RU2627462C1 - Autonomous device for defrosting cryopreserved blood components - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: device for defrosting cryopreserved blood components contained in containers (3) located in a coolant tank (1) contains a microprocessor (14), a control unit (15), a personal computer (16), a battery (17), a generator (18), a switch (19), a mains voltage sensor (20) and a battery charge device (21). In this case, the mains voltage sensor (20) is connected to the AC network and the microprocessor (14), the input of the battery charge device (21) is connected to the AC network, and the output to the microprocessor (14), battery (17) and alternator (18). The alternator (18) is connected to the first input of the switch (19), the second input of which is connected to the AC network, the control input to the microprocessor (14), and the output to the input of the key element (8), whose control input is connected to the microprocessor (14). A temperature sensor (6) and a coolant level sensor (7) are also connected to the microprocessor.

EFFECT: invention provides reliable and highly efficient operation of the device in the event of a power failure, as well as remote monitoring and recording of the parameters of the process of thawing cryopreserved blood components.

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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. Known devices for thawing cryopreserved products — blood (see Water baths of types P-01262-17 and P12-201-10. Valtex International Corporation catalog, 1999-2000, p. 67, 70, utility model RU 20243, U1 , CL A61K 35/14, 10.27.2001).

The disadvantages of these devices are the long thawing time and low quality of thawing of cryopreserved products - blood.

The closest analogue is a device for thawing red blood cells (see RU 2329016, C1, class A61F 7/00, 20.07.2008).

The device for thawing cryopreserved blood components contains a bath for the coolant, a movable basket for placing containers with blood components located in the bath, a drive for shaking the basket with a gear motor and levers, a temperature sensor, a coolant level sensor, a key element, a heating element connected to the outlet a key element, n removable perforated cassettes for placing containers in a basket in which guides for fixing the cassettes are provided, I feed supply and collectors with n + 1 openings for distributing the flow of coolant between the cassettes; circulation pump.

A disadvantage of the known device is its low reliability and low efficiency due to possible damage to the defrosted blood components due to loss of AC voltage, due to violation of the temperature regime, defrosting time, lack of function of shaking containers with defrosted blood components, the lack of remote monitoring and recording of process parameters defrosting.

The technical result to which the invention is directed is to eliminate the above disadvantages and create a device that provides reliable and highly efficient operation of the device in the temperature range up to -140 ° C at a high defrosting speed.

The specified technical result is achieved by the fact that the device for thawing cryopreserved blood components, containing a bath for the coolant, a movable basket for placing containers with blood components, located in the bath, a drive for shaking the basket with a gear motor and levers, a temperature sensor, a coolant level sensor, a key element, a heating element connected to the output of the key element, n removable perforated cassettes for placing containers in a basket in which guides for fixing the cassettes are provided, supply and reception manifolds with n + 1 openings for distributing the heat carrier flow between the cassettes, the circulation pump contains a microprocessor, a control unit, a personal computer, a battery, an alternator, a switch, a voltage sensor and a battery charge device batteries, and the voltage sensor is connected to the AC mains and the microprocessor, the input of the battery charge device is connected to the AC mains, the output to the microprocessor, the battery and the alternator, the alternator is connected to the first input of the switch, the second input of which is connected to the AC network, the control input is connected to the microprocessor, and the output is connected to the input of the key element, the control input of which is connected to the microprocessor, to which a temperature sensor and a coolant level sensor are connected.

In FIG. 1 shows a schematic diagram of a device for thawing cryopreserved blood components.

The device for thawing cryopreserved blood components contains a bath 1 for coolant (water), a movable basket 2 for placing containers 3 with blood components, located in the bath 1, a drive for shaking the basket with a gear motor 4 and levers 5, a temperature sensor 6, a coolant level sensor 7, a key element 8, a heating element 9 connected to the output of the key element 8, n of removable perforated cassettes 10 for placing containers 3 in a basket 2, in which there are guides for iksatsii cassette feeder 11 and a receiver 12 with manifolds n + 1 holes for distributing the coolant flow between the cassettes, the circulation pump 13.

The device for defrosting contains a microprocessor 14, a control unit 15, a personal computer 16, a battery 17, an alternator 18, a switch 19, a voltage sensor 20 and a charge device 21, and the voltage sensor network 20 is connected to an alternating current network and a microprocessor 14, the input of the charge device of the battery 21 is connected to an AC network, and the output to a microprocessor 14, a battery 17 and an alternator 18, the alternator is connected to the first input of the switch 19, the second input of which is connected to the AC network, the control input is connected to the microprocessor 14, and the output is connected to the input of the key element 8, the control input of which is connected to the microprocessor 14, to which the temperature sensor 6 and the coolant level sensor 7 are connected.

The operation of the device for thawing cryopreserved blood components is as follows.

