RU2153889C2 - Hemosorbent regeneration method - Google Patents

Abstract

FIELD: clinical hematology. SUBSTANCE: hemosorbent is treated with 0.1-0.15 N sodium hypochlorite solution at rate 120-150 ml/min on the basis of 500-700 ml sodium hypochlorite per 50 g sorbent, after which sorbent is thermally treated at 160-180 C for 45-60 min. Method is applicable in cases of exo- and endogenous intoxications. EFFECT: reduced mortality and treatment time and cost. 1 dwg, 2 tbl, 3 ex

Description

 The invention relates to medicine and medical chemistry and can be used to treat exo- and endogenous intoxications.

 Given the particular importance of the detoxification of the body associated with environmental pollution, the development of ways to protect the internal environment (homeostasis) of a person from exposure to various kinds of xenobiotics is considered an urgent task of our time. According to WHO data for 1991, more than 100 thousand xenobiotics enter the internal environment of a person, which, after chemical transformations (mainly in the liver) form active compounds that cause an increase in the number of chronic and oncological diseases. The group of exogenous toxicosis most often includes acute poisoning with various chemical agents, which includes about 30% of patients entering the intensive care unit of city hospitals. In Russia, the urgency for acute poisoning at an ambulance station is more than 5 people per 1000 population per year, and half of them require urgent hospitalization.

 Under these conditions, the importance of sorption detoxification methods suitable for use in any intensive care unit and even at the prehospital stage can hardly be overestimated (Gorchakov V.D., Sergienko V.I., Vladimirov V.G. Selective hemosorbents // M .: Medicine. - 1989; Belyakova N.A. // Enterosorption.- L .: TSST, 1991; Lopukhin Yu.M., Parfenov A.S., Kulaev D.V. Analysis of the mechanisms of the therapeutic effect of hemosorption. Efferent therapy. - 1995. - N 1. - S.14-18).

 To date, hemosorption (HS) is considered to be one of the most effective methods of detoxification, the inherent attribute of which is the use of sorbents of various chemical nature. Clinical experience with hemosorption has shown that in terms of the rate of elimination of toxic substances from the blood, it is significantly superior to other methods of artificial detoxification of the body and allows the removal of substances of different physicochemical nature from the blood. The high detoxification and sorption properties of this method have found wide application in the complex of therapeutic measures for a variety of diseases, even in situations where all other therapeutic measures have been ineffective or have not brought success. However, despite the indisputable advantages of sorption methods of detoxification of the body, at present they are not widely used due to the large deficit and high cost of hemosorbents, which naturally affects the results of treatment of this contingent of patients. It is known that many sorption methods of detoxification are used for a long time; therefore, it is also important to find ways to reduce the cost of treatment.

 Based on the foregoing, one of the possible ways to overcome this situation in the treatment of exo- and endogenous intoxications is the regeneration of previously used hemosorbents.

 In this regard, the search for ways to develop an effective technology for the regeneration of used hemosorbents at the present time is an extremely urgent task.

 Currently, various methods for the regeneration of industrial sorbents are known.

A well-known method for the regeneration of sorbents is the method of regeneration of activated carbon after sorption of organic substances, when by maintaining activated carbon for 1-240 minutes at a temperature of 100 - 900 ^o C in an atmosphere containing 0.01 - 50% oxygen or another oxidizing agent, the adsorption process coal of organic material and partial oxidation of sorbed organic matter (Ishibashi Itiji et al. Pat. N 54-18995 (Japan) on "Method for the regeneration of activated carbon". - 1979).

There is also known a method of electrochemical regeneration of activated carbon by electric current (current density 40 - 45 A / m ² ) using H ₂ SO ₄ + H ₂ O as an electrolyte at a temperature of 75-85 ^o C, for 1.5-2.5 hours (Tarhovskaya I .A. Et al., AS USSR No. 1528728 on "Method for the electrochemical regeneration of activated carbon", published in B.I. N 46 of 12.15.89).

 The disadvantages of the presented analogues include the high complexity, multi-stage process, work in harmful production conditions using concentrated acid and expensive equipment.

