RU2599032C1 - Incubator of platelet-containing transfusion media - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to medical equipment. Incubator of platelet-containing transfusion media comprises a thermal insulated housing, control system connected with temperature sensors, placed in simulators of polymeric containers with platelet-containing transfusion media in the form of liquid filled polymeric containers, installed at the levels corresponding to the levels of location of platforms to place polymeric containers with platelet-containing transfusion media, connected with blocks of a semiconductor thermopiles and fans and forming a multichannel temperature control system. Incubator also includes labels of radio frequency identification, fixed on a polymeric containers, label readers, printer of labels and scanner of bar codes.

EFFECT: invention allows to reduce the unevenness of the temperature by the chamber volume and thereby to ensure high temperature stability of platelet-containing transfusion media inside polymeric containers, provide reliable storage and identification of platelet-containing transfusion media while maintaining their viability and hemostatic activity in extreme conditions and emergency situations regardless of the presence of voltage in the electrical network.

3 cl, 1 dwg

Description

The invention relates to the field of medical equipment and can be used at blood transfusion stations, in blood transfusion departments, in surgical and resuscitation departments of hospitals and clinics, as well as in medical research institutions.

In recent years, transfusion of platelet-containing transfusion media has become a prerequisite for program therapy of blood system tumors, aplastic anemia, and bone marrow transplantation. Under the "protection" of transfusions of platelet concentrate, intensive chemotherapy courses are conducted with a pre-planned period of prolonged agranulocytosis and thrombocytopenia, abdominal operations (laparotomy, splenectomy) that were previously impossible are performed. In this case, it is especially important to ensure the prescribed modes of storage of platelet concentrate, their monitoring and recording, since compliance with these modes guarantees its quality. An integral part of the platelet concentrate quality control system is the traceability of its movement along the entire technological chain from the donor to the time of its use, which can be ensured through the use of modern information technologies.

In accordance with the Guidelines for the preparation, use and quality assurance of blood components, M., Fertribstez. m.b.kh., 1996, p. 98 platelets should be stored under conditions in which viability and hemostatic activity of the cells are maintained. If platelets are to be stored for more than 24 hours, a closed bag system is used for preparation. Polymer bags must have good gas permeability in order to ensure oxygen flow to platelets. The need for oxygen depends on the content of platelets and leukocytes in the concentrate. Temperature: 22 ± 2 ° C.

A necessary condition for maintaining the viability of platelets is their constant mixing. It should be efficient enough to provide oxygen during the entire storage time, which under optimal conditions can be 7 days.

The closest analogue prototype is a device for storing platelet-containing transfusion media (platelet concentrate), comprising a thermally insulated body with a transparent door made of laminated glass with an air gap, a door lock, a control system associated with a temperature sensor and a voltage sensor, the first and second autonomous power sources, a secondary power source, which is connected to the electric network via a voltage sensor of the network, a block of semiconductor thermal batteries, a system forced air circulation, an alarm and recording unit for the parameters of the storage process associated with the first autonomous power source, with a light and sound alarm system, an interface with a personal computer and a door position sensor, a mixing system that includes a movable platform with containers with platelet-containing transfusion media connected through a motion transmission unit with an electric motor, a power supply switching unit, the first input of which dklyuchen to the secondary power source, the second input - to the second autonomous power supply source, and an output - to the motor, a motion sensor, which is associated with the movable platform optical or electromagnetic coupling and connected to the alarm unit and recording storage process parameters.

The disadvantage of the prototype is the lack of the ability to ensure high quality of the finished product due to insufficient temperature uniformity throughout the chamber volume, insufficiently reliable measurement and recording of the parameters of the storage process of platelet-containing transfusion media, namely the time dependences of the temperature of platelet-containing transfusion media inside polymer containers, low reliability of data storage on the parameters the storage process of platelet-containing transfusion media and the absence of the traceability of the movement of platelet-containing transfusion media along the entire process chain from the donor to the time of its use, which affects the quality of the final product.

The disadvantage of the prototype is the lack of air access to the polymer containers with platelet-containing transfusion media, which prevents the access of oxygen to the gas-permeable walls of the polymer containers.

The technical result to which the invention is directed is to eliminate the above drawbacks and create an incubator of platelet-containing transfusion media that ensures the viability of the platelet concentrate in case of extreme situations.

