CN113621049B - Buffer solution and filler for ion exchange chromatography for purifying human fibrinogen - Google Patents

Buffer solution and filler for ion exchange chromatography for purifying human fibrinogen Download PDF

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CN113621049B
CN113621049B CN202111028702.7A CN202111028702A CN113621049B CN 113621049 B CN113621049 B CN 113621049B CN 202111028702 A CN202111028702 A CN 202111028702A CN 113621049 B CN113621049 B CN 113621049B
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buffer solution
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fibrinogen
tris
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鲁涛
牟蕾
李伟
余伟
王黔川
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Chengdu Rongsheng Pharmaceuticals Co Ltd
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Abstract

The invention discloses a buffer solution and a filler for an ion exchange layer for purifying human fibrinogen. The invention belongs to the field of plasma product preparation processes. Experimental results show that the buffer solution consisting of the equilibrium buffer solution, the washing buffer solution and the elution buffer solution is used in combination with the filler for ion exchange chromatography to purify the human fibrinogen, so that the content and the purity of the human fibrinogen in the obtained product can be obviously improved, and the virus inactivator residue in the product can be obviously reduced. The buffer solution and the filler for the ion exchange layer provided by the invention have good application prospects in purification of human fibrinogen.

Description

Buffer solution and filler for ion exchange chromatography for purifying human fibrinogen
Technical Field
The invention belongs to the field of plasma product preparation processes, and particularly relates to a buffer solution and a filler for an ion exchange layer for purifying human fibrinogen.
Background
Human Fibrinogen (Fg), also known as human coagulation factor i, is synthesized mainly by liver parenchymal cells, is one of the main components of plasma proteins, and is rich in Fibrinogen content, about 2-4 g/L in normal human plasma, and is one of the "central" proteins in the blood coagulation system.
The human fibrinogen is a final substrate for the sequential activation of blood coagulation factors in the blood coagulation process, has a hemostatic function, can directly participate in the later stage of the blood coagulation process, and can mediate platelet aggregation and influence blood viscosity. In the common pathway of blood coagulation, thrombin cleaves Arg16-Gly17 at the amino termini of two A alpha chains of fibrinogen to release a pair of fibersA vimentin peptide a, forming fibrin monomer I; a pair of fibrinopeptides B is released at the amino terminals Arg14-Gly15 of two B beta chains of the cracked fibrinogen to form a fibrin monomer II, the polymerization part of the fibrin monomer is exposed, and an unstable soluble fibrin monomer is formed through non-covalent combination. In activated blood coagulation factors XIII and Ca 2+ Under the action of the fibrin monomer, the fibrin monomer is mutually cross-linked to generate stable soluble fibrin, and the formed components of blood are wrapped in the stable soluble fibrin, so as to form firm thrombus. Besides being involved in blood coagulation, human fibrinogen has other functions, such as binding to platelet membrane glycoprotein IIb/IIIa to mediate platelet aggregation reaction, and participating in atherosclerosis and tumor metastasis. Therefore, the preparation of high-purity human fibrinogen has important clinical value.
At present, the purification method of human fibrinogen adopted is chromatography purification. The Chinese patent application with the application number of 201711104891.5 discloses a preparation method of human fibrinogen, which comprises the following steps: (1) Dissolving the human plasma low-temperature ethanol precipitation component I in the extracting solution to obtain a component I solution; (2) Performing S/D inactivation on the component I solution obtained in the step (1); (3) Balancing a lysine affinity chromatography medium with a balance solution, then carrying out column chromatography on the solution obtained in the step (2), and collecting a penetration peak; (4) And (3) balancing the cation exchange chromatography medium with a balance solution, then carrying out column chromatography on the penetration peak obtained in the step (3), eluting the chromatographic column with an eluent after the chromatography is finished, finally eluting with an eluent, and collecting the elution peak to obtain the human fibrinogen solution. However, the purification steps of the method are complex, and lysine affinity column chromatography and cation exchange column chromatography are required to be carried out in sequence; in addition, the virus inactivation process of the method adopts an S/D method, but the human fibrinogen purified by the method also contains a virus inactivator tributyl phosphate residue. It was found that tributyl phosphate half-Lethal (LD) of mice 50 ) 602mg/kg, which is harmful to The human body (The use of tri (n-butyl) phosphate reagents to inactive microorganisms viruses and human immunity viruses in plasma and plasma's subsequent reactivity. Transfusion.1990 Sep;30 (7):591-8.). Thus, it is possible to provideThere is a need to develop a fibrinogen purification method that is simpler in operation and has a lower residual amount of tributyl phosphate as a virus inactivating agent.