 Thus, the lack of effectiveness of the currently used methods for the regeneration of medical sorbents necessitates the search and development of simple, environmentally friendly and effective technologies for the regeneration of hemosorbents suitable for use in medical practice.

 As a prototype, we have chosen a method for regenerating a carbon sorbent by sequentially passing through it a physiological solution of sodium hydroxide and an aqueous or aqueous-alcoholic solution of sodium chloride, followed by passing demineralized water and activating water vapor (RF Patent 2056351 C1 of 03.20.96, cl. C 01 B 31/08).

 The disadvantages of the prototype include: the complexity and duration of the process.

 The technical result is an original technology, an original technology of the process of regeneration of hemosorbents with sodium hypochlorite (GHN) in a dynamic mode, which will allow to obtain the maximum regenerating effect.

Technical novelty is the treatment of hemosorbents 0.1 - 0.15 N. a solution of sodium hypochlorite at a rate of 120 - 150 ml / min, based on 500 - 700 ml of sodium hypochlorite per 50 g of sorbent, followed by heat treatment of hemosorbents at a temperature of 160 - 180 ^o C for 45 - 60 minutes

 Our choice of sodium hypochlorite (GHN) as a regenerating agent is environmentally friendly, much cheaper than other known regenerating agents, it is easy to prepare, and does not require expensive equipment.

To achieve this goal, the following tasks were solved:
1. Creation of an experimental setup for conducting experiments on the regeneration of hemosorbents under conditions of dynamic treatment with sodium hypochlorite.

2. Selection of optimal concentrations of sodium hypochlorite solution under conditions of dynamic regeneration of hemosorbents;
3. Selection of optimal volumetric ratios of hemosorbent / sodium hypochlorite solution under conditions of dynamic regeneration of hemosorbents.

 To improve the technology and increase the efficiency of regeneration of previously used hemosorbents, an experimental setup was created for their processing with sodium hypochlorite in a dynamic mode (see drawing).

 The advantages of dynamic regeneration of hemosorbents include, first of all, the simplicity of the execution technology and the high regeneration rate, which can significantly reduce the time for the process technology by reducing the duration of the first stage of the process (oxidation of the sorbent GHN). In addition, the proposed technology for the regeneration of hemosorbents allows you to work with large volumes of sorbents, to avoid preliminary opening of the sorption columns and to be carried out in a closed loop. All this brings this technology as close as possible to the industrial scale of production.

The invention consists in the following: hemosorbent is treated with 0.1-0.15 N. GHN solution at a speed of 120-150 ml / min in dynamic mode, based on 500-700 ml of sodium hypochlorite per 50 g of sorbent, followed by heat treatment of hemosorbents at a temperature of 160-180 ^o C for 45-60 minutes

The method is as follows: using the proposed experimental setup to increase the efficiency of regeneration of previously worked out hemosorbents, 500-700 ml of 0.1-0.15 N are first passed through 50 g of a sample in flow mode. GHN solution at a speed of 120-150 ml / min, after which the sorbent is washed with distilled water (at least 1500 ml) until a negative result on hypochlorite anion is obtained in the wash water. Then washed hemosorbent is subjected for 45-60 minutes to a harsh heat treatment at a temperature of 160-180 ^o C.

Sodium hypochlorite is obtained by electrolysis of a solution of sodium chloride on the apparatus of an electrochemical detoxifier of the body (EDO-3). The concentration of sodium hypochlorite is controlled by iodometric titration. For heat treatment of hemosorbents, a TS-80 drying oven is used. The range of temperature conditions used ranged from 160-200 ^o C.

 In the experiment, dynamic experiments were carried out on the regeneration of 4 carbon hemosorbents by sodium hypochlorite: SIMPLEX-F, SUMS-1, VNIITU-1 and HEMOSPHERE, followed by a study of their sorption capacity. The degree of hemosorbent regeneration is estimated by the change in the concentration of sodium thiosulfate, which we have chosen as a marker-sorbate.

 The experiments were carried out 5 times or more, followed by statistical processing of the obtained data.

