RU2330609C1 - Method of magnetic resonance tomographic diagnostics of coronary circulation ischemic disturbances - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: magnetic resonance heart tomography is performed in T1-weighted mode prior to and in 5-30 min after intravenous introduction of paramagnetic, 0.25M MnCl₂ solution, in amount 1 ml/10 kg of body weight. Image amplification index is calculated for cardiac muscle within all regions by formula

where Al is image amplification index;

is intensity of T1-weighted myocardium image on MR-tomograms written down after MnCl₂ solution has been introduced;

is intensity T1- weighted myocardium image on initial non-contrasted MR-tomograms. Coronary ischemia is diagnosed within that heart region where the image amplification index is less than 1.10.

EFFECT: method provides reliable diagnostic effect and reduces diagnostics cost.

1 ex, 6 dwg

Description

The invention relates to medicine, namely to the field of radiation diagnostics and cardiology, and can be used in magnetic resonance imaging when conducting magnetic resonance imaging studies of blood supply to the myocardium.

A known method of magnetic resonance imaging of ischemic disorders of the myocardial blood supply, presented in detail by S. Plein et al. [1], which consists in the intravenous administration of the subject compounds Gd-diethylene triamine pentaacetate (DTPA) (sold under the name Magnevist by Schering, Austria, as well as by Nicomed-Amersham - called Omniscan) followed by recording a multiphase fast gradient echo sequence of magnetic resonance imaging images using a high-field superconducting MR a chart with a field strength of 1.5 T and subsequent three-dimensional reconstruction of the temporal characteristics of the distribution of Gd-DTPA in the myocardium, with the calculation and visual representation of myocardial blood flow.

This method is the closest to the claimed technical essence and the achieved result and is selected as a prototype.

The disadvantage of this method is the high cost of the contrasting drug Gd-DTPA, exceeding one study of $ 75 [2], as well as the need for research on a high-floor MRI scanner with a superconducting magnet and using complex specialized algorithms for reconstructing images of the distribution of blood supply to the heart. Due to these economic factors, the availability of the method of magnetic resonance imaging tomographic diagnosis of blood circulation of the heart muscle for practical healthcare is reduced, and the time required for the study is increased. On the most widespread magnetic resonance imaging scanners with medium and low magnetic field strengths, this prototype method cannot be implemented.

The aim of the invention is the possibility of implementing a method for the diagnosis of ischemic disorders of the blood supply to the myocardium on low-floor magnetic resonance imaging and reducing its cost.

This goal is achieved by a technical solution, which is a method of magnetic resonance imaging diagnosis of ischemic coronary circulatory disorders, which consists in performing magnetic resonance imaging of the heart in T1-weighted mode before and 5-30 minutes after intravenous administration of a paramagnet, 0.25 M MnCl solution ₂ , in an amount of 1 ml / 10 kg of body weight, and an image enhancement index is calculated for all areas of the heart muscle by the formula

- YIU - image gain index

- интенсивность T1-взвешенного изображения миокарда на МР-томограммах, записанных после введения раствора MnCl₂.-

- the intensity of the T1-weighted image of the myocardium on MRI scans recorded after the introduction of a solution of MnCl ₂ .

- интенсивность T1-взвешенного изображения миокарда на исходных неконтрастированных МР-томиограммах, и диагностируют коронарную ишемию в той области сердца, где индекс усиления изображения составляет менее 1,10.-

- the intensity of the T1-weighted image of the myocardium in the initial non-contrasted MR-tomograms, and coronary ischemia is diagnosed in the area of the heart where the image enhancement index is less than 1.10.

New in the proposed method is the use as a contrast agent for imaging myocardium in MR tomography of a solution of the compound MnCl ₂ , as well as a formula for calculating the intensity gain index of a T1-weighted image

,

,

and diagnosis of coronary ischemia with IU values less than 1.10.

Mn (II) is a biological trace element present in blood plasma and normal [3], while Gd is not present in the human body. The principal advantage of MnCl ₂ is that, unlike other contrast agents-paramagnets, it is not outside, but an intracellular contrast agent and, when administered intravenously, accumulates in the myocardium in proportion to blood flow [4]. At the same time, for the diagnosis of ischemic myocardial blood supply by MRI, the MnCl ₂ compound was not used, and quantitative criteria for the diagnosis of coronary circulatory disorders with its help were not presented.

