), the user can apply a downward force upon the spring biased zero :: omega holder 86 to free the upper umbilicus biock 102 from T'-:e mount 78. Once freed from the block 102, the biasing spring 92 pivots the zero omega holder to a ful ~ upraised and out-of-the-way position shown in ., phantom lines in Fig. 12 and in solid lines in Fig.
:~. 13.
:. 20 As will be described in greater detail later, ~ the ramp 112 also serves to guide the roller member 96 .~ as the drawer 36 closes to return the zero omega hold-er 86 to its normal operating position.
.. .
E. Th~ Two Ome~ Ch~mber_A~e~bly : As Fig. 13 shows, once the centrifuge 16 QCC~-pies its accessible position outside the cabinet 18, ~ the user can pivot the entire processing chamber as-; sembly 52 about the yoke cross member 62 to an upright position convenient for loading and unloading the pro-cessing chamber 22 t~ig. 1 shows this, too). As Fig.
13 also shows, once in its upright position, the user can further open the entire processing chamber assem-: bly 52 to further simplify loading and unloading oper-` 35 ations.

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-- ~0 --vot~n~ the _Ch~mh~r AssemblY~ ~or ~o~lnq Figs. 15 to 18A/B/C show the details of the pivot assembly 194 for moving the processing chamber 52 into its upright position.
The pivot assembly 194 suspends the yoke cross member 62 between the yoXe arms 60. The two smega chamber assembly 52 carried on the cross member 62 thereby rotates between a downward suspended position (shown in Fig. 4) and an upright position (shown in Fig. 15).
When operating, the chamber assembly 52 oc-cupies the suspended position. The user places the chamber assembly 52 in the upright position for load-ing and unloading the processing chamber 22 after hav-ing placed the isolated mass of the centrifuge 16 is in its accessible opened position outside the cabinet.
The pivot assembly 194 for the chamber assembly 52 ~ay be constructed in various alternative ways.
Figs. 15 to 18AIB/C to 18 show the details of one pre-ferred embodiment. The Figures show only one side of the pivot assembly 194 in detail, because the other ; side is constructed in the same manner.
The pivot assembly 194 includes a pair of left and right pivot pins 196. Bearings 198 carry the piv-ot pins 196 on the yoke arms 60. A retainer bracket 200 secures each pivot pin 196 to the yoke cross mem-her 62.
- The pivot assembly 194 employs a swinging lock assembly 202 to control the extent and speed of rotation of the chamber asse~bly 52 on the pivot pins 96. The swinging lock assembly 202 includes a rotat-ing cam 204 secured to the end of each pivot pin 196.
~' Each cam 204 includes a cut out arcuate groove 206 (see Fig. 16) that ends at opposite first and second .
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WO93/l2887 PCT/US92/112l6 2 1 ~