Disclosure of Invention
The invention aims to provide a buffer solution and a filler for an ion exchange layer for purifying human fibrinogen, and application of the buffer solution and the filler in purifying the fibrinogen, so as to simplify the purification steps of the fibrinogen, improve the purity of the fibrinogen and reduce the residual amount of a virus inactivating agent.
The invention provides a buffer solution for ion exchange chromatography for purifying fibrinogen, which comprises an equilibrium buffer solution, a washing buffer solution and an elution buffer solution; the balance buffer solution is 2-8 mM Tris buffer solution; the washing buffer solution consists of an aqueous solution of NaCl and Tris, wherein the concentration of the NaCl is 20-60mM, and the concentration of the Tris is 2-8 mM; the elution buffer solution consists of aqueous solution of NaCl and Tris, wherein the concentration of NaCl is 70-130mM, and the concentration of Tris is 2-8 mM.
Further, the pH value of the balance buffer solution is 8.0-9.0, the pH value of the washing buffer solution is 8.0-9.0, and the pH value of the elution buffer solution is 8.0-9.0.
Further, the equilibration buffer is 5mM Tris buffer, and the pH of the equilibration buffer is 8.5;
and/or, in the washing buffer, the concentration of NaCl is 30mM, the concentration of Tris is 5mM, and the pH of the washing buffer is 8.5;
and/or, in the elution buffer, the concentration of NaCl is 100mM, the concentration of Tris is 5mM, and the pH of the elution buffer is 8.5.
The present invention also provides a composition for ion exchange chromatography for purifying fibrinogen, the composition comprising the following two components:
component 1: the above-mentioned buffer solution for ion exchange chromatography;
and (2) component: the filler for ion exchange chromatography is polymethacrylate anion exchange resin.
Further, the filler for ion exchange chromatography is selected from Capto Q, fractogel EMD TMAE (M) or Fractogel EMD DEAE (M), preferably Fractogel EMD DEAE (M).
The invention also provides the buffer solution for ion exchange chromatography and the application of the composition for ion exchange chromatography in purifying fibrinogen.
Further, the purification of fibrinogen comprises the steps of: and (3) balancing chromatographic packing with a balance buffer solution, loading the fibrinogen subjected to virus inactivation onto a column, eluting with a washing buffer solution, eluting with an elution buffer solution, and collecting the eluate to obtain the purified fibrinogen.
Further, the virus inactivated fibrinogen is prepared according to the following method:
(a) Taking the cryoprecipitate, adding a water phase solvent for dissolving to obtain a cryoprecipitate dissolved solution;
(b) Adsorbing the cold precipitation solution with aluminum hydroxide, centrifuging, collecting supernatant, filtering, and retaining filtrate;
(c) Adding polysorbate 80 and tributyl phosphate into the filtrate, and inactivating to obtain virus-inactivated fibrinogen.
Further, in step (a), the cryoprecipitate is a cryoprecipitate prepared from fresh frozen plasma; the aqueous phase solvent is Tris buffer solution;
and/or, in the step (b), the dosage of the aluminum hydroxide is 1wt.% to 5wt.% of the cryoprecipitate, the adsorption time is 10 to 20 minutes, and the adsorption temperature is 20 to 35 ℃;
and/or in the step (c), the use amount of polysorbate 80 is 0.5wt.% to 2.0wt.% of the filtrate, the use amount of tributyl phosphate is 0.1wt.% to 0.5wt.% of the filtrate, the inactivation time is 4 to 8 hours, and the inactivation temperature is 24 to 26 ℃.
