CA1285440C - Red blood cell filtering system - Google Patents

Abstract

Abstract of the Disclosure Closed filtering system for relatively fast and efficient removal of white blood cells from a red blood cell mixture.
System comprises at least two blood bags in closed communication with each other via an intermediate filter assembly comprising a housing containing continuous filtering fiber. A preferred housing is tapered and the fiber preferably has a generally Y-shaped cross sectional area and it is adapted to permit substantial removal of white blood cells from a red blood cell mixture with minimal red blood cell hemolysis when the mixture is diluted with preservative solution and passed from one bag to the other at a relatively high flow rate. Filtration is completed within 24 hours, preferably within 6 hours, of whole blood donation.

Description

1~8~i440 RED BLOOD CELL FILTERING SYSTEM

SPECIFICATION
Background of the Invention Field: This disclosure is concerned generally with blood ,iltering systems and specifically with a system for the removal of white blood cells from red blood cells.

Prior Art: The desirability of removing white blood cells (WBC) from a mixture of WBCs and red blood cells (RBC) is well known, especially for patients who receive frequent blood transfusions. See, for example abstracts by K.
Kleesiek et al (P-9-01) and M. Jochum et al (p-9-02) from Abstracts of the 18th Congress of the International Society of Blood Transfusion, Munich, July 22 - 27, 1984. See also the article by H. Harke et al, Anaesthesist (1982) 31:165 -171.

In the past, WBCs and platelets associated with febrile reactions have been removed via the reconstitution of frozen blood (which is costly) or by multiple washings with saline of the RBC/WBC mixture (which is time consuming, is less predictable, and results in RBC loss).

Kikugawa et al in Vox Sanq., Vol. 34, 281 - 290 (1975) describe commercial cotton wool filters for filtering blood to remove the above HLA antigen. These filters are however, expensive and cumbersome to use.

Diepenhorst et al in Vox Sang., Vol. 23, 308 - 320 (1972) and Vol. 29, 15 - 22 (1975) disclose cotton wool filtration of blood under pressure. This method, while efficient, requires a special apparatus that is expensive.

All of the above techniques require that the treated blood be infused within 24 hours of treatment in order to avoid the potential 'risk of infection. Prolonged shelf life of blood so treated is not possible.

Some of the above shortcomings have been addressed in Canadian Patent 1,206,831, issued July 2, 1986, L.
Wisdom entitled "Blood Bag System with Integral Filtering Means". The present disclosure represents an improvement over the system and methods disclosed in the application and details of the improved system and method of filtration are described below.

Our red blood cell filtering system comprises a closed multiple blood bag system comprising at least two flexible plastic bags in closed communication with each other via connection plastic tubing.
Intermediate the bags and continuous with the con-necting plastic tubing is a white blood cell filter.
The filter comprises a preferably slightly tapered housing containing continuous filtering fiber adapted to substantially remove WBCs from a mixture of WBCs and RBCs with minimal RBC hemolysis when the mixture is passed from one bag to the other through the filter at a relatively high flow rate. In preferred embodiments filtration is completed within 24 hours (very preferably within 6 hours) of whole blood donation and at a low temperature (e.g. less than 6C). The continuous filtering fiber preferably is a cellulose acetate material and, in a preferred embodiment, has a generally Y-shaped cross sectional area and a packed bulk of less than about 0.6 grams per cc and a continuous fiber length of greater than 1000 meters. The preferred filter has a volume of less than about 50 cc and yet is capable of filtering a unit of blood (about 225 ml of packed RBCs sub-~28544V

sequently diluted to about 325 ml total with a RBCadditive or preservative solution) in less than 3 hours at room temperature. The preferred filter can remove over 80% of the WBCs in a WBC/RBC mixture at the above rate with a RBC hemolysis after five weeks storage of less than 0.30%. In a very preferred embodiment, one of the bags includes a RBC preser-vation solution which is used to prime the filter prior to the filtration step.

Brief Description of the Figures Figure 1 is a plan view of a multiple blood bag filtering system of the type disclosed herein.

Figures 2A and 2B compare with cross sectional areas of the fiber of Canadian Patent 1,206,831, cited above, with the continuous, preferred fiber of the present invention.

Figures 3A and 3B compare a cross sectional view of the filter housing of this disclosure (3B) with that of the housing of Canadian Patent 1,206,831 ~3A).

Figures 4A and 4B compare the filter retainers of the above described filters.

Figure 5 illustrates an exploded view of the prefer-red filter of the invention.

Specific Embodiments In inline RBC filtering system of this disclosure can be understood better by reference to the Figures.

