RU65383U1 - AUTOMATED STRONTIUM-RUBIDIUM INFUSION SYSTEM "RUBIGEN-82" - Google Patents

Abstract

This utility model relates to medical equipment, in particular to means for automating the production of a diagnostic solution from a radionuclide strontium-rubidium generator and remote controlled infusion, with automatic control of the main characteristics of the process. The automated strontium-rubidium infusion system contains a container with an eluent connected by a pipeline of the transportation system through the first and second openings of the first three-way valve with a syringe pump, a strontium-rubidium generator with the first filter and an inlet pressure sensor, and a second three-way valve, the first opening of which is connected by pipelines through the second filter to the means for infusion of the eluate to the patient, and the second hole to the means for collecting and storing excess eluate, means for measuring radio and a control and control unit, wherein the third three-way valve is connected by the first and second holes through pipelines to the third hole of the first three-way valve and the input of the strontium-rubidium generator, respectively, and the generator output is connected to the first hole of the fourth three-way valve, while the third hole of the third the valve and the second hole of the fourth valve are connected by a connecting tube, the monitoring and control system includes the first and second air bubble detectors mounted on t uboprovodah capacitance between eluent and the first port of the first valve and the third opening of the fourth and second valves, respectively connected to the monitoring and control unit comprising a remote computer.

Description

This utility model relates to medical equipment, in particular to automation of the production process of a diagnostic solution from a radionuclide strontium-rubidium generator and remote controlled infusion, with automatic control of the main characteristics of the process, such as the amount of input activity, the amount of occlusion, the presence of air bubbles, and also the weight and activity of the solution in the waste container.

One of the most significant advantages of positron emission tomography (PET) over single-photon emission computed tomography (SPECT) is the possibility of using more long-lived positron emitters and generator systems that cannot be classified as “bioisotopes” for studying biological processes of positron-emitting isotopes. The first in the series of isotope generators for PET are ⁸² Sr (t _1/2 = 25.6 days) → ⁸² Rb (t _1/2 = 75 sec) and ⁶⁸ Ge (t _1/2 = 271 days) → ⁶⁸ Ga generator systems (t _1/2 = 68.3 min).

Therefore, as applied to generator isotopes, we can talk about supplying them with any clinics with PET scanners within a region, state, or group of states.

Generator systems can be especially attractive for so-called mobile PETs mounted in auto-trailers that are called for servicing clinics that have not only their own cyclotrons, but also their own PET scanners. In the absence of "binding"

of such a mobile PET scanner to an isotopic base, the radius of the territory it serves is significantly expanding.

Known strontium-rubidium infusion system for the production of a diagnostic solution from a radionuclide strontium-rubidium generator and conducting controlled infusion (US 4562829, 1986), including a container with an eluent connected to the corresponding pipelines of the transportation system through the first three-way valve with a syringe pump, strontium-rubidium generator with the first filter and inlet pressure sensor, a second three-way valve, the first opening of which is connected through a second filter to the means for infusion of the eluate pa ientu, and the second - an agent for the collection and storage of surplus elution, radioactivity measuring means, and monitoring and control system. The known system is not optimal in terms of protection against radioactive radiation and in the life of the generator column.

The proposed utility model is aimed at eliminating the above disadvantages. The technical result achieved by its use is to increase the efficiency of the diagnostic procedure by automating the infusion procedure, reducing the doses of unwanted radiation to the patient and staff, and increasing the life of the generator column.

The essence of the proposed utility model is that in an automated strontium-rubidium infusion system containing a container with an eluent connected by a pipeline of the transportation system through the first and second openings of the first three-way valve with a syringe pump, a strontium-rubidium generator with the first filter and an inlet pressure sensor , a second three-way valve, the first opening of which is connected by pipelines through the second filter to the means for infusion of the eluate to the patient, and the second hole to the means of I collect and store surplus elution, radioactivity measuring means

and a control and control unit, the third three-way valve is connected by the first and second holes through the pipelines to the third hole of the first three-way valve and the input of the strontium-rubidium generator, respectively, and the output of the generator is connected to the first hole of the fourth three-way valve, while the third hole of the third valve and the second the opening of the fourth valve is connected by a connecting tube, the control and management system includes the first and second air bubble detectors installed on the pipelines between a container with an eluent and a first opening of the first valve and third holes of the fourth and second valves, respectively, connected to the control and management unit, including a remote computer.

In addition, means for measuring radioactivity include first and second activity sensors. In this case, the first activity sensor is placed on the pipeline between the third holes of the fourth and second valves and is made in the form of a beta detector.

Radiation protection of the means for collecting and storing excess eluate can be made in the form of a protective box, including means for monitoring the weight of the waste, for example, a force sensor, and a second activity sensor for radioactive waste, for example, a gamma detector, is installed in the opening of the protective box.