Further, in the step (a), the aqueous phase solvent is 10-30 mM Tris buffer solution with pH value of 6.0-7.5, preferably 20mM Tris buffer solution with pH value of 6.8;
and/or, in step (b), the amount of aluminum hydroxide is 2wt.% of the cryoprecipitate, the adsorption time is 15 minutes, and the adsorption temperature is 25 ℃;
in the step (c), the mass ratio of polysorbate 80 to tributyl phosphate is 10:3, the polysorbate 80 is used in an amount of 1wt.% of the filtrate, the inactivation time is 6 hours, and the inactivation temperature is 25 ℃.
Further, the fibrinogen is human fibrinogen.
Definitions of terms used in connection with the present invention: the initial definitions provided for by terms herein apply to that term throughout the specification unless otherwise indicated; for terms not specifically defined herein, the meanings that would be given to them by a person skilled in the art are to be given in light of the disclosure and the context.
The S/D method is a virus inactivation method, and refers to a method of disrupting the lipid membrane of enveloped viruses with an organic solvent/detergent mixture (S/D). Once the lipid membrane is disrupted, the virus is no longer able to bind to the infected cells.
Cryoprecipitate is a plasma product containing factor VIII and fibrinogen, and can be used for treating patients who lack factor VIII and fibrinogen and have bleeding or hemophilia.
Tris is an abbreviation for Tris hydroxymethyl aminomethane.
Aqueous phase solvent refers to water or an aqueous solution of a non-organic phase.
The room temperature means 25. + -. 2 ℃.
The purification method provided by the invention is simple and convenient to operate, low in cost and good in industrial application prospect.
The buffer solution consisting of the balance buffer solution, the washing buffer solution and the elution buffer solution is used for purifying the human fibrinogen by matching with the filler for ion exchange chromatography, so that the content and the purity of the human fibrinogen in the obtained product can be obviously improved, and the virus inactivating agent residue in the product can be obviously reduced. The buffer solution and the filler for the ion exchange layer provided by the invention have good application prospects in purification of human fibrinogen.
Obviously, many modifications, substitutions, and variations are possible in light of the above teachings of the invention, without departing from the basic technical spirit of the invention, as defined by the following claims.
The present invention will be described in further detail with reference to the following examples. This should not be understood as limiting the scope of the above-described subject matter of the present invention to the following examples. All the technologies realized based on the above contents of the present invention belong to the scope of the present invention.
Drawings
FIG. 1 is a linear elution chromatogram. Wherein the abscissa is the chromatography volume; the ordinate is the percentage of liquid in pump B in the elution buffer; the blue curve is the UV280 absorption value; a green line parallel to the ordinate is the indicator line indicating that the percentage of liquid in pump B in the elution buffer here is 10%; the green curve is the percentage of the B pump; the brown curve is the conductance.
Detailed Description
The raw materials and equipment used in the invention are known products and are obtained by purchasing commercial products.
Example 1 purification of human fibrinogen
The first step is as follows: preliminary purification
1. Taking a cryoprecipitate prepared from fresh frozen plasma, and adding the cryoprecipitate into a Tris buffer solution with the weight ratio of 1:3 and the pH value of 6.8 at room temperature for dissolving to obtain a cryoprecipitate dissolving solution;
2. adding aluminum hydroxide (the amount of the aluminum hydroxide is 2wt.% of the cryoprecipitate) into the cryoprecipitate dissolving solution, and stirring for 15 minutes at room temperature to perform adsorption treatment;
3. centrifuging the system obtained after adsorption for 20 minutes at 4000g, taking the supernatant, filtering the supernatant through a 0.45-micrometer filter membrane, and keeping the filtrate;
the second step is that: inactivation of viruses
Performing virus inactivation on the obtained filtrate according to an S/D method: and (3) adding polysorbate 80 (the dosage of the polysorbate 80 is 1wt.% of the filtrate) and tributyl phosphate (the dosage of the tributyl phosphate is 0.3wt.% of the filtrate) into the filtrate obtained in the first step, and inactivating the mixture at 25 ℃ for 6 hours to obtain a sample to be loaded on the column.
The third step: anion exchange chromatography purification
Fractogel EMD DEAE (M) is used as anion exchange chromatography packing to purify a sample to be loaded on a column, and the method comprises the following specific steps:
and (2) balancing the anion exchange chromatography packing Fractogel EMD DEAE (M) with 10 times of column volume of an equilibrium buffer solution, loading the to-be-loaded column sample obtained in the second step onto the column, eluting the chromatography column with the washing buffer solution, eluting with the elution buffer solution, and collecting the eluent to obtain the human fibrinogen solution.