Connect the device to the network. The coolant is poured into the bath 1 (distilled water can be used as the coolant). On the control unit set the temperature of the coolant and give a command to the microprocessor to turn on the device in the mode of heating the coolant. If there is sufficient water in the bath 1 from the coolant level sensor 7, a corresponding signal is supplied to the microprocessor 14, which gives the command to the control input of the switch 19 to connect the output of the switch to the first input of the switch, while the network voltage through the switch 19 is supplied to the input of the key element 8 At the same time, the microprocessor 14, using the control unit 15, gives the command to turn on the key element 8, while the AC voltage is supplied to the heating element 9, the temperature of which of increases, and begins the process of heating the coolant. At the same time, the circulation pump 13 is turned on, which is connected to the output of the key element (communication not shown), which ensures the circulation of the coolant and the uniformity of the temperature of the coolant in the volume of the bath. The use of a circulation pump significantly accelerates the heat transfer process between the heating elements and the coolant and, accordingly, between the coolant and containers with blood components. Reducing the defrosting time, in turn, ensures the preservation of the quality of blood components and reduces the risk of pathogenic reactions in patients who receive this component of blood.

From the temperature sensor 6, data on the temperature of the coolant enters the microprocessor. Automatic control of the temperature of the coolant in the bath 1, necessary for defrosting, is carried out by the microprocessor 14 by turning the key element 8 on and off. If the coolant temperature is lower than the set temperature, the signal on the inclusion of the heating element from the microprocessor is sent to the key element. If the coolant temperature is higher than the set value, the heating element on signal is not received from the microprocessor. The microprocessor is powered by the battery 17.

If the water level is insufficient, the microprocessor does not include the key element 8, the mains voltage does not come to the heating element, the microprocessor gives an alarm signal to the control unit, and the light and sound alarms are turned on at the control unit.

After reaching the set temperature of the coolant, for example 39 ° C, cassettes with containers containing cryopreserved blood components are installed in the bath in special guides, the defrost time is set from the control unit and the function of shaking containers with blood components is activated. In this case, the gear motor is switched on, the movement from which is transmitted to the movable basket using levers 5.

Using a computer 16 connected to a microprocessor 14, remote monitoring and recording of parameters of the process of defrosting cryopreserved blood components is provided. The information obtained allows the operator to make adjustments to the indicators of the defrosting process.

In the absence of AC voltage, the corresponding signal from the voltage sensor network 20 is supplied to the microprocessor. The microprocessor gives a command to the control input of the switch 19 to connect the output of the switch to the first input of the switch, while the voltage of the alternator 18 is supplied through the switch 19 to the key element 8 and then to the heating element. The power supply of the circulation pump in the event of a power failure of the AC network is carried out from the alternator.

During operation of the device, the voltage value of the battery 17 is supplied to the input of the microprocessor 14, which through the charge device of the battery 21 charges the battery from the AC mains. The specified recharging of the battery ensures the operation of the alternator 18 in the absence of AC voltage. A detailed connection of the battery 17 of the battery charging device 21 and the alternator 18 in FIG. 1 not shown.

At the end of the set defrosting time, which depends on the type of blood component (plasma, erythrocyte mass), the initial temperature of the cryopreserved blood component, the number of simultaneously defrosted containers with cryopreserved blood components, the function of shaking containers with blood components is turned off. The perforated cassettes are removed from the basket, the cassettes are opened and polymer containers with defrosted blood components are taken out of them.

As a microprocessor, any commercially available microprocessor can be used, for example, an AMTEL microprocessor,

The key element can be implemented using a standard triac type TC-132 or relay.

As a temperature sensor, a resistance thermoconverter DTS064-50M manufactured by OWEN can be used (product catalog 2016).

The invention allows for the autonomous operation of the device in the event of a power failure, as well as remote monitoring and logging of the parameters of the defrosting process of cryopreserved blood components, which allows for reliable and highly efficient operation of the device in the temperature range up to -140 ° C at a high defrosting speed.

Claims (1)

A device for thawing cryopreserved blood components containing a coolant bath, a movable basket for placing containers with blood components located in the bath, a drive for shaking the basket with a gear motor and levers, a temperature sensor, a coolant level sensor, a key element, a heating element connected to the output of the key element, n removable perforated cassettes for placing containers in a basket in which guides are provided for fixing the cassettes, collecting and receiving collectors with n + 1 openings for distributing the coolant flow between the cartridges, a circulation pump, characterized in that it contains a microprocessor, a control unit, a personal computer, a battery, an alternator, a switch, a voltage sensor and a battery charging device, moreover, the voltage sensor of the network is connected to the AC network and the microprocessor, the input of the battery charger is connected to the AC network, and the output to the microprocessor, battery battery and alternator, the alternator is connected to the first input of the switch, the second input of which is connected to the alternating current network, the control input is connected to the microprocessor, and the output is connected to the input of the key element, the control input of which is connected to the microprocessor to which the sensor is connected temperature and coolant level sensor.

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