RU2662427C2 - Method for heating infusion and transfusion preparations, washing fluids, thermostat for implementation of method - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: group of inventions relates to medicine. In a method for heating infusion and transfusion preparations or washing fluids to a patient from a heated flexible disposable cassette or a disposable infusion system passed through a heated portion of the tube, use a thermostat, containing a stationary part placed near the patient, and a removable part including a closed cavity filled with a heat carrier, containing also a working compartment intended for placing a heated flexible disposable cassette or a holder of a heated portion of the tube of a disposable infusion system, made in the form of a piece of a cylindrical pipe with a longitudinal groove, holes and a spiral groove on the outer surface. In carrying out the method, the removable part is shifted from the stationary part, pushed onto a separate electric heater, heat carrier is melted, a heated flexible one-time cassette with a heated drug is placed in the working compartment or a tube of the heated area of the infusion system is placed in the helical groove of the holder and then filled. Then a thermostat is assembled, in the working compartment of which the preparation or washing liquid is heated by the heat released during the solidification of the coolant.

EFFECT: application of this group of inventions allows effective and safe administration of the drugs.

5 cl, 5 dwg

Description

The group of inventions can find application in heating infusion media used in surgery, resuscitation and therapy.

A known method of heating flushing fluids, infusion and transfusion preparations with electric devices. Heat is supplied to the flow of liquid medical medium through the wall of the tube of the heated section of the infusion system or through the wall of a flexible disposable cartridge. Use heating devices that do not have at all, or have simplified protection against heat loss.

The closest analogues to the claimed inventions are two interconnected objects. This is an Astotherm plus apparatus [1], as well as a method for heating infusion and transfusion media during its operation. By means of the apparatus in question, these medical media are heated to 36, 39, 41 or 43 ° C. The Astotherm plus device contains a protective thermally insulating sleeve and an electric heater, which is built into the holder of the heated section of the tube of the infusion system. The tube fits into the spiral groove of the holder - its coils are in the space between the electric heater and the heat-insulating sleeve. The set temperature is maintained by the microprocessor, and is reflected on the alphanumeric display. The microprocessor and display significantly increase the cost of the Astotherm plus, but they do not ensure the safety of medical procedures. Like any complex electronics, they can fail, in addition to this, the display distracts the attention of medical personnel.

The thermo-insulating sleeve of the Astotherm plus apparatus only partially protects the heated area of the disposable infusion system from heat loss. Evidence of this is the power of the electric heater of the device, which is 450 watts. This is an order of magnitude more than the amount of energy needed to heat the drug to a given temperature.

Known apparatus Ranger [2], allowing blood and flushing fluids used in surgical practice, to warm up to 41 ° C. The Ranger contains an integrated microprocessor-controlled electric heater and an alphanumeric display. The device has a compartment in which a flexible disposable cartridge is placed. There is no thermal protection for the flexible disposable cartridge.

The length of the unheated portion of the tube of the infusion system, ending with a venipuncture needle, is 1.3 for Astotherm plus and 2.3 meters for Ranger. With an outer diameter of the tubes of 4.0 millimeters, the volume of the drug enclosed in them is 10.4 and 18.5, and with a diameter of 6.8 millimeters it reaches 36.7 and 65.0 milliliters. Each infusion therapy procedure begins with the injection of the indicated volumes of cold medical media into the patient's blood. At low ambient temperatures, this onset of infusion is highly undesirable.

The intensity of the drug cooling in the unheated section of the tube of the infusion system depends on its speed and the parameters of the surrounding air. If the drug is administered intensively, it cools slightly, and at a low rate of infusion, its temperature decreases by several degrees. Therefore, the Astotherm plus is equipped with an “insulating sheath” that protects the end of the tube, and the Ranger is used only at high and medium infusion rates.

Several models of cheap electric heating devices with simplified control electronics are presented on the medical equipment market. Such devices are used exclusively at low infusion rates. Medical institutions prefer to purchase universal devices, which increases the cost of procedures.

In the Hotline system [3], the energy of the electric heater is transferred to the heat carrier, which is used as water. Warm water washes the central channel of the disposable three-way line. The middle channel of the line is connected to a pressure pump, and the outer one to a vessel with water equipped with an electric heater. The Hotline system infuses and transfusion preparations, as well as flushing fluids, are heated to 38, 40 or 42 ° С. This system does not have a control microprocessor, and instead of an alphanumeric display, LEDs are used. Thermal protection of the three-way line is not provided. In the cavities of the Hotline system, the propagation of pathogenic bacteria is possible, therefore, it needs periodic disinfection.