The technical result is achieved by the fact that the incubator of platelet-containing transfusion media contains a thermally insulated case with a transparent door made of laminated glass with an air gap, a door lock, a control system associated with a temperature sensor and a voltage sensor of the network, the first and second autonomous power sources, a secondary power source, which through a voltage sensor connected to the electric network, a block of semiconductor thermal batteries, a forced air circulation system, a block alarm and logging parameters of the storage process associated with the first autonomous power source, with a light and sound alarm system, a node for interfacing with a personal computer and a door position sensor, a mixing system that includes a moving platform with containers with platelet-containing transfusion media connected through a motion transmission unit with electric motor, switching unit for power supplies, the first input of which is connected to a secondary power source ii, the second input is to the second autonomous power source, and the output is to the electric motor, a motion sensor that is connected to the mobile platform by optical or electromagnetic communication and connected to the emergency signaling and recording unit of the storage process parameters, n additional and connected to each other a motion transmission unit for mesh or perforated platforms with cells for placement of polymer containers with platelet-containing transfusion media, n additional temperature sensors control systems, (n + 1) simulators of polymer containers with thrombocyte-containing transfusion media in the form of liquid-filled polymer containers, inside which temperature sensors are placed, n additional blocks of semiconductor thermal batteries connected via the first switch to the output of the power supply switching unit, the system forced air circulation contains n + 1 fans connected through the second switch to the output of the power supply switching unit, read bar codes associated with the control system, an RFID tag printer associated with the control system, RFID tags mounted on polymer containers with platelet-containing transfusion media, RFID tag readers located in the platform cells for placement of polymer containers with platelet-containing transfusion media and associated with the control system, an alphanumeric or graphic display associated with the control system, the control inputs of the first and second switches, as well as the control input of the power supply switching unit are connected to the control system, the alarm and process parameters logging unit is connected to the control system, semiconductor thermal battery blocks, fans and simulators of polymer containers are installed at levels corresponding to the levels of arrangement of polymer containers with thrombocyte-containing transfusion media on platforms, and together with the control system, the first and second comm Tatorey form a multi-channel temperature control system.

The use of temperature sensors placed in polymer containers with liquid significantly increases the reliability of data on the actual temperature of platelet-containing transfusion media in polymer containers, as this takes into account the physical characteristics of platelet-containing transfusion media, such as thermal conductivity, heat capacity, inertia, viscosity, etc. that is not taken into account in the prototype, where the air temperature inside the chamber is measured.

The use of a multi-channel temperature control system makes it possible to distribute blocks of semiconductor thermal batteries evenly throughout the entire volume of the incubator body, eliminate local overheating or overcooling, provide a faster exit of the storage temperature of platelet-containing transfusion media to a given storage temperature (22 ± 2 ° C), and reduce temperature non-uniformity throughout the chamber and thereby guarantee high temperature stability of platelet-containing transfusion media inside polymer containers Placed in an incubator chamber and thus ensure the quality of the final product. This is especially important with a large camera volume. The use of a single-channel temperature control system with one block of semiconductor thermal batteries and one temperature sensor, as is done in the prototype, does not allow to achieve high uniformity of temperature in the chamber volume.

The implementation of platforms for placement in the form of a grid or ribbed and / or perforated sheet material allows contact of the entire outer surface of the polymer container with the platelet-containing transfusion medium with air to supply it with oxygen during storage.

The use of RFID tags allows you to store information about the temperature regime of storage of a polymer container with platelet-containing transfusion media, storage duration, date of receipt of the product, patient, etc. in the memory of a microchip located directly on a polymer container. This method of storing and recording information eliminates its loss, ensures traceability of the entire history of platelet-containing transfusion media and the use of this information after heat treatment, storage and transportation, reduces the risk of using a poor-quality product and increases the reliability of treatment.

The use of RFID tag readers installed directly in each cell to place polymer containers with platelet-containing transfusion media allows you to record information about the temperature storage mode of platelet-containing transfusion media in the memory of RFID tag chips installed on each polymer container individually for each container.

The use of the radio frequency identification tag printer is due to the need to equip each polymer container with platelet-containing transfusion media with a radio frequency identification tag with the initial information recorded in the memory of its chip.

The use of a barcode reader is due to the need to read and recognize product information encoded in barcodes pasted on plastic containers with platelet-containing transfusion media to write it to the memory of RFID tag chips.