 In the table. 1 and further on, the degree of sorption of regenerated hemosorbents is presented as a percentage of the degree of sorption of the initial hemosorbents. As can be seen from the table. 1, the optimal recovery of the sorption capacity of the previously used carbon hemosorbent VNIITU-1 occurred after processing it in a flow mode of 0.1-0.15 n. a solution of sodium hypochlorite in a volume of 500 ml. With a decrease in the concentration and volume of the sodium hypochlorite solution relative to the above figures, the degree of hemosorbent regeneration decreases. The decrease in the flow rate of GHN does not produce a fluidized bed. An increase in the concentration of sodium hypochlorite reduces the adsorption capacity, which indicates the destruction of the active sites of hemosorbent, which is manifested by a change in the color of the solution. Increasing the flow rate reduces the degree of regeneration of the sorbent.

 Thus, the results obtained allow us to study the relationship between the temperature regime of treatment and the degree of regeneration of the studied hemosorbents (table. 2).

As can be seen from the table. 2, the optimal degree of regeneration of previously used hemosorbents is achieved with a 45-60 minute heat treatment in the mode of 160-180 ^o C, which allows to guarantee the destruction of hepatitis A, B, C viruses and HIV infection.

 Attempts to reduce the temperature and time of heat treatment lead to a decrease in the degree of regeneration of hemosorbents, and an increase in the duration of heat treatment and an increase in temperature reduces the adsorption capacity, which indicates the destruction of the active sites of hemosorbent, which is manifested by a change in the color of the solution.

 Similar results on the restoration of the sorption capacity with sodium hypochlorite were obtained during dynamic regeneration of the remaining 3 carbon hemosorbents: SIMPLEX-F, SUMS-1 and HEMOSPHERE.

 Considering that the blood plasma contains more than 100 types of proteins and that the sorbate located in the pores of hemosorbents is mainly protein in nature, a study of wash water after the last stage of regeneration for the presence of protein has been carried out. When determining the purity of the regenerated hemosorbents from the secondary products of oxidation and thermal treatment of plasma proteins, a negative reaction to the protein was obtained, which confirms the complete desorption of organic substances from the studied hemosorbents.

 A study of the hemocompatibility of regenerated hemosorbents on 10 samples of donated blood showed that during a 30-minute perfusion of 400 ml of donated blood through a VNIITU-1 hemosorbent column, the number of red blood cells decreases by 10.2 ± 3% (p <0.05). The decrease in the amount of total protein on regenerated hemosorbents is not significant compared with the original brand of hemosorbent.

 To assess the detoxifying properties of the regenerated hemosorbents, a 10-dog hexenal sleep model was selected (G.D. Rozin, Comparative Assessment of the Toxicity of Chloro Derivatives of the Fatty Hydrocarbon Series from the White Mouse Mice Hexenal Test // Pharm. And Toxicol. 1964. - N 5. - P. 613-614). The model was reproduced by intravenous administration of hexenal at the rate of 0.04 g / kg of animal body weight. Normally, the duration of hexenal sleep in dogs was 105 ± 10 min.

 Hemosorption is carried out on the VNIITU-1 hemosorbent using the UAG-01 apparatus at a speed of 40-50 ml / min, the sorbent volume is 50 ml. Connection is carried out along the venous-venous circuit. To prevent thrombosis before hemosorption, heparin is administered intravenously at a dose of 500 IU / kg. At the end of hemosorption, the effect of heparin is neutralized by the intravenous administration of protamine sulfate at the rate of 1.5 mg per 1 mg of heparin. Hemosorption is stopped after the appearance of a stable corneal reflex.

 In the experiment, 5 dogs were used in the control and experimental groups. Hemosorption was carried out on the initial and regenerated sorbent SUMS-1 (50 ml).

 Studies on the degree of detoxification during hemosorption on regenerated and initial sorbents show a similar decrease in sleep duration by 51% compared to sleep duration in intact animals.

 Similar results were obtained on other regenerated samples of hemosorbents.