Any procedure for infusion of a drug heated in a known manner is unsafe for patients. A threatening situation arises in the event of an accident in the electrical network or in case of failure of the electronics of the heating apparatus. The risk is increased if the drug, initially having a low temperature, is poured at a high speed. Continuation of such a procedure may result in "unintentional" hypothermia.

All known heating devices emit electrical impulses. Therefore, they have a built-in protection against fibrillation that increases their cost. The power cord of any of these devices complicates sanitization, and also makes it difficult for medical personnel to access the patient. Fibrillation protection and an electric cord are potentially dangerous for patients and medical personnel - sooner or later they will fail.

Known thermostat [4] - a device designed for research in isothermal conditions of the physical and chemical properties of substances. A thermostat is a vessel that is carefully isolated from the surrounding space and has a cavity filled with coolant. The investigated body, placed in the working compartment of the thermostat, is in thermal contact with the coolant and has its temperature. The isothermal conditions in such a thermostat are supported by a built-in electric heater with a precision temperature regulator. Another type of electric thermostat heater is used differently - the heat carrier is melted by it. After melting the coolant, the electric heater turns off. The temperature stability in the second type of thermostat is ensured by the heat released during crystallization of the coolant. Such thermostats use the effect that occurs during phase transitions of the first kind. The temperature of the system in which the aggregate transformation of the substance occurs does not change until the transition is complete.

In fact, the Astotherm plus is a simple flow thermostat with a built-in direct-acting electric heater. The Astotherm plus and thermostat have elements with the same purpose: thermal insulation and precision temperature regulator. They differ in that the first of them maintains a given temperature of the fluid flow, and the second maintains the temperature of a body under stationary conditions.

The claimed group of inventions is aimed at solving problems arising from the use of heated washing fluids, infusion and transfusion preparations. This is, firstly, the distracting staff need for control over the heating device. Secondly, this is not a sufficiently high therapeutic and economic efficiency of using the listed media. Thirdly, it is the potential for harm to patients and staff.

The solution of these problems is reduced to solving two technical problems associated with a single inventive concept.

The first of the tasks is solved by improving the known method of heating flushing fluids, infusion and transfusion preparations.

A common feature of the known and proposed methods is that when heating a thermally insulated portion of a disposable infusion system, an electric heater is used.

New in the proposed method is that they use an electric heater located outside the heater. A flow thermostat is used as a heating device. The flow thermostat has a stationary part installed near the patient, as well as a removable part. The stationary part includes the holder of the heated section of the infusion system, and the removable part is made with a closed cavity filled with coolant.

Carrying out the method, in advance, the removable part of the flow thermostat is shifted from the stationary part and pushed onto the electric heater. The coolant is melted with an electric heater, and subsequently the flow thermostat is collected. By means of a flow thermostat, the heated section of the infusion system is isolated from the surrounding space. At the same time, they provide thermal contact of the flow of the medical medium with the hardening coolant.

Also new is the fact that the molten coolant is overheated by 3-5 degrees. When implementing this version of the method, the heated section of the infusion system is introduced into thermal contact with the molten heat carrier. This technique allows to reduce the alignment time of the thermal regime in the working space of the flow thermostat.

New also lies in the fact that before the start of the procedure, they heat a portion of the disposable tube of the infusion system, ending with a needle for venipuncture.

The second technical problem is solved by eliminating the shortcomings of the device selected as the closest analogue.

Common to the analogue and the claimed device is that they contain a thermally insulated holder of the heated portion of the disposable infusion system and an electric heater.

The proposed device differs from the analogue in that the holder is made in the form of a portion of the stationary part of the flow thermostat, fixed near the patient. The removable part of the flow thermostat contains a closed cavity filled with coolant.

In this case, a heat carrier having a melting point selected in the range from 25 to 45 ° C is used.

An electric heater designed to melt the coolant is located outside the flow thermostat.

The technical result achieved is as follows.

1. The therapeutic effectiveness of the use of heated flushing fluids, infusion and transfusion preparations has been increased. This advantage is provided by two methods unknown from the prior art. Firstly, it is overheating of the molten heat carrier by 3-5 degrees. This technique allows you to minimize the period of stabilization of temperature in the working space of a flow thermostat. Secondly, this is an advance heating of the tube section of the filled infusion system located on the patient’s side. Any procedure begins with the infusion of an already heated preparation, which is important at low ambient temperatures. In addition, heater failures during procedures and “unintentional” hypothermia become impossible.