~ 21 -detents, respectively 208 and 210. The groov~ 206 defines the range of rotation of the chamber assembly 52 on the pivot assembly 194.
The swinging lock assembly 202 al50 includes left and right locking pi~ 212 c~rried in the top of each yoke arm 60. Each locking pin 212 has an end key 214 that rides within the interior groove 206 of the associated cam 204. The opposite end cf each locking pin 212 forms a control button for manipulation by the user at the top of the upright yoke arms 60.
The user an independently move each locking pin 212 between an upraised position (shown in Figs.
18A and 18C) and a depressed position (shown in Fig.
18B). The swinging lock assembly 202 uses a spring 218 to normally bias each locking pin 212 toward its upraised position.
When in its upraised position, the end key 214 of each locking pin 212 is captured within either the first detent 208 or the second detent 210 of the as-; 20 sociated cam 204, depending upon the rotational position of the cam 204. When captured by either detent 208/210, the end key 214 prevents further rota-tion of the associated cam 204. ~hen in its upraised position, the end key 214 locks the chamber assembly 52 into either its upright load position or its sus-pended operating position.
; More particularly, when the first detent 208 captures the end key 214 of at least one locking pin 212 (as Fig. 18A shows), the locked cam 204 holds the chamber assembly 52 in its suspended operating posi-tion (shown in Fig. 4). When the second detent 210 captures the end key 214 of at least one locking pin 212 (as Fig. 18C shows), the locked cam 204 holds the ; chamber assembly 52 in its upraised load position ~35 (shown in Fig. 15).
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:~:
When the user depresses the locking pin 212 (as Fig. 18B shows), the end ~ey 214 moves out of the detent 208/210 and into the groove 206, freeing the as~ociated cam 204 for rotation within the limits of groove 206. By freeing the end keys 214 of both lock-ing pins 212 from their a~sociated detents 208/210, the user pivots the cha~ber assembly 52 between its operating and load positions. Upon rotation from one detent position to the other, the biasing springs 218 automatically snap the end key 214 of each the locking pin 212 into the other detent as it reaches alignment with the end key 214, thereby automatically locking the chamber assembly 52 in the other detent position.
In the illustrated and preferred embodiment, the swinging lock assembly 202 also includes a biasing ' spring 220 associated with each cam 204. The springs ; 220 rotationally bias the cams 204 toward the position shown in Fig. 18C, where the second detent 210 cap-tures the end keys 214 of the locking pins 212. To-gether, the springs 220 bias the chamber assembly 52 toward its upraised load position.
In this arrangement, by depressing both locking pins 212 with the chamber assembly 52 located in its downward operating position (Fig. 18A), the freed cams ` 25 204 automatically swing the chamber assembly 52 in re-sponse to the springs 220 into its upraised load posi-tion (Fig. 18C).
The swinging lock as~embly 202 also preferably includes a damping cylinder 222 associated with each spring assisted cam 204. The damping cylinder 222 has a spring or pressure operated pin 224 that con-tinuously presses against an outwardly radially tapered damping surface 226 on each cam 204. As it ; rides upon the tapered damping surface 226, the pin 224 progressively resists the spring-assisted rotation ., :. .

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: :.. :: - : ~ .:.. ,...... : . - .: ., : , .. : , . . : , .. ,.. - , wog3/l~s7 PCT/US92/l1216 21~3~1ll of each cam 204, moving from the fir5t detent 208 (the dow~ward operating position) toward the second detent 210 (the upraised lo~d position). The progressive re-sistance of the pin 224 slows the pivotal movement of ~ 5 the assembly 52, as the pin 224 come~ to rest at the '; outermost radius of the ramp 226 (as Fig. 18B snows), which amounts to about loO degrees of rotation from the suspended operating position. The user then pulls on the processing chamber 52 to rotate it about an lo additional 30 degrees to slip the pin 224 into a re-taining notch 216 (as Fig. 18C shows). There, the biasing springs 218 of each locking pin 212 snap the end keys 214 into the second detents 210, locking the chamber assembly 52 in its upraised load position.
With the chamber assembly 52 located in its up-raised position, the user can simultaneously depress both locking pins 212. The chamber assembly 52 will rotate about 30 degrees, until the pin 224 abuts against the ramped portion 217 of the notch 216. The user is then free to release the locking pins 212 without engaging the second detents 210 and manually pivot the chamber assembly 52 to free the pin 224 from the retaining notch 216. Further rotation against the ; action of the biasing springs 220 brings the chamber ; 25 assembly 52 back to its operating position. There, the biasing springs 218 of each locking pin 212 snap the end keys 214 into the first detents 208 of the cams 204, preventing further rotation out of this po-sition during processing.
As Fig. 15 shows, a protective cover 221 is preferably mounted on each side of the yoke arms 60 to enclose the pivot assembly 194 and associated compo-nents. This protective cover 221 has been removed or cut away in some of the drawings to simplify the dis-cussion.