The column of strontium-rubidium generator preferably has radiation protection, including an external main and transport protective containers, while the main protective container is stationary mounted on the shelf of the cart.

The system is installed in a closed, movable housing. In addition, the body is equipped with a sliding worktop.

The essence of the utility model is illustrated by the functional diagram of the infusion system shown in the figure.

The following conventions are used in the figure:

1 - capacity with eluent;

2, 3, 4, 5 - three-way valves,

6, 7 - activity sensors;

8, 9 - pressure sensors;

10 - syringe pump;

11 - strontium-rubidium generator;

12 - control unit;

13 - weight sensor

14 - remote computer,

15, 16 - filters;

17, 18 - detectors of air bubbles;

19 - means for infusion of the eluate to the patient (needle);

20 - a means for collecting and storing excess eluate.

An automated strontium-rubidium infusion system includes means for generating rubidium-82 in a solution that can be administered to a patient, namely a strontium-rubidium generator 11 (FIG. 1), of a conventional type in a transport container. This container is placed in a protective external main box (container) and, together with the latter, performs the function of the main radiation protection. The generator assembly is permanently mounted on the shelf of the trolley (not shown in the figure). The complete system can be installed in a movable housing, which is also equipped with a sliding tabletop, which provides ease of use.

In addition, the system includes means for carrying out infusion, namely: a syringe remotely controlled infusion pump 10 and means for automatically filling it with eluent 1 (0.9% NaCl solution); a system for transporting the eluent and eluate to the patient or waste collector, equipped with multi-way (three-way) valves 2-5, branching the transportation system in accordance with the work program; antibacterial protective equipment, namely antibacterial filters 15 and 16 at the inlet and outlet

transportation systems; means for measuring the activity of the eluate for monitoring and dosing during infusion in a patient 6 and 7; pressure measuring instruments 8 and 9 in the conveyor system, including for measuring occlusion; means for storing waste 20, including measuring the amount of activity and the weight of the solution in the waste tank 13 and protecting against radioactivity; means of automated control of the entire elution process and its components 12, carried out using on-board or remote computers 14.

In the proposed system, a container with an eluent 1 (physiological saline) is connected by a plastic fitting to a pipeline (for example, a Perfuline infusion tube, this tube has an external diameter of 2.5 mm with an internal diameter of 1.5 mm). Pieces of such tubes (pipelines) are then used to build the entire transport system for infusion. The other end of the pipeline is connected through an air bubble detector 17, which generates a control signal to the control and control unit 12 when the air bubble passes, to a three-way valve 2. This valve transfers the infusion system to one of two possible operating modes: (1) filling the syringe during operation syringe pump 10 for suction of saline from a container with eluent 1 (through the first and second valve openings) or (2) infusion, i.e. the supply of saline from the filled syringe of the syringe pump 10 into the infusion system (through the first and third valve openings).

The three-way valve 2 is further connected by a segment of the connecting tube to the first hole of the third three-way valve 4, the second hole of which is connected through the first filter 15 to the inlet of the column of strontium-rubidium generator 11. The pressure control at the inlet to the column of strontium-rubidium generator 11 is carried out by the first pressure sensor 8.

The third hole, valve 4, through a piece of connecting pipe, is connected to the second hole of the fourth three-way valve

5. This valve also has connections to the outlet tube of the column of strontium-rubidium generator 11 (first hole) and the continuation of the infusion system at the third hole.

In the “infusion” syringe pump operating mode, a pair of three-way valves 4, 5, working synchronously, allows either (1) to pump the eluent from the syringe 10 through the column of the strontium-rubidium generator further into the infusion system as an eluate, i.e. a solution enriched with Rb-82, or (2) pump the eluent (physiological solution) into the infusion system, bypassing the strontium-rubidium generator 11. This mode of operation is used when the necessary amount of Rb-82 activity has been accumulated and it must be delivered to the patient 19, and the infusion system should be filled with an inactive eluent at the end of the infusion into the patient. When using the eluent pumping mode, almost the entire infusion system, with the exception of the connecting pipe from the exit from the strontium-rubidium generator to the fourth three-way valve, will be filled with non-radioactive physiological saline and will not be a source of additional undesirable radioactivity to the patient and staff; in addition, the volume of eluent needed to pressurize the accumulated eluate into the patient will not pass through the column of the strontium-rubidium generator and deplete it, because It is known that the potency of the generator depends not only on the time of its operation, but also on the volume of the eluent passed through it.