2. The economic efficiency of using heated wash liquids, infusion and transfusion preparations has been increased. The use of a flow thermostat, carefully isolated from the surrounding space, allows to minimize heat loss. The heat released during the phase transition is absorbed only by a heated medical environment. This minimizes the consumption of electrical energy. The proposed flow thermostat has a simple design, complex electronics are not used. In mass production, the price of the device will be several times lower than the cost of existing universal heating devices.

3. The proposed device belongs to the category of universal heaters. They can heat any infusion and transfusion medium, as well as flushing fluids, which are delivered to the patient at a high, medium or low speed. A change in the speed of the drug leads to a commensurate increase (decrease) in the amount of heat absorbed by it. As a result, the speed of the process of solidification of the coolant is correspondingly accelerated (decelerated). As long as the phase transition continues, the temperature of the drug delivered to the patient cannot change.

4. Patient safety ensured. Operations and procedures of infusion therapy are not interrupted in case of accidents in the electric network. The flow thermostat does not have control electronics, which can fail, and the failure of the temperature control system is not dangerous. The flow thermostat does not emit electrical impulses, so fibrillation is not possible. The absence of a wire connecting the flow thermostat to the electric network facilitates access to the patient, which is important in critical situations.

5. Created comfortable conditions for medical personnel - there is no need to control the temperature of the infusion medium. The flow thermostat almost instantly and without fail responds to any changes in the infusion rate. The temperature of the heated medium flow is always constant. Sanitizing a flow thermostat and an electric heater is common.

6. The safety of medical personnel. This is achieved, firstly, due to the fact that the electric heater is connected to the mains via a step-down transformer. Secondly, the shells of the flow thermostat serve as screens for electromagnetic pulses emitted by an electric heater. Thirdly, the device does not contain substances hazardous to health. Fourth, the flow thermostat does not have an electric power cord, which eliminates the possibility of harm to personnel.

All materials of which the heater is made are recyclable.

The proposed device is illustrated by drawings, where in FIG. 1 shows an infusion stand with an infusion system and a flow thermostat; in FIG. 2 - a fragment of a block of electric heaters; in FIG. 3 is a longitudinal section of a flow thermostat assembly; in FIG. 4 is a longitudinal section of a removable part of a flow thermostat; in FIG. 5 is a stationary part of a flow thermostat containing a holder of a heated section of the tube of the infusion system.

The claimed device includes a flow thermostat having a removable 1 and stationary 2 parts. The removable part 1 of the flow thermostat (Fig. 1 - Fig. 4) is made in the form of a thermally insulated vessel (Fig. 3, Fig. 5) with vacuum thermal insulation. Instead of vacuum, a synthetic material with low thermal conductivity can be used. Stationary part 2 has a compartment 3 for the circuit board for monitoring the temperature of the drug, and on its outer surface there is a platform 4 with LEDs (not shown in the drawings). The stationary part 2 is made with a hole 5 (Fig. 3, Fig. 5), designed to pass the tube 6 of the heated section of the infusion system. The stationary part 2 is mounted on the rack of the infusion tripod 7 (Fig. 1, Fig. 3, Fig. 5) installed near the patient. The removable part 1 of the flow thermostat contains an airtight cavity filled with coolant 8. An alloy of high molecular weight substances is used as the coolant. The composition of the alloy depends on the purpose of the heater. So, if the infusion must be carried out in a hypothermic mode, use a coolant 8, melted at 27 ° C (or at a lower temperature). In other cases, coolant 8 is used, the melting point of which is in the range 36-45 ° C. The stationary portion 2, located in the cavity of the removable portion 1, performs the functions of the holder 9 of the tube 6 of the heated portion of the infusion system. The holder 9 is a piece of a cylindrical pipe with a longitudinal groove 10, holes 11 and a spiral groove on the outer surface. In accordance with established practice, the outer diameter of the tube 6 of the infusion system is 6.8 or 4.0 millimeters, and the length is 5.7 or 4.9 meters. As a heated section of the infusion system can be a flexible disposable cartridge (not shown in the drawings). The composition of the proposed device includes an electric heater. The electric heater consists of elements 12 of a separate unit located outside the flow thermostat. Elements 12 (Fig. 2) mounted on the table 13 are connected to a step-down transformer connected to the network and disconnected from it by the simplest automation. In addition to the listed parts, the device contains a disposable "passive" heat-insulating cover (not shown in the drawings). The cover protects the infusion tube section located between the flow thermostat and the patient from heat loss. Use a cover at low infusion rates, as well as at low ambient temperatures.

