RU2466745C1 - Method for improving gas transmission function of long-life donor packed red cells - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: 40-60 minutes before blood transfusion, packed red cells are mixed and then incubated at room temperature with Perftoran. Perftoran is added at 0.8-1.2 ml in 10 ml of packed red cells.

EFFECT: method enables effective and safe transfusion of long-life donor packed red cells ensured by improved gas transmission function, improved blood oxygen capacity, recovered structure and function of donor red cells caused by Perftoran saturation of red cells.

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Description

The invention relates to medicine, namely anesthesiology - resuscitation, surgery and transfusiology.

Anemia is a common problem in patients in intensive care units. The main way to correct anemia is to transfuse red blood cells. The ultimate goal of blood transfusion is to increase the delivery and consumption of oxygen.

It has been shown that erythrocyte mass with a shelf life of <4 days restores oxygen consumption in oxygen-dependent animals, as opposed to a red blood mass with a shelf life of 28 days [Futzgerald RD et al., Transfusions red blood cells stored in citrate phosphate dextrose adenine-1 for 28 days fails to improve tissue oxygenation in rats. Crit Care Med 1997; 25: 726-32], which is associated with changes in donated blood during storage. The erythrocyte mass with a long shelf life has a reduced level of ATP, 2,3-DPH, as well as low rheological parameters, which reduces the availability of oxygen to tissues, despite the increase in its delivery. The weakened functionality of red blood cells of the “old” blood is one of the reasons for the insufficient increase in oxygen consumption or its absence after blood transfusion, which was demonstrated by clinical studies [Hebert PC, McDonald BJ, Tinmouth A. Clinical consequences of anemia and red cell transfusion in the critically ill. Crit Care Clin 2004; 20: 225-35].

There is a method of “revitalizing" donor blood with an expiring shelf life, which consists in treating red blood cells with special solutions containing glucose, pyruvate, inosine, phosphate and adenine, which helps to restore the content of ATP and 2,3-DPH in red blood cells [Lockwood WB et al. Effects of rejuvenation and frozen storage ob 42-day-old AS-3 RBCs. Transfusion, November 1, 2003; 43 (11): 1527-32]. It was also shown that the use of a “revitalizing” solution has a positive effect on the morphology of red blood cells [Usry RT, Moore GL, Manalo FW. Morphology of stored, rejuvenated human erythrocytes. Vox Sang, January 1, 1975; 28 (3): 176-83]. However, in practice, this method is applied only to expired red blood cells, and the effectiveness of this “rejuvenation” method was evaluated only by measuring some metabolic parameters in vitro, that is, in a package, without assessing the oxygen transport function of red blood cells in vivo, those. at the recipient.

Closest to the proposed method for improving the gas transport function of a donor erythrocyte mass of long-term storage is a method of improving tissue oxygenation after blood transfusion using a "rejuvenating" solution for erythrocytes of long-term storage [Raat NJ et. al. Rejuvenation of stored human red blood cells reverses the renal microvascular oxygenation deficit in an isovolemic transfusion model in rats. Transfusion, March 1, 2009; 49 (3): 427-4]. In this experimental work, we used a model of isovolemic transfusion of red blood cells with a shelf life of up to 3 days and a shelf life of 5 to 6 weeks, some of which were incubated with a solution of Rejuvesol containing glucose, pyruvate, inosine, phosphate and adenine. The oxygen concentration in the microvessels of the kidneys was determined before and after transfusion. It was shown that during the transfusion of "old" red blood cells treated with a "revitalizing" solution, oxygen debt in the tissues did not develop, in contrast to the transfusion of "old" red blood cells not treated with a solution.

The disadvantage of this method is that the “anti-aging” solution itself is not intended for intravenous use. If the solution enters the recipient's body, the development of adverse reactions associated with intolerance to one of its components is possible. Therefore, after thermal incubation with the “revitalizing” solution, the red blood cells are washed, which requires special equipment and additional time.

The objective of the invention is to provide a highly effective and safe way to improve the gas transport function of donor red blood cell mass for long periods of storage to increase the efficiency of blood transfusion for critical patients.

The problem is solved by the method consisting in the fact that 40-60 minutes before transfusion of the erythrocyte mass of long-term storage, perfluorane is added to it, at the rate of 0.8-1.2 ml per 10 ml of erythrocyte mass.

The literature describes the membrane-stabilizing, endothelium-protective, antioxidant, rheological properties of perftoran, in connection with which it is used to correct disorders in various parts of oxygen transport [Moroz VV, Krylov NL, Ivanitsky GR et al. The use of perftoran in clinical medicine // Anesthesiology and Intensive Care. - 1995. - No. 6. - S.12-17]. In addition, oxygen and carbon dioxide dissolve well in perfluorane, which contributes to more efficient gas transport, although its own oxygen capacity is 2.5 times lower than that of blood. [Frost V.V., Mayevsky E.I., Ivanitsky G.R. and others. An emulsion of perfluororganic compounds as a means for the treatment of disorders of regional blood flow. General Resuscitation 2007; 3 (3/1): 49-53].

To improve the gas transport function of the donor erythrocyte mass, long-term storage of perftoran has not been previously used. The method is highly effective. It allows you to increase the oxygen capacity of the transfused blood, restore the structure and function of donor red blood cells, protect them from damage. This leads to an increase in tissue oxygen consumption and a decrease in carbon dioxide in the blood, normalization of the oxygen budget as a whole. Correction of hypoxia helps to improve the functional state of vital organs, reduce the risk of purulent-septic complications and multiple organ failure, reduce the duration of mechanical ventilation and reduce mortality of critical patients with anemia.