- 3a -Figure 1 illustrates a whole blood collection bag ~donor bag) 3 in continuous close~d communication via plastic tubing 5 and filter 15 with an additive (preservative) solution bag 7 and one or more satel-lite bags 9 connected via a typical Y-connector 11~ Also in communication with the donor ~ag is blood collection tubing 13 which includes at its distal end (not shown) a blood donor needle of the common type used in the art (not shown). The system of Figure 1 may include various internal valves of the types well known in the art for containing or moving one or more components of blood through the closed filtering system.
As used herein, the term "closed" refers to a blood collection system which allows the collection, storage, processing, separation, filtration and preservation of donor whole blood or blood components without the need to enter the system (and risk contamination of the system).
Such a closed system may be originally made as an internal one piece unit or, result from the connection of the individual (or partially connected)components of such a syst~m using what are known as "sterile docking" devices of the type shown, for Example, in U.S. 4,507,119.

The system of Figure 1 is used as follows: Whole blood is collected via tubing 13 from a donor into donor or collec-tion bag 3 which typically contains an anticoagulant solution. The whole blood is then centrifuged using normal procedures (e.g. 3000 rpm for 2 minutes) to separate the blood into denser packed red blood cells and less dense platelet rich plasma. By opening a conventional valve (not shown) between donor bag 3 and one of the satellite bags 9, the platelet-rich plasma may be expressed into one of the satellite bags by known means (e.g., by using a plasma expressor), leaving behind the packed red blood cells in donor bag 3. The packed RBCs include both WBCs and some platelets, both of which should be removed if possible before use or storage. This is accomplished by reconsti-tuting the RBC mixture with an additive solution, preferably a~lready in the closed system and available from additive solution bag 7, by merely expressing the solution from bag 7 through filter 15 (in the non-filtering direc-tion) into donor bag 3 for mixture with and dilution of the .

12~3544~

RBC mixture. Additive (or preservative) solutions for RBCs are well known and deseribed in numerous publications. Two such solutions are described in the Examples below. This pre-filtering flow of additive solution through the filter into the bag of ~packed) RBCs allows reconstitution and provides a viscosity for the RBCs that is beneficial for filt-ration. In addition, the additive solution primes the filter for the important filtration step with the RBC/additive solution. This initial priming is important because it is a necessary step to prepare the filter for efficient white blood cell removal.
In particular it allows the cellulose acetate mate-rial to absorb water and flushes the air void volume of the filter.

The above steps can all be accomplished by known means via external manipulation of the bags or internal values, thus keeping the system "closed" to outside contaminants. After the RBC mixture has been reconstituted with the additive solution, the recon-stituted mixture is passed in a forward filtering direction through filter 15 by gravity at which time most of the WBCs and remaining platelets are removed by the filter, allowing the filtered RBCs already in an additive/preservation solution, to be stored in bag 7 which can be clamped and removed from the system for long term storage, preferably for up to 6 weeks. The platelet-rich plasma in one of the satellite bags 9 can be further processed (e.g. by centrifugation at higher speeds, etc.) to separate the mixture into yet further components (platelets and plasma components) by other known means.

.

lZ85440 Figure 2B shows a cross section of the preferred present filter fiber of this disclosure having a generally Y-shaped cross sectional area and compares it with the earlier fiber of Canadian Patent 1,206,831, Figure 2A. It is important to note that the filtering fiber of this invention is "continuous", that is, an essentially single strand of fiber that may be up to 9000 meters long. This is unlike the chopped filter material of the prior art which is undesirable because potential loose short (3.2 cm) fibers of the prior art might pass through a fiber-retaining screen and into the final product.

Figures 3A and 3B compare the cross section of the filter housing of the filter of this disclosure (3B) with that of the earlier housing of Canadian patent 1,206,831 and illustrates how the housing of this disclosure is slightly tapered at one end to assist in the filtering process.

As can be seen in Prior Art housing 3A, the housing in cross section appears rectangular and is not tapered as in housing 35 of this invention, Figure 3B. The taper of the housing 35 of Figure 3B is defined by an angle of about 2 degrees, as illust-rated at 19 of Figure 3B. Such tapering assures the prevention of any channelling within the filter potentially resulting in unfiltered white blood cells in the final product.

Both Figures 3A and 3B have inlet and outlet ports 33, 31, 39 and 37 and members 27 and 21 adapted to assist in retaining the filter fiber (41 of Figure 5). In the present filter, however, the fiber ~ 285440 retaining me~ber 21 has interrupted ridges 23 and channels 25. The ridges are used to support the fused screen and prevent blocking of the outlet port 37. Also, the ridges provide a continuous pathway for the leukocyte poor red cells to exit the filter.