 Thus, the materials of bench and experimental experiments on the proposed technology for the regeneration of hemosorbents presented in this application indicate a fundamentally new approach to the problem of increasing the detoxifying properties of hemosorbents and open up prospects for their repeated use in clinical practice for the treatment of a wide range of diseases.

 The developed technology is highly economical and simple enough to establish production capacities.

 The method is illustrated by the following examples.

EXAMPLE 1. Using the proposed experimental setup for the regeneration of previously used sorbents, 500 ml of 0.1 N was passed through a sample of 50 g of carbon hemosorbent VNIITU-1 using the UAG-01 apparatus in a flow mode. sodium hypochlorite solution. Then, 1500 ml of distilled water was passed through the sorbent. The method of iodometric titration in the wash water determined the presence of hypochlorite anion until a negative result was obtained. After that, the washed sorbent was subjected to severe heat treatment (at a temperature of 180 ^° C) for 45 minutes, followed by its control for the degree of regeneration.

 The methodology for determining the degree of regeneration of the carbon sorbent is as follows: 5 g of the studied sample of hemosorbent, which is a representative sample (i.e., selected according to the law of quarting), was filled with 50 ml of distilled water and incubated for 10 min. After that, distilled water was drained and 50 ml of 0.1 N was added to a sample of hemosorbent for 30 min. sodium thiosulfate solution. After the incubation time, the sodium thiosulfate solution was discharged and its concentration was determined by the method of reverse iodometric titration. Then, a portion of the hemosorbent was washed three times within 30 minutes with 200 ml of distilled water, treated for 30 minutes, 50 ml of 0.1 N. GHN solution, with subsequent determination of its concentration in the wash-off waters. After that, the sample was washed three times with distilled water and 50 ml of 0.1 N was added to it. sodium thiosulfate solution. The concentration of sodium thiosulfate solution was determined by reverse iodometric titration after 30 min of incubation with a sorbent.

 As a result of the experiment, the sorption capacity of the carbon hemosorbent VNIITU-1 was restored by 108.0 ± 2.9% (Tables 1, 2).

EXAMPLE 2. Using the proposed experimental setup for the regeneration of previously used sorbents, 500 ml of 0.15 N was passed through a sample of 50 g of carbon hemosorbent VNIITU-1 using the UAG-01 apparatus in a flow mode. GHN solution. Then, 1500 ml of distilled water was passed through the sorbent. The method of iodometric titration in the wash water determined the presence of hypochlorite anion until a negative result was obtained. After that, the washed sorbent was subjected to severe heat treatment (at a temperature of 180 ^° C) for 60 minutes, followed by its control for the degree of regeneration.

 As a result of the experiment, the sorption capacity of the carbon hemosorbent VNPITU-1 was restored by 105.2 ± 1.6% (Tables 1, 2).

EXAMPLE 3. Using the proposed experimental setup for the regeneration of previously used sorbents, 700 ml of 0.05 N was passed through a weighed 50 g of carbon hemosorbent VNIITU-1 using the UAG-01 apparatus in a flow mode. GHN solution. Then, 1500 ml of distilled water was passed through the sorbent. The method of iodometric titration in the wash water determined the presence of hypochlorite anion until a negative result was obtained. After that, the washed sorbent was subjected to severe heat treatment (at a temperature of 180 ^° C) for 60 minutes, followed by its control for the degree of regeneration.

 As a result of the experiment, the sorption capacity of the carbon hemosorbent VNIITU-1 was restored at 89.5 ± 1.2% (Tables 1, 2).

 Medical and social effectiveness. The invention will help to increase the effectiveness of treatment of patients with exo- and endogenous intoxications, reduce the mortality rate, reduce the time and cost of treatment.

Claims (1)

A method for the regeneration of hemosorbents, including desorption of hemosorbents with solutions, characterized in that the hemosorbents are treated with 0.1 - 0.15 N sodium hypochlorite solution at a rate of 120-150 ml / min at the rate of 500-700 ml sodium hypochlorite per 50 g of sorbent, followed by heat treatment hemosorbents at a temperature of 160 - 180 ^o C for 45 - 60 minutes

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