RU2639827C1 - Device for mixing thrombocyte concentrate or thrombocyte containing transfusion media - Google Patents

Abstract

FIELD: medicine.SUBSTANCE: device for mixing thrombocyte concentrate or thrombocyte containing transfusion media comprises a housing 1 with a cover 2, the platform 3 with installed containers of thrombocyte concentrate or thrombocyte containing transfusion medias 4, the node of transmission 5, the motor 6, the motor control module 7, the digital-analogue converter 8, the microprocessor 9, the temperature sensors 12 and Peltier thermocouples 13. The temperature of the moving platform 3 is controlled by the microprocessor 9 by applying the voltage of the first power supply 16 to the Peltier thermocouples13 by means of electronic switches 14 and voltage reversal units 15. The device also contains a motion sensor 17 that is associated with the node of transmission 5, and is connected to the microprocessor 9, second power source 23, also first and second drivers 20 and 22 of wireless data transfer, connected to the microprocessor 9 and PC 21.EFFECT: device provides reliable and safe storage of thrombocyte containing transfusion media, as well as remote monitoring of the storage process based on the use of modern information technologies.2 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 carried out with a pre-planned period of prolonged agranulocytosis and thrombocytopenia, abdominal operations (laparotomy, splenectomy) are performed, previously impossible. 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 monitoring of the concentrate storage process and logging of the storage process parameters.

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 containers must have good gas permeability in order to ensure oxygen flow to platelets. Platelet concentrate storage temperature: (22 ± 2) ° С.

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 to the prototype is a device for mixing and temperature control of liquids (see RU 2259869, class B01F 11/00, 04/15/2004), comprising a housing with a lid, a movable platform with containers with platelet concentrate placed on it, connected through a motion transmission unit with an electric motor connected to an electric motor control unit, the input of which through a digital-to-analog converter is connected to the first output of a microprocessor associated with a keyboard and a display, one or more temperature sensors and, respectively the actual number of Peltier thermocouples, electronic keys and voltage polarity reversal nodes, the first power supply connected to the electric motor control unit and electronic keys, Peltier temperature sensors and thermocouples are located on the platform, temperature sensors are connected to the microprocessor inputs, the control outputs of which are connected to the control inputs of electronic keys and control inputs of voltage polarity change nodes, electronic keys are connected between the first source of electric Itani inputs and voltage polarity reversal nodes, the outputs of which are connected to the Peltier elements.

The disadvantage of the prototype is the lack of remote monitoring of the storage process of platelet concentrate in the absence of a wired communication line with a centralized personal computer, for example, when using the device in mobile medical units and field hospitals.

The disadvantages of the prototype are the lack of light and sound alarms about device malfunctions, the lack of control over the process of mixing platelet concentrate, the lack of the ability to print protocols of the process parameters for storing platelet concentrate, and the lack of autonomy of the device dependence of electric power on a stationary electric network, which can lead to spoilage of platelet concentrate.

The technical result to which the invention is directed is to eliminate the above drawbacks and create a device for storing platelet concentrate or platelet-containing transfusion media, ensuring the viability of the platelet concentrate in case of extreme situations.

The technical result is achieved in that the device for mixing the platelet concentrate of platelet-containing transfusion media contains a motion sensor that is connected to a motion transmission unit and connected to a microprocessor, an audio signaling unit and a light signaling unit connected to the microprocessor, a first wireless data transmission driver connected to the microprocessor , a personal computer, a second wireless data driver connected to the personal computer, a second source of electrical power driver connected to the second wireless data transfer and a personal computer, and the connection between the first and second drivers wireless data transmission by means of electromagnetic waves in the radio frequency range.

The technical result is also achieved by the fact that the first and second power sources are autonomous.

The figure 1 shows a schematic diagram of a device for mixing a concentrate of platelets or platelet-containing transfusion media.

A device for mixing platelet concentrate or platelet-containing transfusion media contains a housing 1 with a cover 2, a movable platform 3 with containers with platelet concentrate 4 located thereon, connected through a motion transmission unit 5 to an electric motor 6 connected to an electric motor control unit 7, the input of which is through a digital-to-analog the converter 8 is connected to the first output of the microprocessor 9, associated with the keyboard 10 and the display 11, one or more temperature sensors 12 and the corresponding number about Peltier thermocouples 13, electronic keys 14 and voltage polarity change nodes 15, the first power supply 16 connected to the motor control unit 7 and electronic keys 14, temperature sensors 12 and Peltier thermocouples 13 are located on platform 4, temperature sensors 12 are connected to microprocessor inputs 9, the control outputs of which are connected to the control inputs of the electronic keys 14 and the control inputs of the nodes for changing the polarity of the voltage 15, the electronic keys 14 are connected between the first source of electronic power supply 16 and the inputs of the nodes changing the polarity of the voltage 15 the outputs of which are connected to the Peltier elements 13. The device contains a motion sensor 17, which is connected to the motion transmission unit 5 and connected to the microprocessor 9, an audible alarm unit 18 and a light signaling unit 19 connected to the microprocessor 9 , the first wireless data driver 20 connected to the microprocessor 9, a personal computer 21, the second wireless data driver 22 connected to the personal computer 21, the second power supply anija 23 connected to the second wireless data driver 22 and the personal computer 21, and the connection between the first 20 and second driver 22 of wireless data transmission by means of electromagnetic waves in the radio frequency range.