Wherein the balance buffer solution is a Tris buffer solution with the concentration of 5mM and the pH value of 8.5; the pH value of the washing buffer solution is 8.5, the washing buffer solution consists of NaCl and Tris aqueous solutions, the concentration of NaCl in the washing buffer solution is 30mM, and the concentration of Tris in the washing buffer solution is 5mM; the elution buffer pH was 8.5 and consisted of an aqueous solution of NaCl and Tris, with the NaCl concentration being 100mM and the Tris concentration being 5mM.
Example 2 buffer for ion exchange chromatography for purification of fibrinogen
The buffer solution for ion exchange chromatography for purifying fibrinogen in this example consists of an equilibration buffer solution, a washing buffer solution and an elution buffer solution, wherein the equilibration buffer solution is a Tris buffer solution with 5mM and pH of 8.5; the pH value of the washing buffer solution is 8.5, the washing buffer solution consists of a NaCl aqueous solution and a Tris buffer solution, the concentration of NaCl in the washing buffer solution is 30mM, and the concentration of Tris in the washing buffer solution is 5mM; the elution buffer has a pH of 8.5, and consists of an aqueous NaCl solution and a Tris buffer, wherein the concentration of NaCl in the elution buffer is 100mM, and the concentration of Tris in the elution buffer is 5mM.
Example 3 ion exchange chromatography composition for purifying fibrinogen
This example ion exchange chromatography composition for purifying fibrinogen consisted of the following two components:
component 1: buffer for ion exchange chromatography for purifying fibrinogen described in example 2;
and (2) component: packing for ion exchange chromatography: fractogel EMD DEAE (M).
The advantageous effects of the present invention will be described below by way of experimental examples.
Experimental example 1 evaluation of adsorption Effect
1. Experimental method
The filtrates obtained by the first step of the cold precipitation and adsorption treatment in example 1 were used as test samples to test the purity of human fibrinogen and the adsorption effects of blood coagulation factors II, VII, IX and X in the samples before and after the initial purification.
2. Results of the experiment
TABLE 1 human fibrinogen and adsorbed coagulation factors II, VII, IX, X (n = 3) in samples before and after primary purification
Test index Before preliminary purification After preliminary purification
Protein content mg/ml (n = 8) 34.65 33.01
The content of coagulable protein is mg/ml (n = 8) 21.88 21.49
Purity% (n = 8) 63.15 65.10
FII IU/ml(n=2) 0.32 0.11
FVII IU/ml(n=2) 0.54 0.08
FIX IU/ml(n=2) 0.85 0.23
FX IU/ml(n=2) 0.13 0.04
In table 1, protein content refers to the total protein content in the sample; the content of the coagulable protein, namely the content of human fibrinogen, and the test method comprises the following steps: incubating the sample with a thrombin solution, separating the precipitate, and determining the protein content, namely the content of the coagulable protein; purity is the percentage of coagulable protein content in the sample.
As can be seen from the results in Table 1, the method of the invention can primarily improve the purity of human fibrinogen after the adsorption treatment by aluminum hydroxide, and the process has excellent removal effect on blood coagulation factors FII, VII, IX and X which affect the stability of human fibrinogen.
Experimental example 2 evaluation of Virus inactivation Effect
1. Experimental methods
The sample to be subjected to virus inactivation obtained in the second step of example 1 was used as a test sample to evaluate the virus inactivation effect.
2. Results of the experiment
TABLE 2 SD Virus inactivation Effect (n = 3)
Indicative of virus PRV virus Sindbis virus HIV virus
Inactivating effect ≥4.75logTCID 50 /ml ≥4.02logPFU/ml ≥5.5logTCID 50 /m
As can be seen from the results in Table 2, the method of the present invention for SD virus inactivation can effectively inactivate lipid enveloped viruses, and achieve the national standard.