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W093/l2887 PCl/US92/11216 f~',.
2103'~

2. O~e~n~ th~ Ch~ber A9~e~1Y for ~on~nn As Figs. 13, 19 and 20 show, when locked in its upraised position, the user also can open the chamber assembly 52 for loading and unloading the replaceable processing chamber 22 in the manner shown in Fig. 1.
For this purpose, the chamber assembly 52 includes a rotating outer bow~ 128 that carries within it an inner spool 130. In use, the inner spool 130 holds the processing chamber 22. The inner spool 130 telescopically moves into and out of the outer bowl 128 to allow the mounting and removal of the chamber 22 upon the spool 130.
The outer bowl 128 has a generally cylindrical interior surface 132. The inner spool 130 has an ex-terior peripheral surface 134 that fits telescopically within the outer bowl surface 132 (see Fig. 9). An ; arcuate channel 136 extends between the two surfaces 132 and 134. When mounted on the spool 130, the pro-cessing chamber 22 occupies this channel 136. The spool 130 preferably includes top and bottom flanges 138 to orient the processing chamber 22 within the channel 136.
The centrifuge assembly 12 includes a mechanism for moving the inner spool 130 into and out of the bowl 128. The mechanism can be variously constructed, and Figs. 19 to 24 show one preferred arrange~ent.
As Figs. 19 and 20 show, the outer bowl 128 is coupled to the se~ond drive shaft 56. The inner spool 130 includes a center hub 140. A ~pool shaft 142 is secured to the hub 140 by a pin 144. The spool shaft 142 fits telescopically within the open bore of the second drive shaft 56.
The exterior surf~ce of the spool shaft 142 has a hexagonal shape (as Fig. 21 best shows). The inte-:

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WO 93/12887 PCr/U$92tl1216 2 1 0 3 ~ 1 ~
", . , rior bore at the base 146 of the second drive shaft 56 has a mating hexagonal 6hape. The mating hexagonal surfaces couple the spool 130 to the bowl 12~ for com-mon rotation with the second drive shaft 56.
In the arra~gement, the lnner spool 130 is movable along the second drive shaft 56 between a low-ered operating position within the outer bowl 128 (as Fig. lg shows) and an unlifted loading position out of ;~ the outer bowl 128 (as Fig. 20 shows). As Fig. 21 best shows, the hub 140 preferably takes the shape of a handle that the user can easily grasp to raise and lower the spool 130.
As Figs. 19 and 20 show, the spool shaft 142 includes an axial keyway 148 having a lower detent 150 and an upper detent 152. The keyway 143 defines the range of up and down movement of the spool 130 within the bowl 128.
The bowl 128 includes a detent pin 154 that ex-tends into the open bore of the second drive shaft 56.
A spring 156 biases the detent pin 154 into the keyway 148, where it rides into and out of releasable engagement with the lower and upper detents 150 and 152 as the user raises and lowers the spool 130.
In this arrangement, when the upper detent i52 engages the spring biased pin 154 (as Fig. 19 shows), the spool 130 is releasably retained in its lowered operating position. When the lower detent 150 engages the spring biased pin 154 (as ~ig. 20 shows), the spool 130 is releasably retained in its uplifted load-ing position. Normal external lifting and lowering force exerted by the user overcomes the biasing force of the spring 156 to easily move the spool 130 up and down between these two limit positions.
With the spool 130 locked in its uplifted posi-tion, the user can wrap the processing chamber 22 upon : ' ' . ' ` ' '~ . ' ' , .

