RU2753474C1 - Method for low-dose scanning of chest organs, adapted to patient's body weight - Google Patents

Abstract

FIELD: medicine, namely radiology.

SUBSTANCE: invention relates to medicine, in particular radiology, and can be used for low-dose scanning of the chest organs adapted to the weight of the human body. The patient is scanned when the patient is lying on their back with the hands raised to the head, while holding the breath at the depth of inhalation. The length of the scan is provided from the tops of the lungs to the pulmonary sinuses. The current strength on the tube (mA) is 10 mA. At the same time, the voltage on the tube (kv) is set at the level of 100 kV when the patient weighs less than 90 kg. If the patient weighs more than 90 kg, but less than 120 kg, the voltage on the tube is set at 120 kV. If the patient weighs more than 120 kg, the voltage on the tube is set at 140 kV. A computed tomographic dose index (CTDI) of 1.0 mGy is established. The rotation speed of the tube is set to 0.4 s. Data is reconstructed using a model iterative reconstruction with an iteration level of IMR 2. The Y-Sharp Plus filter is installed.

EFFECT: method provides low-dose scanning of the chest organs, adapted to the patient's body weight, through the use of model iterative reconstructions.

1 cl, 2 tbl, 2 ex

Description

The field of technology to which the invention relates is medicine, in particular radiology.

A number of analogues of the proposed technical solution are known from the prior art. The most common is to perform a diagnostic procedure according to a standard protocol, i.e. the basic protocol recommended by the CT scanner manufacturer, [Recommendations of the American Association of Medical Physicists, American Association of Physicists in Medicine, AAPM Adult Routine Chest CT Protocols Version 2.1 5/4/2016]. The images obtained are of good quality, they can diagnose any pathological condition of the chest organs, however, when using standard settings, the average radiation dose is very high, namely, it is 6-8 mSv, depending on the patient's size, which does not allow using this protocol as a preventive study (screening) according to the SanPin 2.6.1.1192-03 standards, so the maximum permissible radiation dose of 1 mSv is exceeded.

Another analogue of the claimed technical solution is a method for screening lung cancer using a low-dose computed tomography protocol, proposed in the course of a large-scale screening study in the United States (National Lung Screening Trial, NLST) [National Lung Screening Trial Research Team. Reduced lung-cancer mortality with low-dose computed tomographic screening. New England Journal of Medicine. 2011. V. 365. No. 5. P. 395-409.] The advantage is the high sensitivity of this solution in the detection of lung cancer. However, the protocols are not adapted depending on the patient's constitution, and the average dose of radiation exposure in this study exceeds 1.5 mSv, which makes it impossible to use it as a screening method in Russia.

Another analogue of the claimed technical solution are scanning methods based on the use of low-dose protocols proposed in a screening study in Europe [Horeweg, Nanda, et al. "Characteristics of lung cancers detected by computer tomography screening in the randomized NELSON trial." American Journal of Respiratory and Critical Care Medicine 187.8 (2013): 848-854.] Protocols were developed with different voltage for the X-ray tube 80-90, 120, 140 kV for patients weighing less than 50, from 50 to 80, more than 80 kg , respectively. The technique is aimed only at screening for lung cancer and does not provide for the use as a method for diagnosing other pathological conditions of the chest organs due to the insufficient quality of images.

Another analogue of the claimed technical solution is a method of carrying out a diagnostic procedure using computed tomography performed according to a low-dose protocol with the characteristics recommended by the American Association of Physicists in Medicine AAPM [Association of Physicists in Medicine Lung Cancer Screening CT Protocols Version 4.0 2/23/16]. The procedure is carried out with different settings depending on the patient's weight: up to 90 kg, 90-120 kg and more than 120 kg. The advantage of this prototype is a reduced dose of radiation when scanning a patient in comparison with standard scanning and the possibility of using the obtained images to identify foci in the lungs and screening for lung cancer. The disadvantage of the prototype is the lack of the possibility of using for the diagnosis of other pathologies of the lungs due to the insufficient quality of the images obtained.

The prototype of the claimed technical solution is the technical solution "Method for screening lung cancer using ultra-low-dose computed tomography in patients weighing up to 69 kg" (V.A. Gombolevsky, V.Yu. Chernina, etc.), RF patent No. 2701922. The advantage of this solution is to obtain an image quality sufficient for performing lung cancer screening tasks with a radiation dose not exceeding 1 mSv. The disadvantage of this invention is the impossibility of its use for the diagnosis of pathological conditions of the chest organs, except for the specified oncopathology.

Disclosure of invention

The technical problem solved by the claimed invention consists in overcoming the limitations of the prototype associated with the identification of only oncopathology, by improving the image quality through the use of iterative reconstructions, while maintaining the radiation dose of less than 1 mSv. Thus, it becomes possible to use the low-dose protocol not only as a screening for lung cancer, but also as a routine diagnosis of various pathologies of the chest cavity organs.

The technical result consists in providing the possibility of diagnosing a wide range of pathologies by means of low-dose scanning of the chest organs by improving the image quality of the low-dose protocol, which expands the indications for its use, including for routine diagnostics of various pathologies of the chest organs.