The first 16 and second 23 power sources can be made autonomous.

The operation of the device for mixing and thermostating of platelet concentrate is as follows.

On a movable platform 3, located in the housing 1, place containers with platelet concentrate. Close the lid 2, while ensuring the restriction and thermal insulation of the internal volume from the surrounding space.

Using the keyboard 10 through the microprocessor 9 sets the operating conditions of the electric motor control unit 7, in particular, sets the operating time and the required vibration frequency in the range from 5 to 30 Hz, and also sets the nominal storage temperature of platelet concentrate in polymer containers at 22 ° C.

Using the keyboard 10 include the mixing mode of the platelet concentrate and the mode of thermal stabilization of temperature in the internal volume of the housing 1.

The microprocessor 9 through the digital-to-analog converter 8 and the motor control unit 6 provides power supply from the first power source 16 to the electric motor 6. The electric motor 6 drives the platform 3 with mounted containers 4 with platelet concentrate 4 mounted on it in accordance with the previously installed ones, through the motion transmission unit 5 motion parameters.

In the event of a change in the ambient temperature and, accordingly, the temperature of the liquid in the containers, the signals of the temperature sensors 12 are fed to the inputs of the microprocessor 9, which generates the corresponding control signals received at the control inputs of the electronic keys 14 and voltage polarity change nodes 15. The electronic keys provide voltage to the change nodes voltage polarity 15. The latter carry out a change in voltage polarity if necessary, change the heating process in the process with cooling. Peltier elements 13 convert electrical energy into heat or cold, respectively.

Temperature control can be carried out by the microprocessor through separate channels; for this, as many temperature sensors 12 are installed on the platform as there are Peltier elements 13 installed (Fig. 1 shows an example with three control channels). It is possible to install one temperature sensor that provides an averaged temperature signal supplied to the microprocessor. The temperature and operating times are shown on display 11.

The constant mixing of platelet concentrate in containers 4 is ensured by swinging the movable platform 3. The motion sensor 17, connected to the motion transmission unit 5, generates signals corresponding to the presence of movement or the absence of movement, which ensures the monitoring of the mixing process of the platelet concentrate, including the control of the oscillation frequency platforms 3. Signals from the motion sensor are fed to the microprocessor 9, which generates information signals supplied to the display 11, the sound alarm unit 18 light signaling node. If there is no swing of the platform 3, the operator decides to urgently eliminate the malfunction or to move the containers 4 with platelet concentrate to a working device.

The nodes of the sound 18 and light 19 signaling contain the necessary sound emitters and light indicators, allowing the operator to obtain the necessary information about the status of the device and process parameters.

All elements of the device can be made on the basis of well-known and widely used in industry elements. Atmel's AT 89 S 8952 series chip can be used as a microprocessor, a set of buttons of type B 170 N as a keyboard, a set of digital seven-segment indicators of type DA 56-11EWA as a display, an electric motor control unit can be made on NOT 561 series, as a node for changing the polarity of the voltage can be applied chip BTS 780 GP company INFINEON TECHNOLOGIES.

Thus, the above set of features allows you to create a device for the safe storage of platelet-containing transfusion media using thermal stabilization systems based on semiconductor thermoelectric elements and providing remote monitoring of the storage process based on the use of modern information technologies.

Claims (2)

1. A device for mixing a platelet concentrate or platelet-containing transfusion media, comprising a housing 1 with a cover 2, a movable platform 3 with containers with platelet or platelet-concentrate transfusion media 4 placed thereon, connected through a motion transmission unit 5 to an electric motor 6 connected to the control unit an electric motor 7, the input of which through a digital-to-analog converter 8 is connected to the first output of the microprocessor 9, connected to the keyboard 10 and the display 11, one or more temperature sensors 12 and the corresponding number of Peltier thermocouples 13, electronic keys 14 and voltage polarity change nodes 15, a first power supply 16 connected to the motor control unit 7 and electronic keys 14, temperature gauges 12 and Peltier thermocouples 13 are located on platform 3, temperature sensors 12 are connected to the inputs of the microprocessor 9, the control outputs of which are connected to the control inputs of the electronic keys 14 and the control inputs of the nodes for changing the polarity of the voltage 15, the electron Keys 14 are connected between the first power source 16 and the inputs of the voltage polarity change nodes 15, the outputs of which are connected to Peltier elements 13, characterized in that it contains a motion sensor 17, which is connected to the motion transmission unit 5 and connected to the microprocessor 9, an audible alarm unit 18 and the light signaling unit 19 connected to the microprocessor 9, the first wireless data transfer driver 20 connected to the microprocessor 9, a personal computer 21, the second wireless data transfer driver 22, connect nny to the personal computer 21, the second power source 23 connected to the second wireless data driver 22 and the personal computer 21, and the connection between the first 20 and second driver 22 of wireless data transmission by means of electromagnetic waves in the radio frequency range. 2. The device according to p. 1, characterized in that the first 16 and second 23 power sources are autonomous.

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