On the pipeline, from the third hole of the fourth three-way valve 5 to the third hole of the second three-way valve 3, a first radioactivity detector 6 (beta detector) and a second air bubble detector 18 are installed, similar to the first bubble detector 17. The radioactivity detector 6 operates in real time and measures activity Rb-82 at the location of the detector.

A second three-way valve 3 directs the eluate: either (1) through the first opening and second filter 16 into the patient, i.e. on the needle 19, or (2) through the second hole, dumps it into the waste container, means for collecting and storing excess eluate 20. The filling of the waste container with liquid is monitored using a force sensor (not shown in the figure). To measure the radioactivity contained in the waste container, a second radioactivity sensor 7 (gamma detector) is used. Radiation protection of the means for collecting and storing excess eluate is made in the form of a protective box, which includes a force sensor, and a second activity sensor is installed in the opening of the protective box.

During infusion into the patient, the second three-way valve 3 is switched to passing the eluate to the pipeline connected to the needle 19 through the Millipore filter 16. A second pressure sensor 9 is installed on this segment, which allows to measure the occlusion pressure when the solution containing Rb-82 is introduced into the patient.

The process of operation of the strontium-rubidium infusion system occurs under the control of a control computer program, which states the status of each of the devices included in the infusion system at the beginning and end of the step, also describes the actions of these devices and the conditions of their functioning under normal conditions and in the case of emergency occurrence.

To avoid overfilling of the waste collection vessel 20 with radioactive liquid, remote control over the limit value of its level is carried out using a force sensor, while the total tare and liquid weight is monitored, current weight (volume) of the liquid and its limit value are monitored. In addition, fixing the weight of empty containers for waste collection, the system of routine interrogation of the control unit of the installation

receives information that the container is installed in the container. The maximum amount of waste in a container is 250 ml.

The control and control unit is connected to a remote computer, the display of which displays a graphic mnemonic diagram of the generating device, which provides monitoring of controlled parameters in automatic mode and operational control of individual elements (electromagnetic three-way valves 2-5, pump 10) in manual mode. The scheme allows you to monitor the current state of all elements of the generator device (valves 2-5, air bubble detectors 17, 18) and the operation of the syringe pump 10. It also allows you to obtain information about the pressure parameters in the lines from pressure sensors 8, 9, eluate activity on the output of the generator column 11 and the total activity, the weight of the container with waste 20, the activity in the container with waste from the detectors 6, 7.

The control unit 12 of the system is connected to the control elements of the generator set - electromagnetic three-way valves 2, 3, 4, 5 and pump 10, and also includes elements for collecting and processing signals from sensors 6, 7 (radioactivity sensors), 8, 9 ( pressure sensors), 17, 18 (air bubble detectors). The control unit 12 is connected to a panel personal computer (PPC) or any other remote computer 14 via an Ethernet channel. He receives commands from the PPC or the remote computer to perform the individual steps of the generator set work program and informs them of the current state of the elements he controls and the state of the system’s sensors.

Claims (7)

1. An automated strontium-rubidium infusion system containing a container with an eluent connected by a pipeline of the transportation system through the first and second openings of the first three-way valve with a syringe pump, a strontium-rubidium generator with the first filter and an inlet pressure sensor, a second three-way valve, the first opening of which connected by pipelines through the second filter to the means for infusion of the eluate to the patient, and the second hole to the means for collecting and storing excess eluate, means for measuring dioactivity and control and control unit, characterized in that the third three-way valve is connected by the first and second holes through pipelines to the third hole of the first three-way valve and the input of the strontium-rubidium generator, respectively, and the output of the generator is connected to the first hole of the fourth three-way valve, while the third the hole of the third valve and the second hole of the fourth valve are connected by a connecting tube, the monitoring and control system includes the first and second air bubble detectors, tanovlenii pipeline between the container and eluting with a first opening of the first valve and the third holes of the fourth and second valves, respectively connected to the monitoring and control unit comprising a remote computer. 2. The system according to claim 1, characterized in that the means for measuring radioactivity include first and second activity sensors. 3. The system according to claim 2, characterized in that the first activity sensor is placed on the pipeline between the third holes of the fourth and second valves and is made in the form of a beta detector. 4. The system according to claim 2 or 3, characterized in that the radiation protection of the means for collecting and storing excess eluate is made in the form of a protective box, including means for monitoring the weight of the waste, for example, a force sensor, and a second activity sensor is installed in the opening of the protective box for determining the radioactivity of the waste, for example, a gamma detector. 5. The system according to claim 1, characterized in that the column of strontium-rubidium generator has radiation protection, including an external main and transport protective containers, while the main protective container is stationary mounted on the shelf of the trolley. 6. The system according to claim 1, characterized in that it is installed in a closed movable housing. 7. The system according to claim 6, characterized in that the housing is equipped with a sliding tabletop.