The present filter also includes at the opposite ~smaller) end within housing 35 a fused screen (see 17 in Figure 3s and, in exploded form, 17 in Figure 5). The screen is designed to retain fiber material and prevent fiber blockage of inlet and outlet ports and is preferably made by sonic energy fusion of polyester screens. Two each 1000 micrometer mesh size screens sandwiching of a 27 micrometer pore size screen to form a single unit.

The preferred fiber is a "continuous" cellulose acetate (obtained, for example, from Celanese Corp.
and known as Celanese brand cellulose acetate "TOW"
filter material). Other continuous fibers include polyester, cotton wool and polypropylene. (TOW
identifies a continuous type fiber as distinguished from staple or chopped fibers).

The filter housing itself may be made from polycar-bonate. Other details on the filter and bags (how made and connected) may be found in Canadian Patent 1,206,831.

The filter of this disclosure compared in physical properties with that of Canadian Patent 1,206,831, as follows:

s~

128~440 - 7a -Table I
Earlier Disclosure This Disclosure Fiber: Cellulose Acetate Cellulose (Staple) Acetate (Tow) Fiber length: ~ 3.2 cm 7 1000 m Shape (x.c.): gen. circular gen. Y shaped Housing Vol.: 55 cc 48 cc Fiber weight: 35 g 25 g Density: 0.636 g/cc 0.521 g/cc Flow time (unit)*
(at room temperature): 4.2~ 0.8 h 2.3 -0.4 h % WBC
removal (at room temperature): 84~ 9% 87 ~ 9~
~one unit - about 250-300 ml of reconstituted RBCs.
Discussion of Differences As can be seen from the above Table, the filter of this disclosure uses about 30% by weight less fiber without compromising WBC removal. Quite surpris-ingly, this is done while significantly reducing the flow time. As can be i.
, seen, the flow time is reduced by almost one-half, a convenience to the user and a useful feature in cases where filtered RBCs are needed in a hurry.

Effects of WBC Titration on RBCs With Time: In a preferred embodiment of the invention disclosed herein, the WBCs are removed via filtration from the RBC/WBC mixture as soon as possible (i.e. within 24 hours) after whole blood collec-tion so that the WBCs have as little contact as possible with the RBCs during storage, which can be up to 6 weeks.
The effects of WBC removal using the filtration system disclosed herein were surprising when both hemolysis and 2,3-DPG levels of the stored RBCs were measured over varying periods of time both with and without using the filtering system of this invention.

Hemolysis Studies: The amounts of hemolysis at 5, 6 and 7 week storage periods were compared for filtered and non-filtered RBCs using two different RBC storage solutions designated "AS-3~ and "AS-5~ additive systems. In cases where the filtering system of this disclosure was used, filtration was done within about 6 hours of blood donation and gross separation. The AS-3 and AS-5 additive systems (for up to 42 day RBC storage) used in the examples had the following ingredients per 100 ml additive solution:

Table II
AS-3 Additive Solution (Der 100 ml) Dextrose - H201100 mg Sodium Chloride410 mg Citric Acid - H2042 mg Sodium Citrate - 2H20 588 mg Monobasic Sodium Phosphate - H20276 mg Adenine 30 mg Water q.s.

g Table III
AS-5 Additive Solution (per 100 ml) Trisodium-L-Ascorbate-2-Phosphate 230 mg Sodium Chloride 450 mg Adenine 30 mg Sodium Phosphate (anhydrous) 400 mg Mannitol 750 mg Water q.s.

Using the above storage solutions, RBC hemolysis was measured by direct spectrophotometry as described by Blakney an~ Dinwoodie, Clin. Biochem. 1975; 8:96 - 102 and the results over varying periods are shown in Tables IV
and V, below.

