RU2123860C1 - Affine sorbent for removal of tumor necrosis factor and method of its preparing - Google Patents

Abstract

FIELD: medicine, sorbents. SUBSTANCE: affine sorbent has a carrier containing an immobilized human α₂--macroglobulin. Method of a sorbent preparing involves immobilization of human α₂--macroglobulin at pH 7.0-8.2 followed by its treatment with thio-ester loop modifying agent. The latter is monomethylamine hydrochloride or proteolytic enzyme plasmin of human blood plasma. Invention can be used for development of new approaches to treatment of patients with sicknesses caused by massive inflow of cytokines in blood, for example, as a result of septic shock. EFFECT: improved method of sorbent preparing, enhanced effectiveness of sorbent. 4 cl, 4 ex

Description

 The invention relates to medicine and may find application in the development of new approaches to the treatment of diseases caused by massive influx of cytokines into the blood, for example, septic shock.

 The closest in essence to the proposed sorbent for removing the tumor necrosis factor and the method for its production are the affinity sorbent and the method for producing the sorbent described in [1].

 The affinity sorbent contains a carrier onto which monoclonal antibodies to the tumor necrotizing factor (TNF) are immobilized.

 A method of obtaining an affinity sorbent provides for the immobilization of protein on a carrier. Monoclonal antibodies to TNF were used as the protein.

 Monoclonal antibodies are a protein foreign to the human body. The effect of "leakage" of monoclonal antibodies from the carrier during the procedure of removal of tumor necrosis factor may lead to sensitization and a number of other undesirable effects during treatment procedures. In addition, the high cost and complexity of obtaining monoclonal antibodies to TNF makes it virtually impossible to use this sorbent in a clinical setting.

 The invention is aimed at improving the affinity sorbent for removing tumor necrosis factor and developing a method for its production. At the same time, the clinical use of the sorbent is ensured by eliminating the influence of the ingress of a protein alien to the body into the blood.

 Tumor necrosis factor (tumor-criticalizing factor) is one of the endogenous pyrogens, it can cause hypotension, significant metabolic changes (increased carbohydrate metabolism, depletion of energy reserves, loss of lipids by adipocytes). The mechanisms of direct action of TNF is also an increase in the expression of adhesive molecules on the surface of the endothelium for blood leukocytes, in particular for granulocytes, with which the development of granulocytopenia can be associated. In addition, TNF mediates leaky capillary syndromes and disseminated intravascular coagulation.

 The essence of the invention is as follows.

The affinity sorbent for removal of tumor necrosis factor is a carrier onto which α ₂ - human macroglobulin is immobilized.

A method of obtaining an affinity sorbent for removing tumor necrosis factor involves the immobilization of protein on a carrier. As a protein, human α ₂ -macroglobulin is used, which is immobilized at a pH of 7.0 ... 8.2, and then treated with a thiol ether loop modifier.

The main task in the "landing" of α ₂ -macroglobulin on the carrier was to obtain the drug in its native form, which subsequently made it possible to modify the protein, making it suitable for removal (sorption) of TNF-α from solutions.

The results of our experiments showed that the main, decisive factor in the "landing" is the choice of pH-medium, in which there is an "attachment" of α ₂ -macroglobulin to the carrier. At a pH below 7.0, the amount (percentage of “sewing”) of sorbed α ₂ -macroglobulin is markedly reduced, and at a pH below 6.0, protein is irreversibly denatured.

When using buffers with a pH above 8.2, despite a high percentage of “crosslinking” (less than 5% of the initial amount of protein remains in the solution), such changes in the conformation of the protein occur that significantly change its properties. So, for example, such preparations of immobilized α ₂ -macroglobulin are not able to bind proteolytic enzymes. The effectiveness of using these drugs for further modification and removal of TNF is less than 10% of the optimal obtained at pH buffers 7.0 ... 8.2. The effectiveness of "sewing" at the indicated pH values averaged 96 ± 0.8%, which allows us to consider the above pH values to be optimal.

After immobilization, the α ₂ human macroglobulin is treated with a thiol ether loop modifier.

A thiol ether loop modifier may be, for example, a chemical agent selected from the group of primary amines, or a proteolytic enzyme capable of binding to α ₂ macroglobulin.

When processing α ₂ -macroglobulin adsorbed on a carrier by the indicated agents, a thiol ether loop breaks in the α ₂ -macroglobulin molecule, which leads to its transition to the F form (Fost form), and it acquires the ability to bind TNF.

Removal of TNF using immobilized α ₂ -macroglobulin is possible with sufficient strength of interaction between them.

 The invention is implemented as follows.

 Example 1. For the construction of the sorbent used sepharose 4B CL (Pnaracia, Sweden), which was activated with cyanogen bromide (Fluka, Germany), as indicated in [2].

As an affinity ligand, a preparation of human α ₂ macroglobulin with a concentration of 1.5 mg / ml was used. The preparation was obtained from donated human citrate plasma by repeated gel filtration on a TSC-60 HW column and ion exchange chromatography on DEAE cellulose. The purity of the drug was over 95% according to enzyme tests and EF in PAG. Before "landing" the preparation of α ₂ -macroglobulin was transferred to 0.15 M phosphate buffer pH 7.0, containing 0.5 M NaCl. The procedure of covalent “sewing” of protein was carried out.