The figure 1 shows a schematic diagram of an incubator for storing platelet-containing transfusion media.

The platelet-containing transfusion media incubator comprises a thermally insulated housing 1 with a transparent laminated glass door with an air gap 2, a door lock 3, a control system 4 connected to (n + 1) temperature sensors 5 and 25 and to a voltage sensor 6, the first 7 and the second 8 autonomous power sources, a secondary power source 9, which is connected via an electric voltage sensor to the electric network, (n + 1) semiconductor thermal battery blocks 10 and 27, forced air circulation system 11, consisting of (n + 1) vents liatorov 29, an alarm and recording unit for the parameters of the storage process 12, associated with the control system, with the first autonomous power supply, with a light and sound alarm system 13, an interface with a personal computer 14 and a door position sensor 15, a mixing system 16, including ( n + 1) movable mesh or perforated platforms 17 and 23 with cells 24 for accommodating polymer containers with platelet-containing transfusion media 18 and connected via an electric motion transmission unit 19 to an electric the motor 20, the switching unit of the power supply 21, the first input of which is connected to a secondary power source, the control input of which is connected to the control system, the second input to the second autonomous power source, and the output to the electric motor, motion sensor 22, which is connected to the mobile platform optical or electromagnetic communication and is connected to the alarm and logging unit for storing process parameters, (n + 1) simulators of polymer containers with platelet-containing transfer ionic media 26 in the form of liquid-filled polymer containers, inside which temperature sensors are placed, the first switch 28 connected by the outputs to the (n + 1) blocks of semiconductor thermal batteries, the input to the power supply switching unit, and the control input to the control system, the second switch 30, connected by outputs to (n + 1) fans 29 of the forced air circulation system, by an input to a power supply switching unit (in FIG. 1, the connection is not shown), but by the control input to the control system, a barcode reader 31 connected to the control system, a radio frequency identification tag printer 32 connected to the control system, radio frequency identification tags 33 attached to polymer containers with platelet-containing transfusion media, tag readers radio frequency identification 33, located in the cells of the platforms for placement of polymer containers with platelet-containing transfusion media and associated with the control system I, an alphanumeric or graphic display 34 associated with the control system.

The incubator of platelet-containing transfusion media is as follows.

Before starting work with an incubator of platelet-containing transfusion media, they include electrical power to the control system 4, alarm and process unit 12, mixing system 16, first 28 and second 30 switches, barcode reader 31, RFID printer 32. Power availability is monitored voltage sensor 6.

Before loading into the thermally insulated casing 1 of the polymer containers 18 with platelet-containing transfusion media, a check is made for the presence of RFID tags 33 on the surface of the polymer containers 18. If there are no tags on any containers, they are printed and programmed using a printer 32. Information is entered based on data either directly indicated on labels pasted on polymer containers, or obtained by decrypting the data obtained after reading the scanner 31 m bar codes printed on these labels. After printing the missing RFID tags 33, they are glued to polymer containers with platelet-containing transfusion media 18, after which all polymer containers 18 are placed in cells 24 of mesh or perforated platforms 23 and 17 located in a thermally insulated housing 1.

After laying the polymer containers 18 with platelet-containing transfusion media, the door 2 is closed with a lock 3. Making the door transparent of several glasses with air gaps between them, on the one hand, provides thermal insulation of the case, and, on the other hand, allows visual monitoring of the storage process thrombocyte-containing transfusion media.

After closing door 2, the control system automatically starts the process of measuring and regulating the temperature. The display 35 displays data on the temperature outside and inside the insulated housing 1, as well as the set value of the storage temperature (22 ° C). The temperature inside the incubator body is measured using (n + 1) temperature sensors 5 and 25, placed in simulators of polymer containers with platelet-containing transfusion media 26, and is automatically maintained using a control system 4, which is connected via the first switch 28 to the blocks of semiconductor thermal batteries 10 and 27, providing heating or cooling depending on the polarity of the voltage supplied to them. The supply voltage is supplied from the switching unit of the power sources 21 through the first switch 28 at the command of the control system 4. The control system 4 generates a signal that allows you to adjust not only the polarity, but also the voltage level on the semiconductor thermal batteries for precise adjustment. By means of the second switch 30, the control system controls the switching (n + 1) of the fans 29 of the forced air circulation system 11, which ensures high uniformity of air temperature throughout the body volume. The control system 4 also generates a signal that allows you to adjust the voltage level to precisely control the speed of rotation of the fans in order to optimize the speed of the air flow inside the incubator chamber and the heat generated by the fan motors.