Table IV
Hemolvsis for AS-3 Additive Systems Conditi n Week 5 Week 6 Week 7 AS-3 Filtered Q 5 C n=4 0.28 + 0.20 0.36 + 0.25 0.37 + 0.25 AS-3 Filtered @ RT nF4 0.17 + 0.04 0.22 + 0.06 0.28 + 0.08 x + SD n=8 0.23 + 0.15 0.29 + 0.18 0.33 + 0.18 AS-3 Unfiltered n=3 0.21 + 0.06 0.48 + 0.10 0.79 + 0.06 AS-3 Unfiltered n=3 0.30 + 0.14 0.80 + 0.33 0.93 + 0.55 AS-3 Unfiltered n=4 0.61 ~ 0.64 - 1.02 + 1.04 AS-3 Unfiltered n~4 -0.66 + O. 22 x + SD n=10 , 0.40 + 0.420.52 + Q.27 0.93 + 0.66 ~28S440 Table V
Hemolysis for AS-5 Additive Systems Condition Week 5 Week 6 Week 7 AS-5 Filtered @ 22 C n=4 0.16 + 0.020.24 + 0.050.38 + 0.09 AS-5 Filtered @ 5 C n=4 0.21 + 0.150.27 + 0.180.44 + 0.35 x + SD n=8 0.18 + 0.100.25 + 0.130.41 + 0.24 AS-5 Unfiltered n=40.46 + 0.150.64 + 0.27 ---AS-5 Unfiltered n=30.73 + 0.111.01 + 0.18 ---AS-5 Unfiltered n=40.45 + 0.190.65 + 0.33 ---x + SD n=ll 0.53 + 0.190.74 + 0.30 ---Statistics P = <0.01 P = <0.01 -2,3-DPG Studies: Using the filtering system of this disolosure and the AS-5 additive solution, 2,3-DPG levels (a measure of RBC oxygen affinity or RBC function) were determined and compared with non-filtered RBCs. Results are shown in Table VI.

Table VI
2,3-DPG Date for AS-5 % of Initial Condition Week 3 Week 5 Week 7 . . .
AS-5 Filtered @ RT n=4 194% 160 102 AS-5 Filtered @ 5 C n=4 172% 128 104 AS-5 Unfiltered n=4158% 108 AS-5 Unfiltered nF3171% 110 --In use, whole blood should be filtered with the above filtering system as soon as possible after collection from a donor. As a practical matter, this should be within 24 ~28S440 hours of whole blood collection but, very preferably, the filtration is completed within about 6 hours of whole blood collection and the filtration should be at a low tempera-ture (at least as low as 25 C, or in the range of about 4 to 25 C.

ATP Levels in Filtered (F) vs. Unfiltered (C) Blood: ATP
levels of filtered and unfiltered blood were compared.
Each unit of blood (six in all) had a portion drawn and stored as the control (C = unfiltered) sample before filtration occurred. The results are summarized below:

Table VII
ATP (~M/gHb) F C F C
273 4.0 3.7 3.5 2.6 274 5.1 4.7 5.0 4.3 275 4.3 3.8 3.7 3.2 276 3.5 3.7 3.2 3.0 277 4.1 3.4 3.3 2.4 278 2.6 2.0 2.2 1.6 x + SD 3.9+0.8 3.6+0.93.5+0.9 2.9+0.9 p <0.03 p '0.01 ATP Levels in filtered samples were significantly higher (n=6) compared to corresponding unfiltered control samples at both Week 5 and Week 6. In general. ATP levels tend to correlate with in vivo recovery. (Dern et al, J. Lab.
Clin. ~ed., Vol. 69, 968 - 978, 1967).

Usual comparisons to initial samples cannot be made since initial samples were not measured. ATP levels were determined by the method of enzymatic analysis, H-U
Bergmeyer, ed. 2nd printing, rev. 1965. Acad. Press, New York, pp. 559 - 572.

Given the a~ove disclosure, it is thought numerous varia-tions will occur to those skilled in the art. Accordingly, it is intended that the above example should be construed as illustrative only and that the inventions disclosed herein be limited only by the following claims.

Claims (28)

1. In a closed multiple blood bag system comprising at least two flexible plastic bags in closed communication with each other via connecting plastic tubing, the improvement comprising a filter disposed between the two bags and continuous with the connecting tubing, the filter comprising a housing containing continu-ous filtering fiber, the filter adapted to permit sub-stantial removal of white blood cells from a mixture of red and white blood cells with minimal red blood cell hemolysis when the mixture is passed from one bag to the other through the filter at a relatively high flow rate.

2. The system of claim 1 wherein the continuous filtering fiber has a fiber length of greater than about 1000 meters.

3. The system of claim 1 wherein the filtering fiber has a density of less than about 0.6 grams per cc.

4. The system of claim 1 wherein the filter housing has a volume of less than about 50 cc and the filtering fiber has a generally Y-shaped cross sectional area and is cellulose acetate.

5. The system of claim 1 wherein the filter is capable of filtering a unit of blood comprising a mixture of red and white blood cells in less than about 3 hours at room temperature.

6. The system of claim 1 wherein the filter is capable of removing at least about 80% of white blood cells from the mixture.