EXAMPLE 3 chromatography Medium screening experiment
1. Experimental methods
The procedure of example 1 was followed except that the anion exchange chromatography packing in the third step was replaced with Capto Q, fractogel EMD TMAE (M) or Fractogel EMD DEAE (M) in table 3. The gel loading and yield were compared when the three anion exchange chromatography packing materials were used separately.
The gel loading refers to the amount of target protein that can be adsorbed by the gel, and the higher the loading, the better the adsorption effect, and the less gel is needed to separate a sample of the same volume. The yield is the ratio of the target protein obtained by removing impurities such as foreign proteins in the chromatography step to the target protein before chromatography.
Gel loading = (upper column sample volume x protein concentration)/chromatography column volume;
note: the sample volume on the column refers to the volume from the beginning of loading to the obvious rise of the ultraviolet absorption peak and the appearance of a large amount of protein flowing through.
Yield = total amount of fibrinogen in post-chromatography sample/total amount of fibrinogen in pre-chromatography sample.
2. Results of the experiment
TABLE 3 chromatographic Medium screening test results
Figure BDA0003244327460000061
As can be seen from Table 3, the gel loading of the three chromatographic packings is Fractogel EMD DEAE (M) > Fractogel EMD TMAE (M) > Capto Q in sequence from large to small, and the yield is Fractogel EMD TMAE (M) > Fractogel EMD DEAE (M) > Capto Q in sequence from large to small. In terms of balanced consideration of both loading capacity and yield, fractogel EMD TMAE (M) requires a larger chromatography gel volume, is higher in cost, inconvenient to operate and not suitable for large-scale production, so Fractogel EMD DEAE (M) is selected as a purification chromatography medium.
EXAMPLE 4 elution buffer screening experiment
1. Experimental methods
The procedure of example 1 was followed, except that the NaCl concentration in the elution buffer of the third step was changed, and a linear gradient elution was performed, which was specifically performed by:
the liquid (pH 8.5) in pump A was 5mM Tris buffer, and the liquid (pH 8.5) in pump B was composed of Tris buffer and aqueous NaCl, with a Tris concentration of 5mM and a NaCl concentration of 1M. And taking the liquid obtained by mixing the pump A and the pump B as an elution buffer solution, gradually increasing the proportion of the liquid in the pump B in the elution buffer solution, and performing linear gradient elution.
2. Results of the experiment
The chromatogram is shown in figure 1, and the detection shows that a hetero-protein peak appears when the proportion of the liquid in the B pump is 3% -4%, and the elution peak obtained when the proportion of the liquid in the B pump reaches 10% is rich in human fibrinogen. Therefore, when the liquid in the B pump in the elution buffer solution reaches 10%, the elution solution rich in human fibrinogen can be obtained. Here, the concentration of Tris was 5mM and the concentration of NaCl was 100mM, respectively, in the elution buffer.
Experimental example 5 verification experiment for purification Effect of human fibrinogen
1. Experimental methods
Test samples: purified human fibrinogen (i.e., post-chromatography sample) prepared in the third step of inventive example 1; the sample to be loaded on the column (i.e. the sample before chromatography) obtained in the second step of example 1 of the present invention.
The following criteria were tested:
coagulable protein (i.e., human fibrinogen) content: incubating the sample and thrombin solution, separating precipitate, and determining protein content, namely the content of coagulable protein;
purity: percent coagulable protein content in the sample;
yield of coagulable protein: percentage of total amount of coagulable protein of the sample after chromatography and before chromatography;
polysorbate 80 residue: measuring by a colorimetric method;
tributyl phosphate residue: and (4) measuring by gas chromatography.
2. Results of the experiment
Table 4 human fibrinogen purification effect (n = 8)
Test index Pre-chromatography samples Post-chromatography samples
Content of coagulable protein (mg/ml) 3.81±0.27 4.35±0.51
Purity (%) 63.29±0.05 72.99±0.06
Yield of coagulable protein / ~70
Polysorbate
80 residual mu g/ml 1000 28.13±2.47
Residual mu g/ml of tributyl phosphate 300 Not detected out
In table 4, the coagulable protein refers to human fibrinogen in the product.
As can be seen from Table 4, the content and purity of human fibrinogen in the product purified by the method of the present invention are significantly improved, and the yield is also higher; meanwhile, the purification method of the invention can obviously reduce the virus inactivator residue, and tributyl phosphate is not detected in the obtained product.