The placement of temperature sensors 5 and 25 in simulators of polymer containers with platelet-containing transfusion media 26 provides a measurement of the temperature of the liquid under conditions close to the storage conditions of platelet-containing transfusion media in polymer containers 18, and allows more accurate control of the thermal stabilization process taking into account the thermal inertia of platelet-containing transfusion media. It is advisable to choose the dimensions and volume of simulators of polymer containers with thrombocyte-containing transfusion media 26 equal to the dimensions of real polymer containers with thrombocyte-containing transfusion media 18 on movable platforms 23 and 17. The fluid filling the simulators 26 must have the same physical characteristics (heat capacity, thermal conductivity) as well as platelet-containing transfusion media in polymer containers 18. This ensures high reliability of the recorded time storage temperature dependency trombotsitosoderzhaschih transfusion media in polymeric containers 18 on the movable platforms disposed at different levels in the heat-insulated casing 1 incubator. This method of temperature measurement ensures the preservation of high quality platelet-containing transfusion media during their long-term storage in an incubator.

If the temperature goes beyond the set limits, the requirements for which are set more stringent, for example (22 ± 1) ° С, the control system 4, connected with the (n + 1) temperature sensors 5 and 25, generates the corresponding control signal and gives the command to the emergency unit signaling and recording process parameters 12 to run a visual and audible alarm system 13, which allows you to fix the output of the process parameter beyond the specified limits. Additionally, the control system displays information about the emergency on the display 35 in the form of a text message. The output of text messages to the display 35 allows you to quickly obtain information about a specific accident and, in some cases, restore the functionality of the intelligent storage system of platelet-containing transfusion media before contacting the service department.

All information about the temperature inside the insulated housing 1 is recorded in the memory of the chips of the tags of radio frequency identification readers 34 at regular intervals. If the reader 34 detects that there is no container in its cell, recording is not performed. Data on the temperature inside each polymer container with platelet-containing transfusion media 18 is formed based on the readings of the temperature sensor 5 and 25, located at the same level as the container 18.

The power of the mixing system 16 of platelet-containing transfusion media in polymer containers 18 is provided through a switching unit 21. In the event of a mains voltage, the electric motor 20 is supplied from a secondary power supply 9.

In case of failure of the mixing system 16, the corresponding signal is sent from the motion sensor 22 to the alarm and process unit 12, which, in turn, gives a signal to the visual and audible alarm systems 13. Additionally, the control system 4 displays a corresponding text message on the display 35 .

After receiving a signal about a malfunction of the mixing system 16, maintenance personnel take measures to ensure the necessary storage conditions for platelet-containing transfusion media - mixing, for example, moving polymer containers to another backup device, or urgently repairing the mixing system.

The alarm and logging unit for process parameters 12 provides the following functions:

- Indication of turning on and off the network;

- indication of the current temperature;

- task and indication of the current time, time of the beginning of the process and time of the end of the storage process;

- sound and light signaling of the end time of the process;

- logging the parameters of the storage process through the built-in memory;

- emergency alarm.

The parameters of the storage process of platelet-containing transfusion media include:

- start and end time of the storage process;

- the measured time dependences of temperature in n simulators of polymer containers with thrombocyte-containing transfusion media;

- data on the termination of the mixing of platelet-containing transfusion media (termination of the movement of the platforms due to malfunction);

- data on the time of opening and closing the door of the insulated chamber during storage;

- data on the time of absence of the mains voltage.

In the event of an accident in the network or its disconnection, the power of the alarm unit and the recording of process parameters 12 is carried out from the first autonomous power source 7, which can be a rechargeable chemical source of low current direct current. Moreover, based on the readings of the voltage sensor of the network 6, the control system 4 generates a control signal to the switching unit 21, which connects the second autonomous power source 8 to the mixing system 16, ensuring its operation.

The second autonomous power source 8 can be part of the incubator for storing platelet-containing transfusion media or can be connected separately through special terminals.