собирали промывочный буфер, определяли его объем и концентрацию белка микробиуретовым методом. Расчет баланса позволял судить о количестве ковалентно связавшегося α₂ -макроглобулина. Далее проводили блокировку оставшихся активных групп 0,5 М глицином в 0,15 М фосфатном буфере с 0,5 M NaCl pH 7,9. Процедура занимала 2 часа при комнатной температуре и постоянном перемешивании на роторной мешалке. Окончательную отмывку сорбента осуществляли на фильтре Шотта, попеременно пропуская по 200 мл буферных растворов (0,1 Глицин-HCl буфер pH 3,0±0,1 и 0,15 М фосфатный буфер с 0,5 М NaCl pH 7,9±0,1). Смену буферов проводили 5 раз. Готовый сорбент помещали в 0,15 М фосфатный буфер pH 7,2 ± 0,1.After activation and washing with ice-cold distilled water on a Schott filter, Sepharose was added to a solution of α ₂ -macroglobulin in a volume equal to the volume of the protein solution. The mixture was incubated for 2 hours at t = 18-20 ^o C, and then 16 hours at t = 4 ^o C, constantly stirring on a rotary mixer. After a series of washes of the sorbent on a Schott filter

washing buffer was collected, its volume and protein concentration were determined by the microbiuret method. The calculation of the balance made it possible to judge the amount of covalently bound α ₂ -macroglobulin. Then, the remaining active groups were blocked with 0.5 M glycine in 0.15 M phosphate buffer with 0.5 M NaCl pH 7.9. The procedure took 2 hours at room temperature and with constant stirring on a rotary mixer. The final washing of the sorbent was carried out on a Schott filter, alternately passing 200 ml of buffer solutions (0.1 Glycine-HCl buffer pH 3.0 ± 0.1 and 0.15 M phosphate buffer with 0.5 M NaCl pH 7.9 ± 0 ,one). Buffers were changed 5 times. The finished sorbent was placed in 0.15 M phosphate buffer pH 7.2 ± 0.1.

The efficiency of covalent binding of α ₂ -macroglobulin on the sorbent was 96%.

 Example 2. Removal of TNF-α from buffered saline (PBS).

 A microcolumn with a volume of 2.0 ml of gel (sorbent) was prepared. The sorbent was obtained by activating Sepharose 4 B CL with cyanogen bromide, followed by conjugation of a protein in 0.15 NaCl at pH 7.9.

The column with immobilized α ₂ -macroglobulin was washed with a 0.5 M solution of monomethylamine hydrochloride for 30 min at 20 ^o C. Then elution was carried out.

Washed column PBS (pH 7.2) for 30 minutes at a speed of 20 ml / hour at 20 ^o C to remove from the sorbent monomethylamine hydrochloride. Then a sample was applied that contained 10,000 units of TNF-α (0.6 μg) in 1 ml of PBS. After applying the sample, the pump was stopped and after 15 minutes of incubation, PBS elution was continued. The total activity of the eluate fractions containing TNF was 800 IU. Thus, the removal efficiency was over 90%.

 Example 3. Removal of TNF-α from human serum.

 Prepared a microcolumn with a volume of 2.0 ml of the gel obtained according to example 2 at a pH of 8.2.

Then, 3.0 ml of donated blood was applied, into which 10,000 units of TNF-α were previously injected.
Chromatography was performed using a PI peristaltic pump (LKB, Sweden) at a rate of 20 ml per hour. The serum circulated in a closed loop for 30 minutes. Then the circuit was opened and the PBS was eluted at the indicated rate. The total activity of TNF-α in the eluate was 555 U, i.e. less than 7% of the original.

 After washing this column from sorbed TNF-α, 0.9 M NaCl and PBS successively applied another serum sample containing 10,000 U of TNF-α. The chromatographic procedure was repeated as described.

 The removal efficiency of TNF-α as a result of the repeated procedure was 91%, i.e. practically did not worsen.

Example 4. In the conditions of example 2, the modification of α ₂ -macroglobulin was carried out by treatment with a solution of the proteolytic preparation fibrinolysin (plasmin), which was taken in double excess with respect to the immobilized α ₂ -macroglobulin (by molarity). The removal of TNF-α from PBS was performed as described in example 1. The removal efficiency of TNF in this experiment was 92%.

Sources of information
1. Wilcher M., Mikon T., Kohr J. In: Methods in Enzymology, Jakoby WB (ed), Academic Press, New York, vol 104. p. 3, 1984.

 2. Affinity chromatography. Methods - M .: Mir, 1988, p. 48-52. Editors P. Dean, W. Johnson, F. Mild.

Claims (4)

1. An affinity sorbent for removing tumor necrosis factor, comprising a carrier on which a protein is immobilized, characterized in that a modified human α ₂ -macroglobulin is used as the protein. 2. A method of producing an affinity sorbent for removing tumor necrosis factor by immobilizing a protein on a carrier, characterized in that human α ₂ -macroglobulin is used as the protein, which is immobilized at pH 7.0 - 8.2, and then treated with a thiol ether modifier loops.  3. The method according to claim 2, characterized in that monomethylamine hydrochloride is used as a thiol ether loop modifier.  4. The method according to claim 2, characterized in that the proteolytic enzyme of human blood plasma is used as a modifier of the thiol ether loop.