RU196435U1 - DEVICE FOR POSITRON EMISSION TOMOGRAPHY - Google Patents

Abstract

The utility model relates to medical equipment, namely to devices for positron emission tomography. The device contains an array of PET detectors with a field of view covering the entire body of the patient being examined, each of the PET detectors containing at least one scintillator crystal connected to a set of photoelectronic multipliers, as well as an information reading and processing unit. The device is made in the form of a continuous cylindrical tube assembled from PET detectors that are tightly adjacent and fastened together and form an array, while a NaI crystal is used as a scintillator crystal, and the information reading and processing unit, which allows simultaneous collection of information from the entire PET detectors mounted on a cylindrical pipe. Using the utility model allows its use in lightweight PET cabinets. 2 ill.

Description

The utility model relates to the field of medical imaging, in particular to radionuclide imaging of cancer foci using positron emission tomography using radiopharmaceuticals based on the gallium-68 generator isotope.

An effective health service requires early diagnosis of diseases and abnormalities in the body. As a result, there is an increased interest in the study of biochemical processes in the human body in vivo. All diseases in the body occur due to malfunctions in the chemical structure of the tissue caused by viruses, genetic abnormalities, and the aging process. Detection of chemical abnormalities provides the earliest diagnosis of the disease, even in the pre-symptomatic stage. Among the variety of diagnostic methods, positron emission tomography (PET) provides researchers with a unique opportunity to visualize the course of biological processes (Marusina M.Ya., Kaznacheeva AO Modern types of tomography. - S.-P.: ITMO, 2006. - 131 p.) . Using a radiopharmaceutical (a substance in which one of the isotopes ( ¹¹ C, ¹³ N, ¹⁵ O, ¹⁸ F, ⁶⁸ Ga, etc.) is embedded in the molecule), PET images can be obtained. A radiopharmaceutical is administered to a visualized subject in which positrons form radioactive decay events of the radiopharmaceutical. Each positron interacts with an electron, annihilation of the electron-positron pair occurs, and two oppositely directed γ-rays are emitted. A ring array of radiation detectors (gantry) with a diameter of 80-100 cm and a width of 10-20 cm, which are a set of scintillation crystals and photoelectronic multipliers connected to the crystal, surrounds the visualized subject and determines the coincident events of oppositely directed γ-rays corresponding to electron-positron annihilation couples. The response line connecting two coinciding directions contains the position of the annihilation event of the electron-positron pair. Such response lines are similar to projection data and can be restored to form a two- or three-dimensional image. PET research in many areas remains the most informative, but also very expensive due to the use of expensive radiopharmaceuticals made on the basis of isotopes obtained on cyclotrons specifically for a specific study, as well as the use of an expensive PET scanner.

The closest in technical essence and selected as a prototype is a device for PET / CT (Badawi RD, Shi N., Hu P. et al. First Human Imaging Studies with the EXPLORER Total-Body PET Scanner. // The Journal of Nuclear Medicine . - 2019. - V.60, No. 3. - P. 299-303), which allows you to scan the entire human body with the entered radiopharmaceutical based on the cyclotron-derived isotope ¹⁸ F and having a field of view of 194 cm. The device consists of 8 axial ring assemblies from PET detectors with a field of view of 24 cm and a distance of 2.5 mm between the assemblies. Each of the PET detectors consists of an array of scintillation crystals of lutetium oxyorthosilicate (LSO) or scintillation crystals of lutetium-yttrium orthosilicate (LYSO), as well as silicon photomultipliers that read signals from the array of detectors. Each ring assembly has its own independent signal analysis and processing system. The device also has a computed tomography (CT) system.

The disadvantage of this device is its high manufacturing cost (due to the use of expensive LSO crystals (LYSO), the use of a complex data reading and processing system, since each detector assembly has its own independent and expensive signal analysis and processing system, as well as an expensive structurally complex computed tomography system), which makes it impossible to use the device in an express study of the patient’s body for the presence of metastases in lightweight PET cabinets, polycl nikah, remote areas and district hospitals.

The technical result of the utility model is to reduce the manufacturing cost of the device for positron emission tomography, which provides scanning of the whole body of the patient, as well as the possibility of using it in an express study for the presence of cancer in lightweight PET rooms, as well as to reduce the cost of the study itself carried out using the above device.

The technical result is achieved by the fact that the device for positron emission tomography contains an array of PET detectors with a field of view that covers the entire body of the patient being examined, while each of the PET detectors contains at least one scintillator crystal connected to a set of photoelectronic multipliers; as well as an information reading and processing unit, in this case, it is made in the form of a continuous cylindrical tube assembled from PET detectors tightly adjacent and fastened together, forming the aforementioned array, while a NaI crystal is used as a scintillator crystal, and a reading and processing unit information that allows for the simultaneous collection of information from the entire aforementioned array of PET detectors is mounted on the aforementioned cylindrical pipe.

The use of Nal crystals as scintillator crystals in the device significantly reduces the cost of manufacturing a positron emission tomography device, which allows the information analysis and processing unit to read and process signals simultaneously from the entire cylindrical array of PET detectors made in the form of a cylindrical tube, which in turn allows you to get a complete visualization of the investigated object without the use of complex additional devices, which also reduces the manufacturing cost devices without harming the quality of visualization of foci of cancer.

The following is an example of a specific implementation of the proposed utility model.

In FIG. 1 shows a diagram of a device for positron emission tomography: 1 - a cylindrical tube, which is an array of PET detectors, 2 - each of the PET detectors of the array, 3 - a NaI crystal, 4 - a set of four photomultipliers, 5 - information reading and processing unit .

In FIG. 2 is a diagram of the device explaining its principle of operation: 1 - a cylindrical tube, which is an array of PET detectors, 2 - each of the PET detectors of the array, 3 - a NaI crystal, 4 - a set of four photomultipliers, 5 - a reading and processing unit .

The device operates as follows. The studied patient with the introduced radiopharmaceutical, in this case, based on the Ga-68 generator isotope, is placed in a cylindrical tube 1, which is an array of PET detectors covering the entire patient’s body, where each detector 2 contains a NaI 3 crystal and four photoelectronic multipliers connected to it 4. In the process of radioactive decay of a radiopharmaceutical, positrons are formed. Each positron interacts with an electron, annihilation of the electron-positron pair occurs, and two oppositely directed γ-quanta are emitted. A cylindrical array of PET detectors completely surrounds the visualized subject and determines the coincident events of oppositely directed γ-quanta, NaI crystals capture 5-keV γ-quanta, and the photoelectronic multipliers connected to them convert the signal and feed it to the information reading and processing unit 5, which collects and processes the signal simultaneously from the entire array of PET detectors and allows you to quickly get the processed signal, which by any technical means is transmitted to the doctor for express ss-diagnosis of the disease.

Thus, this utility model allows for rapid scanning of the entire patient’s body and determination of the presence or absence of cancer in the patient’s organs and tissues at a low cost, both of the device itself and the cost of the study carried out using it.

Claims (1)

A device for positron emission tomography containing an array of PET detectors with a field of view overlapping the entire body of the patient being examined, each of the PET detectors containing at least one scintillator chip connected to a set of photoelectronic multipliers, as well as a reading and processing unit, characterized in that it is made in the form of a continuous cylindrical pipe assembled from tightly adjacent and fastened together PET detectors forming the aforementioned array, while as a crystal and the scintillator uses a NaI crystal, and the information reading and processing unit, which allows for the simultaneous collection of information from the entire array of PET detectors, is mounted on the aforementioned cylindrical tube.

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