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W093/1~87 PCT/US92/11216 210391~ ~ ~

the peripheral spool surface 134 ~as Fig. 1 shows~.
With the spool 130 locked in its lowered position (see Fig. 19~, the wrapped processing chamber 22 is sandwiched within the channel 136 between the spool 130 and the bowl 128. Rotation of the chamber assem-bly 52 subjects the proce~sing chamber 22 to centrifugal forces within the channel 136.
A locking mechanism 158 prevents the spool 130 from dropping out of the bowl 128 while the chamber lo assembly 52 rotates in its downward suspended operat-ing position.
The mechanism lS8 includes locking pin 160 fas-tened to the bowl 128. The distal end of the locking pin 160 extends out through a passage 120 in the hub 140. The distal end includes a notch 122.
As Figs. 21 and 22 show, a latch member 124 slides on tracks 126 upon the handle end of the hub 140. The notched distal end of the locking pin 160 ; passes through an elongated slot 162 in the latch mem-ber 124. Springs 164 normally bias the latch member 124 toward a forward position on the handle end of the hub 140. In this position (shown in Fig. 24), the notch 122 engages the rear edge 163 of the slot 162.
This engagement secures the spool 130 to the bowl 128.
The latch member 124 is mass balanced so that centrif-ugal ~orce will not open it during use.
As Fig. 23 shows, sliding the latch member 124 rearward frees the notch 122 frcm the rear slot edge 163. This releases the spool 130 from the bowl 128, allowing the user to lift the spool 130 from the bowl 120 in the manner previously described.
In the embodiment shown in Figs. 19 to 24, the sliding latch member 124 also forms a part of the two omega umbilicus clamp mount 84. As Figs. 21 and 23 show, sliding the latch member 124 rearward opens the .
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WO 93/1~887 pcr/us92/112l6 '` 2103911 .

mount 84 to receive the lower umbilicus block 110.
The spring assisted return of the latch member 124 to i~s forward position (shown in Fig. 24) captures the lower umbilicus block 110 within the mount 84. The biasing springs 164 also hold the latch member 124 closed to clamp the block 110 within the mount during processing operations.
In this arrangement, the locking pin 160 is preferably flexible enough to be resiliently displaced by the user (as the phantom lines in Fig. 24 show) to free the notch 122 from the rear slot edge 163 without operating the latch ~fffember 124. This allows the user to lift the spool 130 into its upraised position with-out freeing the lower umbilicus block (as Fig. 13 shows).
As Figs. 22 and 23 also show, the latch member 124 is preferably vertically moveable within the tracks to drop the rear slot edge 163 into engagement ~, against the rear edge 166 of the hub handle. This , 20 allows the user to temporarily secure the latch member 124 in its rearward position against the action of the ; ~iasing ~prings 164, fr~-eing both of the user's hands to load the umbilicus 76. Lifting upward frees the - rear slot edge 163, allowing the springs 164 to return -' 25 the latch member 164 to its forward clamping position.
Figs. 25 to 27 show an alternative locking mechanism 158 for the spool 130. In this arrangement, the second drive shaft 56 includes an undercut latchway 168. The hub 140 houses a latch pawl 170 carried by a pin 172 for pivotal movement between an engaged position with the latchway 168 (as Fig. 26 shows) and a disengaged posltit)n from the latchway 168 (as Figs. 25 and 27 show).
l~he hub 140 carries linkage 174 that operates - 35 the latch pawl 170. The linkage 174 has a hooked end w093/12887 PCT/US92/11216 2 1 0 3 9 1 ~