The proposed method is as follows. A section of the tube 6 of the infusion system with a needle for venipuncture at the end, as well as a heated section of the tube 6 are threaded into the hole 5 of the stationary part 2 of the flow thermostat. The tube 6 is placed in the spiral groove of the holder 9 (Fig. 5), then the infusion system is filled. At least 5 minutes before the start of the infusion therapy procedure, the removable part 1 of the heater is transferred to the table 13 elements 12 of electric heaters (Fig. 2). The removable part 1 of the flow thermostat is pushed onto the elements 12 of one of the electric heaters. Then the coolant 8 is melted, the melt is overheated by 3-5 degrees, and then the removable part 1 is transferred to the infusion stand 7 and pushed onto the stationary part 2. In the assembled flow thermostat, both heated sections of the infusion system enter into heat exchange with the coolant 8. The temperature of the cooling melt decreases by 3-5 ° C, and the temperature in the working cavity of the flow thermostat increases accordingly. By the beginning of the process of solidification of the coolant, the thermal regime is stabilized. The readiness of the device for use is indicated by a green LED. Before the infusion therapy procedure, the flow thermostat is disassembled and 1.3 meters of tube 6, ending with a venipuncture needle, are wound from the holder 9. After that, the flow thermostat is again collected, venipuncture is performed and the set infusion rate is set. The drug is heated to a predetermined temperature due to the heat released during the solidification of the coolant 8. The thermal regime in the working compartment of the removable part 1 of the flow thermostat is leveled with air circulating through the openings 11. During the infusion, the amount of solid coolant 8 in the flow thermostat gradually increases. However, the temperature of the heat exchange participants does not change. At the end of the solidification of the coolant warn the sound signal and the light of the yellow LED. If the procedure needs to be continued, a removable part 1 of another flow thermostat containing molten coolant 8 is pushed onto the stationary part 2.

In the best way, the group of inventions can be used in resuscitation, surgery, obstetrics, gynecology, in the treatment of infectious diseases, in therapy and veterinary medicine.

List of cited information sources

1. http://www.altaide.ru/index.php?menu=stihler&pid=3.

2. http://www.delrus.com/index.php?part_name=good&g_id=576.

3. http://levellhotline.com/pdf/TM194849GL-042014_HOTLINE_white_paper.pdf

4. Physical encyclopedic dictionary. Editor-in-chief A.A. Prokhorov. M., Soviet Encyclopedia, 1984.

Claims (5)

1. The method of heating infusion and transfusion preparations or flushing fluids entering the patient from a heated flexible disposable cartridge or passed through a heated section of the tube of a disposable infusion system, characterized in that they use a thermostat containing a stationary part installed near the patient and a removable part, including closed cavity filled with coolant, also containing a working compartment, designed to accommodate a heated flexible disposable cartridge or holder about of the heated portion of the tube of a disposable infusion system, made in the form of a segment of a cylindrical pipe with a longitudinal groove, holes and a spiral groove on the outer surface, during which the removable part is moved from the stationary part, pushed onto a separate electric heater, melt the coolant, and the heated flexible is placed in the working compartment a disposable cartridge with a heated drug or in the spiral groove of the holder, lay the tube of the heated section of the infusion system and fill it, then collect the thermostat, in the working compartment of which the preparation or flushing liquid is heated due to the heat released during the solidification of the coolant. 2. The method according to p. 1, characterized in that the removable part with a coolant hardened during a lengthy procedure is replaced by another in which it is molten. 3. The method according to p. 1, characterized in that it is located on the patient’s side of the tube section of the disposable infusion system, ending with a venipuncture needle. 4. The method according to p. 1, characterized in that the molten coolant is overheated by 3 ... 5 degrees Celsius. 5. The thermostat intended for use in the implementation of the method according to claim 1, comprising a working compartment in which a heated flexible disposable cartridge or holder of a heated section of the tube of the infusion system is located, having the form of a section of a cylindrical pipe with a longitudinal groove, holes and a spiral groove on the outer surface also containing a stationary part installed near the patient and a removable part with a closed cavity inside it filled with a coolant, made with the possibility of a shift from the stationary part and pushing onto a separate electric heater used to melt the coolant that hardens in the assembled thermostat when transferring heat to the infusion or transfusion preparation or flushing fluid, coming to the patient from a heated flexible disposable cassette or passed through a heated section of the tube of a disposable infusion system.

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