The technical result when using the invention is achieved due to the fact that the improvement of the gas transport function of the erythrocyte mass of long-term storage sufficient to increase consumption and ensure oxygen utilization by tissues becomes possible due to the restoration of the morpho-functional properties of donor red blood cells and their involvement in gas exchange. For this purpose, the authors first proposed before using blood transfusion to use in vitro treatment of long-term erythrocyte mass with a gas-transporting and cytoprotective function in vitro in patients with massive blood loss and anemia and used a perfluorane emulsion not previously used for these purposes.

In this case, the authors proceed from the fact that when an emulsion of perfluorane with a gas transport, cytoprotective and rheological function is added, the functional activity of donor red blood cells lost as a result of long-term storage is restored. This leads to an increase in the quality and quantity of actively functioning red blood cells, a decrease in the likelihood of transfusion complications and a decrease in the volume of transfused red blood cells necessary for the correction of hypoxia, which ultimately increases the efficiency and safety of the blood transfusion.

The method is as follows. The blood group and Rh factor of the donor and recipient are determined, a test is carried out for individual compatibility of the donor and recipient. Before performing blood transfusion of the erythrocyte mass prepared at the blood transfusion station and suitable for transfusion, but with a shelf life of more than 15 days, an emulsion of 10% perfluororane thawed to room temperature is introduced into one of the container ports, at a rate of 0.8-1, 2 ml per 10 ml of red blood cell mass. Mixing is carried out on a special device for mixing the blood of the donor for 20-30 minutes. Then for 20-30 minutes the mixture is incubated at room temperature. A biological test is performed and blood transfusion is carried out intravenously under the control of clinical data (skin color, body temperature, urine color, etc.), hemodynamic parameters, and blood oxygenation parameters.

The use of blood transfusion in the proposed manner in a patient with massive blood loss and anemia is accompanied by an increase in the oxygen transport function of red blood cells and their involvement in gas exchange. After transfusion, there is an increase in oxygen transport and consumption, saturation, oxygenation of arterial blood and hemoglobin, blood rheology indicators improve, and the risk of post-transfusion complications is also minimized.

Example No. 1 Patient V., 45 years old.

Was in the intensive care unit of the State Clinical Hospital named after S.P. Botkin from 01/22/11 to 04/02/11. (12 days). Transfer to the department 04.02.11.

Clinical diagnosis: Severe concomitant injury. Closed head injury, concussion. Dull chest injury, multiple fractures of the ribs, bilateral hemopneumothorax, contusion of the lungs, heart. Dull abdominal injury, rupture of the spleen, diaphragm. Fracture of both the pubic and ischial bones. Shock 2-3.

The volume of blood loss, taking into account intraoperative - 38 ml / kg. Assessment of the severity of the condition according to APACHE II at the time of admission - 27 points. Upon admission, the patient showed clinical signs of traumatic shock of the II-III degree: tachycardia to 120-130 beats per minute, hypotension with a decrease in blood pressure to 70/0 mm Hg, a change in the level of consciousness to stupor, a sharp pallor of the skin, with " marble ”pattern, decreased urine output, in the analyzes - anemia, metabolic acidosis. After clarifying the scope of the injury, the patient was sent to the operating room, where the following volume surgery was performed: laparoscopy, laparotomy, splenectomy, closure of the rupture of the diaphragm. Drainage of the left pleural cavity. The volume of blood loss was 300 ml. The duration of the period of critical hypotension is up to 3 hours. The volume of infusion therapy in the first 16 hours was 6000 ml, incl. 500 ml of colloids, 300 ml of FFP, 300 ml of red blood cells. On January 23, 2003, a Svan-Hans catheter was installed to monitor the parameters of central hemodynamics and O ₂ transport.

01/23/03. erythrocyte mass was transfused in a volume of 600 ml (10 ml / kg), treated with the addition of 60 ml of perfluoran according to the method described above. The dynamics of hemoglobin, central hemodynamics, delivery and consumption of O ₂ before and after blood transfusion are presented in table 1.

Table 1. Indicator Before blood transfusion 2 hours after Нb, g / l 68 75 Heart rate in 1 min 104 108 UI, ml / m ² 44,2 46.2 SI, l / m ² 4,5 4.7 ITO ₂ , ml / min · m ² 734.4 789.2 IPO ₂ , ml / min · m ² 224.7 274.8 KUO ₂ ,% 31 34 SvO ₂ ,% 65 70 Lactate, mmol / L 2.1 1.3

As can be seen from the table, after blood transfusion, an increase in the oxygen delivery index is observed, due mainly to an increase in the concentration of hemoglobin and, in part, to a slight increase in the cardiac index. At the same time, there is an increase in the oxygen consumption index from 224.7 to 274.8 ml / min · m ² . Moreover, the growth of O ₂ consumption is slightly ahead of the growth of O ₂ delivery, which is manifested by an increase in the oxygen utilization coefficient from 31 to 35% and may indicate an increase in the availability of oxygen to tissues. Against the background of an improvement in the oxygen budget, the saturation indicators of mixed venous blood and lactate concentration are normalized as markers of tissue hypoxia.

In the future, the patient's condition is stable, with positive dynamics. Artificial ventilation was carried out until 01/26/11, the introduction of drugs of inotropic action - during the first day. 01/24/11 pleural drainage removed. 02/04/11 the patient was transferred to the relevant department, 03/13/11 discharged home.

Similar results were obtained using this method in another 7 patients with severe combined trauma and massive blood loss.

Claims (1)

A method for improving the gas transport function of a donor erythrocyte mass with a long shelf life, characterized in that it is stirred 40-60 minutes before transfusion and then incubated at room temperature with perfluorane added at the rate of 0.8-1.2 ml per 10 ml of erythrocyte mass.