176 coupled to the latch pawl 170 and a pin end 178 positioned in the path of a cam 180 carried by a latch lever 182. A pin 228 attaches the latch lever 182 to the hub 140 for pivotal movement between an unlatched position (shown in Figs. 25 and 27) and a latching position (shown in Fig. 26).
A spring 230 normally biases the linkage 190 to maintain the latch pawl 170 in its disengaged position when the latch lever 182 is in its unlatched position.
In this orientation, the user is free to raise the spool 130 in the manner just described.
With the spool 130 in its lowered position, movement of the latch lever 182 to the latching posi-tion brings the cam 180 into contact with the pin end 178. Depressing the pin end 178 in turn moves the linkage 174 against the biasing force of the spring ; 230 to pivot the latch pawl 170 into its engaged po-sition with the latchway 168. In this orientation, the interference between the latch pawl 170 and the ` 20 latchway 168 prevents axial movement of the spool 130 a~ong the second drive shaft.
: When the latch lever 182 is in its latching position, spring biased pins 232 releasably engage detents 234 on the latch lever 182. The pins 232 releasably resist movement of the latch lever 182 out of its latching position. By applying deliberate - lifting force to the latch lever 182, the user can overcome the spring biased pins 232 to move the latch-ing lever 182 into its unlatched position.
In this arrangement, a holding bracket 236 as-sociated with the latch lever 182 locks the lower um-. ., bilicus block 110 within the mount 84 while the spool .:..................................... . .
130 is locked into its lowered position. In this em-bodiment, the holding bracket 236 opens the mount 84 3S when the latch lever 182 is in its unlatched position , : : . . ~ . . .
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W093/12887 PCI/U59Z/II~I~

2~039~1 i (showrl in Fig. 25) and closes the mount 84 when the latch lever 182 is in its latching position (shown in Flg. 26).

F. Loa~in~ t~e Flu~d Processi~A~semblv Figs. 28 to 31 show the details of loading a representative processing assembly 14 on the centri-fuge 16, as is generally depicted in Fig. 1. The rep-resentative processing assembly 14 includes a processing chamber 22 formed as an elongated flexible tube or belt made of a flexible, biocompatible plastic materlal such as plasticized medical grade polyvinyl chloride. The umbilicus tubes 74 communicate with :, ports 248 to conduct fluids into and out of the pro-cessing chamber 22.
The user begins the loading process by wrapping the flexible processing chamber 22 about the upraised and open spool 130.
As Fig. 28 best shows, the spool 130 includes one or more alignment tabs 238 on the spool 130. The spool alignment tabs 238 register with alignment notches 240 on the processing chamber 22 to assure the desired orientation of the processing chamber 22 on the spool 130.
Of course, the ways of aligning the chamber 22 on the spool 130 can vary. In the illustrated em-bodiment, the spool 130 has two alignment tabs 238A
and 238B, and the processing chamber 22 has two mating alignment notches 240A and 240B. Alternatively, pins or other alignment mechanisms can be used.
As Fig. 28 shows, one spool alignment tab 238A
protrudes from the spool surface 134 and mates with the notch 240A on the processing chamber 22. The oth-- er spool alignment tab 238B protrudes from a flap 242 that extends from and overhangs a portion of the spool , .... ,., ~. ,. ~ . . . . .

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WO93/12887 PCT/US92~11216 210391~ ~

surface 134.
In the illustrated embodiment, the flap 242 is hinged. It is movable between a rai~ed position (shown in phantom lines in Fig. 28), away from the spool surface 134, and a lowered position (shown in solid lines in Fig. 28), facing toward the spool sur-face 1~4. By placing the flap 242 into its lowered position, the alignment tab 238B on the flap 242 fits within a retainer 244 in the spool surface 134.
In this arrangement, with the flap 242 upraised, the user aligns the notch 240A with the tab 238A and aligns the notch 240B over the retainer 244.
Lowering the flap 242 places the tab 238B into the retainer 244, capturing the notch 240B between the flap 242 and the spool surace 134 (as Fig. 28 shows) to hold the processing chamber 22 in place.
Instead of a hinged flap 242, a flap fixed in the lowered position can be used. In this arrange-ment, the user tucks the processing chamber 22 beneath the flap.
As Fig. 29 shows, the user completes the loading process by overlapping the free ends of the processing chamber 22 on the opposite side of the spool 130. A clip 246 captures the o~erlapping ends, holding them close against the spool surface 134.
Alternatively, an adhesive tab (not shown) can be used to hold the overlapping ends of the processing chamber 22 together, ~s could pins mating with associated holes in the processing chamber 22.
The user then lowers and locks the spool 130 within the bowl 128 in the manner previously described to complete the loading process (as Fig. 30 shows).
The user clamps the lower umbilicus block llO into the - mount 84 in the manner previously described and pivots ; 35 the chamber assembly 52 into its downward suspended ~' -WO93/12887 PCT/US92/1t216 21~3nl~