Known from the prior art routine methods for diagnosing pathological changes in the chest organs using computed tomography contain the following main steps:

- scanning with the patient supine with arms raised to the head;

- scanning with breath holding at the depth of inspiration;

- the length of the scan is set from the apex of the lungs to the pulmonary sinuses.

- the current on the tube (mA) is reduced to 10 mA

In a preferred embodiment of the proposed technical solution, the following image reconstruction parameters are used:

- slice thickness 1 mm

- interval between slices 0.5

- matrix size 512 × 512

Unlike analogs, the claimed invention involves the implementation of the following actions:

- set the voltage on the tube (kv) with a patient weighing less than 90 kg at a level of 100 kV; with a patient weighing more than 90 kg, but less than 120 kg - 120 kV; with a patient weighing more than 120 kg - 140 kW.

- set the computed tomographic dose index (CTDI) 1.0 mGy;

- the time of rotation of the tube (Time rotation) is set to 0.4 s;

- a Y-Sharp Plus filter is installed,

- data reconstruction is carried out using model iterative reconstruction and the iteration level IMR 2

The principal differences of this method from analogs are the equipment of the tomograph with a specialized reconstructor and software. The iteration rate characterizes the level of processing by a specialized reconstructor and reflects the number of repetitions of the algorithm performed to eliminate digital noise. The higher the level, the more repetitions occur, the more digital noise is removed. The lower the level of iteration, the image is sharper and more noisy. The higher the iteration level - the image is less sharp and less noisy. There are 6 levels in total when using Philips software (Mehta D. et al. Iterative model reconstruction: simultaneously lowered computed tomography radiation dose and improved image quality // Med Phys Int J. - 2013. - T. 2. - No. 1. - S. 147-55.). When using a higher iteration level, along with noise, normal structures (for example, interlobular septa in the lung tissue) can be eliminated, which the program will mistake for noise. In our experience, the best rendering quality is provided by the IMR 2 iteration level. Iterative reconstruction (from eng. Iterative - repetitive) repeats the reconstruction several times to better estimate the mathematical assumptions, which allows you to get images with a lower noise level. The ultimate goal of all iterative reconstructions is to extract noise and obtain an image as close as possible to a real object, which results in the possibility of reducing the dose during CT examination.

The novelty of the proposed solution lies in the possibility of diagnosing various pathologies of the chest organs with a radiation dose of less than 1 mSv, previously available only for preventive studies. This was made possible by optimizing low-dose scanning protocols through the use of model iterative reconstructions of IMR 2. Model iterative reconstruction (MIR) works with projection data and reconstructed images and uses reverse and forward data recovery. Model iterative reconstruction is the least sensitive to the appearance of noise when the current on the tube decreases [Mehta D. et al. Iterative model reconstruction: simultaneously lowered computed tomography radiation dose and improved image quality // Med Phys Int J. - 2013. - T. 2. - №. 1. - C. 147-55.]

The parameters of scanning and image reconstruction depending on the patient's weight are shown in Tables 1 and 2. This combination of parameters was selected during the modification of the prototype parameters with optimization due to the use of the model iterative reconstruction of IMR 2, which was not used before.

The claimed method is illustrated by the following examples.

Example 1.

Patient B., 62 years old, weight 83 kg, was referred by a general practitioner for CT scan of the chest organs to exclude pneumonia. When examining a patient in the 9th and 10th segments of the right lung, areas of consolidation of the lung tissue are determined. X-ray conclusion: CT picture of bisegmental pneumonia on the right. A control CT scan of the chest organs was performed 10 days after the primary CT scan. The study revealed a decrease in the size of the previously discovered areas of consolidation, the changes were regarded as positive dynamics. In the first study, the radiation dose was 0.56 mSv, in the second study, it was 0.55 mSv.

The use of the proposed protocol made it possible to fulfill the set diagnostic task and evaluate the effectiveness of treatment. In this case, the radiation dose did not exceed 1 mSv and was several times lower than with standard scanning.

Example 2.

Patient B., 70 years old, weight - 95 kg, was referred by a general practitioner to exclude pneumonia. In the study, the patient revealed bilateral peripheral polysegmental areas of consolidation of lung tissue. X-ray conclusion: bilateral polysegmental pneumonia. The radiation dose was 0.81 mSv.

The use of the proposed protocol made it possible to fulfill the set diagnostic task. In this case, the radiation dose did not exceed 1 mSv and was several times lower than with standard scanning.

Claims (14)

The method of low-dose scanning of the chest organs, adapted to the weight of the human body, containing the stages at which: - scan the patient while the patient is supine with arms raised to the head; - scanning is performed while holding the breath at the depth of inspiration; - provide the length of scanning from the apex of the lungs to the pulmonary sinuses; - set the current on the tube (mA) 10 mA; characterized in that - set the voltage on the tube (kv) with the patient's weight: less than 90 kg - at the level of 100 kV; more than 90 kg, but less than 120 kg - at the level of 120 kV; more than 120 kg - at the level of 140 kV; - set the computed tomographic dose index (CTDI) 1.0 mGy; - set the rotation speed of the tube to 0.4 s; - carry out data reconstruction using a model iterative reconstruction with an iteration level IMR 2; - install the Y-Sharp Plus filter.