7. The system of claim 6 wherein the filter is capable of filtering the cells and reducing long term hemolysis of the cells such that the amount of hemolysis detectable after five weeks storage of the filtered red blood cells is less than about 0.30%.

8. The system of claim 1, wherein the filter housing is tapered in one direction.

9. The system of claim 1, wherein the filter housing includes between the red blood cell exit and the container filter fiber, at least two filter fiber support screens, the screen closer to the fiber having a mesh size larger than the remaining screen.

10. The system of claim 9, wherein the screens are fused to form an integral unit adapted to restrain the filter fiber without substantial clog-ging of the filter.

11. A closed multiple blood bag system comprising a first and second flexible bag in com-munication with each other via flexible tubing, the system including a red blood cell additive solution in the first bag and an inline filter in communi-cation with the tubing and between the two bags, the filter comprising a housing having a volume of less than about 50 cc and containing continuous filtering fiber having a density of less than about 0.6 grams per cc, the fiber being retained within the housing by a pair of fused support screens having different mesh sizes and disposed between the filter fiber and the RBC exit of the filter.

12. A method of processing whole blood for the storage of red blood cells comprising the steps of -(a) collecting whole blood from a donor into the donor bag of a closed multiple blood bag system comprising a donor bag in communication with at least one other bag via connecting tubing, the tubing including an integral white blood cell filter and the other bag including a red blood cell additive solution;

(b) centrifuging the whole blood in the donor bag under conditions sufficient to separate the whole blood into an upper plasma component and a lower red blood cell component which includes some white blood cells;

(c) removing the plasma component from the donor bag;

(d) introducing the additive solution into the donor bag by passing it through the filter to prime the filter removing air from it and then mixing the solution with the red and white blood cells; and (e) passing the mixture of step (d) through the filter and into the other bag under conditions sufficient to remove substantially all white blood cells from the mixture, thereby providing a red blood cell preparation substantially free of white blood cells and suitable for long term storage without substantial amounts of white blood cell contaminants.

13. The method of claim 12 where steps (a) through (e) are accomplished within 24 hours of each other.

14. The method of claim 13 wherein steps (a) through (e) are accomplished within 6 hours of each other.

15. The method of claim 12 wherein the white blood cell filter includes filtering fiber of cellulose acetate having a density of less than about 0.6 grams per cc.

16. The method of claim 15 wherein the fiber is a continuous filtering fiber having a fiber length of greater than about 1000 meters.

17. The method of claim 15 wherein the filter housing has a volume of less than about 50 cc.

18. The method of claim 15 wherein the filter is capable of filtering a unit of blood comprising a mixture of red and white blood cells in less than about 3 hours at room temperature.

19. The method of claim 15 wherein the filter is capable of removing at least about 80% of white blood cells from the mixture.

20. The method of claim 12 wherein the filter is capable of filtering the cells and reducing long term hemolysis of the cells such that the amount of hemolysis detectable after five weeks storage of the filtered red blood cells is less than about 0.30%.

21. In a closed multiple blood bag system comprising two flexible plastic bags in closed communication with each other via connecting plastic tubing, the improvement comprising a filter disposed between the two bags and continuous with the connect-ing tubing, the filter comprising a housing tapered in one direction and containing continuous filtering fiber, the filter adapted to permit substantial removal of white blood cells from a mixture of red and white blood cells with minimal red blood cell hemolysis when the mixture is passed from one bag to the other through the filter at a relatively high flow rate.

22. The system of claim 21, wherein the con-tinuous filtering fiber has a fiber length of greater than about 1000 meters.

23. The system of claim 21, wherein the filter-ing fiber has a density of less than about 0.6 grams per cc.

24. The system of claim 21, wherein the filter housing has a volume of less than about 50 cc and the filtering fiber has a generally Y-shaped cross sectional area and is cellulose acetate.

25. The system of claim 21, wherein the filter housing includes at least two filter fiber support screens.

26. The system of claim 25, wherein the screens are fused to form an integral unit adapted to restrain the filter fiber without substantial clog-ging of the filter.

27. The system of claim 21, wherein one of the plastic bags includes a red blood cell additive solution.

28. In a closed multiple- blood bag system comprising two flexible plastic bags in closed communication with each other via connecting plastic tubing, the improvement comprising a filter disposed between the two bags and continuous with the connect-ing tubing, the filter comprising a housing having a volume of less than about 50 cc containing continuous cellulose acetate filtering fiber having a generally Y-shaped cross section, the filter adapted to permit substantial removal of white blood cells from a mixture of red and white blood cells with minimal red blood cells hemolysis when the mixture is passed from one bag to the other through the filter at a relative high flow rate.