position shown in Fig. 4.
The user then snaps the umbilicus bushings 106 into position in the slotted second and third mounts 80 and 82 on the one omega holder 104, as Fig. 4 shows. The user lowers the zero omega holder 86 to-ward the rotating components 50 and 52 of the centrifuge 16 to seat the upper block 102 into the mount 78.
The user closes the drawer 36 and completes the loading process by placing the tubes 74 into operative alignment with the pumps 28 and clamps 30 on the front panel of the cabinet 18.
The user generally follows a re~erse sequence of steps to unload the fluid processing assembly 14.
G. 8ha~ln~ the Prooessinq Ch~mber The interior bowl surface 132 and the exterior spool surface 134 are preformed to create within the high-G and low-G regions of the processing chamber 22 the specific contours required either to get the de-sired separation effects or to achieve optimal priming and air purging, or both.
In the embodiment shown in Fig. 32, the interi-or bowl surface 132 is preformed with a constant outer radius (as measured from the rotational axis). In this arrangement, the exterior spool surface 134 is preformed with contours of varying radii (also as mea-sured from the rotational axis) to present the desired geometry for the low-G region.
For areas where a non-iso-radial geometry on the high-G wall is desired, the chamber assembly 52 includes an overhanging attachment on the spool 130 extending between the low-G spool surface 134 and the high-G bowl surface 132. In the illustrated embodi-ment the attachment comprises the hinged flap 242 ,. ~ .: -. : - ................... :

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WO93~12887 PCT/US92/11216 21~3~1~
- 3~ -previously de~cribed. As Fig. 31 shows, the flap 242 is clipped, fastened by screw6, or otherwise con-veniently attached to the spool 130.
In this arrangement, all structures that create the desired contours in both the high-G and low-G re-gions of the cha~ber 22 are associated with the inner spool 130. In this way, changes in the contours to do different procedures or air purging methods can be made simply by changing the spool 130.
As Fig. 32 shows, the user can completely separate the spool 130 from the bowl 12~ by pulling up on the spool 130 to fully release the spool 130 from the locking pin 160. Since the spool 130 contains the desired contour forming surfaces for the processing chamber 22, the user can easily and quickly remove and exchange a spool having one configuration with a spool having another configuration.
Various features of the invention are set forth in the following claims.

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Claims (18)