When using a direct current electric motor 16 in the mixing system 16, the second autonomous power source 8 can be made in the form of a built-in or plug-in rechargeable chemical DC power source of high power, and the secondary power source in the form of a rectifier. When using an alternating current electric motor in the mixing system, the connected second autonomous power source 8 can be made in the form of an integrated or connected high-power chemical direct current source and an integrated alternating current generator, and the secondary power source 9 can be in the form of a transformer. If the second autonomous power source 8 includes an integrated rechargeable chemical direct current source, the secondary power source 9 contains a charging circuit for a rechargeable direct current chemical source. In this case, the rechargeable chemical source of direct current is charged when there is voltage in the network.

The visual and audible alarm system 13 contains the necessary digital, light indicators, as well as sound emitters, allowing the operator to obtain the necessary information about the status of the incubator and process parameters.

The interface unit with a personal computer 14 provides the ability to transfer data on the parameters of the storage process of platelet-containing transfusion media to a personal computer in order to provide remote monitoring of these parameters by displaying the parameter values on the monitor screen, recording them on electronic media, and also processing them (graphing and printing protocol). The incubator of platelet-containing transfusion media can be connected both directly to a personal computer and to a computer network, which in turn is connected to a personal computer. Using a connection to a personal computer through a computer network allows you to control at the same workplace several incubators of platelet-containing transfusion media located in different places at once.

An incubator of platelet-containing transfusion media provides reliable storage and high quality of platelet-containing transfusion media while maintaining their viability and hemostatic activity, as well as a low level of risk of complications during therapy using them due to the high uniformity of temperature in the volume of the heat-insulated chamber, which provides a multi-channel temperature control system, and the possibility of tracking the movement of platelet-containing transfusion x media throughout the processing chain from the donor to the RFID tags on the moment of its use, which provides barcode reader, the printer and the RFID tag readers that are part of the incubator.

Claims (3)

1. An incubator of platelet-containing transfusion media containing a thermally insulated body (1) with a transparent laminated glass door with an air gap (2), a door lock (3), a control system (4) associated with a temperature sensor (5) and a voltage sensor (6), the first (7) and second (8) autonomous power sources, a secondary power source (9), which is connected to the electric network through a voltage sensor, a semiconductor thermal battery unit (10), a forced air circulation system (11), a unit alarm data and recording parameters of the storage process (12) associated with the first autonomous power source, with a light and sound alarm system (13), a node for interfacing with a personal computer (14) and a door position sensor (15), a mixing system (16), including a movable platform (17) with containers with platelet-containing transfusion media (18) connected through a motion transmission unit (19) to an electric motor (20), a power supply switching unit (21), the first input of which is connected to a secondary source power supply, the second input is to the second autonomous power source, and the output is to the electric motor, a motion sensor (22), which is connected to the mobile platform by optical or electromagnetic communication and connected to the emergency signaling and recording unit of the storage process parameters, characterized in that it contains n additional platforms located above each other and connected with the motion transmission unit (23) with cells (24) for placing polymer containers with platelet-containing transfusion media, n additional x temperature sensors (25) associated with the control system, (n + 1) simulators of polymer containers with platelet-containing transfusion media (26) in the form of liquid-filled polymer containers, inside which temperature sensors are placed, n additional blocks of semiconductor thermal batteries (27) connected through the first switch (28) with the output of the power supply switching unit, the forced air circulation system contains n + 1 fans (29) connected through the second switch (30) with the output of the switching unit power supply sources, barcode reader (31), connected to the control system (4), radio-frequency identification tag printer (32), connected to the control system, radio-frequency identification tags (33), mounted on plastic containers with platelet-containing transfusion media, radio frequency tag readers identification (34) located in the cells of platforms for placement of polymer containers with thrombocyte-containing transfusion media and associated with a control system, alphanumeric or grap a visual display (35) associated with the control system, the control inputs of the first and second switches, as well as the control input of the power supply switching unit are connected to the control system, the alarm and process parameter logging unit is connected to the control system, semiconductor thermal battery blocks, fans and simulators polymer containers are installed at levels corresponding to the location levels of polymer containers with platelet-containing transfusion media on platforms, and with jointly with the control system, the first and second switches form a multi-channel temperature control system. 2. The incubator according to claim 1, characterized in that the platforms for accommodating polymer containers with platelet-containing transfusion media are made in the form of a grid. 3. The incubator according to claim 1, characterized in that the platforms for accommodating polymer containers with platelet-containing transfusion media are made in the form of ribbed and / or perforated sheet material.

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