In summary, the present invention provides a buffer and a filler for an ion exchange layer for purifying human fibrinogen. Experimental results show that the buffer solution consisting of the balance buffer solution, the washing buffer solution and the elution buffer solution is used for purifying the human fibrinogen in cooperation with the filler for ion exchange chromatography, so that the content and the purity of the human fibrinogen in the obtained product can be obviously improved, and the virus inactivating agent residue in the product can be obviously reduced. The buffer solution and the filler for the ion exchange layer provided by the invention have good application prospects in purification of human fibrinogen.

Claims (6)

1. Use of a composition for ion exchange chromatography comprising the following two components in reducing tributyl phosphate residue in fibrinogen:
component 1: buffer solution for ion exchange chromatography; the buffer solution for ion exchange chromatography comprises an equilibrium buffer solution, a washing buffer solution and an elution buffer solution; the balance buffer solution is a 5mM Tris buffer solution, and the pH value of the balance buffer solution is 8.5; the washing buffer solution consists of aqueous solution of NaCl and Tris, wherein the concentration of NaCl is 30mM, the concentration of Tris is 5mM, and the pH value of the washing buffer solution is 8.5; the elution buffer consists of an aqueous solution of NaCl and Tris, wherein the concentration of NaCl is 100mM, the concentration of Tris is 5mM, and the pH of the elution buffer is 8.5;
and (2) component: the filler for ion exchange chromatography is polymethacrylate anion exchange resin;
the method for reducing tributyl phosphate residue in fibrinogen comprises the following steps: balancing chromatography packing with a balance buffer solution, loading the fibrinogen subjected to virus inactivation onto a column, eluting with a washing buffer solution, eluting with an elution buffer solution, and collecting the eluate to obtain purified fibrinogen;
the fibrinogen after virus inactivation is prepared by the following method:
(a) Taking the cryoprecipitate, adding a water phase solvent for dissolving to obtain a cryoprecipitate dissolved solution;
(b) Adsorbing the cold precipitation solution with aluminum hydroxide, centrifuging, collecting supernatant, filtering, and retaining filtrate;
(c) Adding polysorbate 80 and tributyl phosphate into the filtrate, and inactivating to obtain virus-inactivated fibrinogen.
2. Use according to claim 1, characterized in that: the filler for ion exchange chromatography is selected from Capto Q, fractogel EMD TMAE (M) or Fractogel EMD DEAE (M).
3. Use according to claim 2, characterized in that: the filler for ion exchange chromatography is Fractogel EMD DEAE (M).
4. Use according to claim 1, characterized in that: in step (a), the cryoprecipitate is prepared from fresh frozen plasma; the aqueous phase solvent is Tris buffer solution;
and/or in the step (b), the dosage of the aluminum hydroxide is 1 to 5wt.% of the cold precipitation, the adsorption time is 10 to 20 minutes, and the adsorption temperature is 20 to 35 ℃;
and/or in the step (c), the dosage of polysorbate 80 is 0.5wt.% to 2.0wt.% of the filtrate, the dosage of tributyl phosphate is 0.1wt.% to 0.5wt.% of the filtrate, the inactivation time is 4~8 hours, and the inactivation temperature is 24 ℃ to 26 ℃.
5. Use according to claim 4, characterized in that: in the step (a), the aqueous phase solvent is a Tris buffer solution with the pH value of 10-30mM and the pH value of 6.0-7.5;
and/or, in step (b), the amount of aluminium hydroxide is 2wt.% of the cryoprecipitate, the adsorption time is 15 minutes, and the adsorption temperature is 25 ℃;
in the step (c), the mass ratio of polysorbate 80 to tributyl phosphate is 10:3, the polysorbate 80 is used in an amount of 1wt.% of the filtrate, the inactivation time is 6 hours, and the inactivation temperature is 25 ℃.
6. Use according to claim 5, characterized in that: in step (a), the aqueous solvent is 20mM Tris buffer at pH 6.8.
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CN107827974B (en) * 2017-11-10 2021-01-01 中国科学院过程工程研究所 Preparation method of human fibrinogen

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