I claim:
1. A centrifugation system comprising a frame enclosing an interior area, a centrifuge assembly including a chamber and means for rotating the chamber about an axis, and a base for supporting the centrifuge assem-bly on the frame including track means for moving the base and, with it, the centrifuge assembly between a first position within the interior area of the frame blocking access to the centrifuge assembly and a sec-ond position outside the interior area of the frame permitting access to the centrifuge assembly.
2. A centrifugation system comprising a frame enclosing an interior area, a centrifuge assembly including a chamber, means for rotating the chamber about an axis, and a processing element removably insertable into the cham-ber for receiving fluids to undergo centrifugal sepa-ration during rotation of the chamber, a base for supporting the centrifuge assem-bly on the frame including track means for moving the base and, with it, the centrifuge assembly between a first position within the interior area of the frame blocking access to the centrifuge assembly and a sec-ond position outside the interior area of the frame permitting access to the centrifuge assembly for in-sertion and removal of the processing element.
3. A system according to claim 1 or 2 and further including force dampening means between the centrifuge ass bly and the base for isolating the base from vibration and oscillation caused by the ro-tating chamber.
4. A system according to claim 1 or 2 wherein the track means moves the base in a direction generally perpendicular to the rotation axis of the chamber.
5. A system according to claim 1 or 2 wherein the frame includes a drawer moveable in the track means between a closed position and an opened position, and wherein the centrifuge assembly base is mounted within the drawer to locate the centrifuge assembly in its first position when the drawer is closed and to locate the centrifuge assembly in its second position when the drawer is opened.
6. A system according to claim 5 and further including means for locking the drawer in its closed position.
7. A system according to claim 5 and further including interlock means for preventing opening of drawer when the chamber is ro-tated.
8. A centrifugation system comprising a frame enclosing an interior area, a centrifuge assembly including a chamber, means for rotating the chamber about an axis, a processing element removably insertable into the chamber, an umbilicus for conveying fluid into the processing element to undergo centrifugal separation during rotation of the chamber, a base for supporting the centrifuge assem-bly on the frame and including holder means including mounting means for releasably receiving the umbilicus, the holder means being moveable between an operating position for orienting the umbilicus within the mounting means in a prescribed relationship with the centrifuge assembly and an nonoperating position spaced away from centri-fuge assembly and allowing user access to the chamber, track means for moving the base and, with it, the entrifuge assembly and holder means be-tween an enclosed position within the interior area of the frame blocking access to the centrifuge assembly and holder means and an exposed position outside the interior area of the frame permitting access to the centrifuge assembly and holder means for insertion and removal of the processing element in the chamber and mounting and removing the umbilicus on the holder means, and means for moving the holder means to-ward its operating position during movement of the base toward the enclosed position and for moving the holder means toward its nonoperating position during movement of the base toward the exposed position.
9. A system according to claim 8 and further including locking means for re-taining the holder means in its operating position when the base is in its enclosed position.
10. A system according to claim 9 wherein the locking means is freed in re-sponse to movement of the base from its enclosed posi-tion toward its exposed position.
11. A system according to claim 8 and further including force dampening means between the base and the centrifuge assembly and the holder means for isolating the base from vibration and oscillation of the centrifuge assembly and holder means caused by the rotating chamber.
12. A system according to claim 8 wherein the track means moves the base in a direction generally perpendicular to the rotation axis of the chamber, and wherein the means for moving the holder means pivots the holder means generally axially of the rotational axis.
13. A system according to claim 8 wherein the frame includes a drawer moveable in the track means between an closed position and an opened position, and wherein the centrifuge assembly base is mounted within the drawer to locate the centrifuge assembly and the holder means in the enclosed position when the drawer is closed and to locate the centrifuge assembly in its exposed position when the drawer is opened.
14. A system according to claim 13 wherein the drawer has an open top to allow user access to the centrifuge assembly when the drawer is opened.
15. A system according to claim 14 wherein the holder means orients the umbili-cus in a prescribed relationship above the centrifuge assembly when in its operating position and is spaced away from centrifuge assembly when in its nonoperating position to allow user access to the chamber through the open top of the drawer when the drawer is opened.
16. A system according to claim 13 wherein the drawer means moves the base in a direction generally perpendicular to the rotation axis of the chamber, and wherein the means for moving the holder means pivots the holder means generally axially of the rotational axis during movement of the drawer means.
17. A system according to claim 8 wherein the means for moving the holder means includes first means for biasing the holder means toward its nonoperating position and second means for retaining the holder means in its operating position against the force of the first means when the base is in its enclosed position.
18. A system according to claim 17 wherein the second means includes locking means for retaining the holder means in its operating position when the base is in its enclosed position and means for releasing the locking means in response to movement of the base from its enclosed position toward its exposed position to allow the first means to urge the holder means towards its nonoperating position.
CA002103914A 1991-12-23 1992-12-23 Centrifugal processing system with direct access drawer Abandoned CA2103914A1 (en)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
US81315791A 1991-12-23 1991-12-23
US7/813,157 1991-12-23

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EP0572623A1 (en) 1993-12-08
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US5362291A (en) 1994-11-08
JPH06505675A (en) 1994-06-30
AU652888B2 (en) 1994-09-08

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