As can be seen from figure 1, there is a high degree of amplification of the intensity of the T1-weighted image by the compound MnCl ₂ as a paramagnetic contrast preparation for MR imaging in T1-weighted mode starting from low concentrations. Figure 1 presents a section view of a T1-weighted MRI tomogram of phantoms with a capacity of 100 ml with different contents of the paramagnetic contrast agent - MnCl ₂ - in physiological saline. Parameters of a T1-weighted MRI scan: Time Repetition = 400-800 ms, Time Echo = 15 ms, Flip Angle = 90 °, Number of slices = 5, Thickness of slices = 7 mm . Image recording matrix = 192 * 256, Field of view = 350 mm. The number of repetitions = 5. The intrinsic intensity of the image of the phantom wall made of plastic was less than 40 intensity units.

The quantitative results of experimental studies of the intensification of the intensity of a T1-weighted MRI image on phantoms using MnCl ₂ are shown in Figs. 2, 3. In particular, it can be seen that at concentrations of the MnCl ₂ compound in phantoms from 0 to 1 mM corresponding to the concentrations achieved in the myocardium or in pathological neoplasms with the introduction of the usual dosages of paramagnetic contrast agents for MR imaging, the increase in the intensity of the T1-weighted MRI image caused by MnCl ₂ exceeds the amplification e intensity induced by the complex Gd-DTPA (figure 2). At high concentrations of MnCl ₂ exceeding 2 mM, the intensity of the T1-weighted image in phantom studies of MnCl _{2 is} slightly lower than the intensity of the T1-weighted image obtained using Gd-DTPA. As can be seen from the data of FIG. 3, a pronounced increase in the intensity of a T1-weighted MRI image is achieved already at physiological non-toxic concentrations of MnCl ₂ unchanged in a wide range of repetition time indicators (TR) commonly used to obtain T1-weighted images. This allows you to use the method for various protocols of magnetic resonance imaging in T1-weighted mode.

In an experimental study in rabbits (Figs. 4, 5), as a result of the introduction of MnCl ₂ , a significant increase in the intensity of the T1-weighted signal of the perfused left ventricular myocardium is achieved, which is visible to the eye, compared with the initial intensity, which is almost close to the background, and also compared to the indicated arrow area of experimental ischemic damage. When calculating the gain index of a T1-weighted image

in all cases of ischemic damage, its value turned out to be less than 1.10, and in intact regions - more than 1.10 (Fig.6).

Economically, the use of Gd-DTPA compounds is costly, since the cost of one injection of the drug is at least $ 75 [3], while the cost of 100 g of dry MnCl ₂ sufficient to obtain more than 1000 doses of MnCl ₂ solution to visualize myocardial circulation by the claimed method is up to 12 US dollars [5].

Distinctive essential features characterizing the invention, showed in the claimed combination of new properties that are not explicitly derived from the prior art in this field and are not obvious to a specialist.

An identical set of features was not found in the study of patent and medical literature.

This invention can be used in practice for the diagnosis of coronary ischemia. Based on the foregoing, the present invention should be considered relevant to the criteria of "Novelty", "Inventive step", "Industrial applicability".

The invention will be clear from the following description and the accompanying drawings.

Figure 1. Visual changes in the intensity of a T1-weighted image of phantoms containing MnCl ₂ at concentrations of 0-2 mM / L.

Figure 2. The dependence of the intensity of the T1-weighted image of phantoms containing MnCl ₂ , Mn-EDTA and Gd-DTPA (TR = 420 ms, TE = 15 ms), on the concentration of the substance in the phantom solution.

Figure 3. The dependence of the intensity of a T1-weighted MRI image of phantoms on the content of MnCl ₂ in them, with a change in the repetition time (TR) from 400 to 700 ms.

Figure 4. T1-weighted image (TR = 420 ms, TE = 15 ms) of the chest and heart of a rabbit with experimental ischemic myocardial damage (the area of damage is indicated by an arrow) before the introduction of MnCl ₂ .

Figure 5. T1-weighted image (TR = 420 ms, TE = 15 ms) of the rabbit’s chest after administration and rabbit’s heart with experimental ischemic myocardial damage (the lesion is indicated by the arrow) MnCl ₂ .

6. Gain values of T1-weighted image

areas of ischemia and intact myocardium.

The method is as follows.

The examinee is placed on the diagnostic table of an MRI scanner in a convenient manner in accordance with the design requirements of a particular MRI scanner. Then, magnetic resonance imaging is performed in a T1-weighted mode, observing the repetition time (TR) parameters within TR = 400-1000 ms, in axial, sagittal or frontal planes, or in planes oriented along the long and short axes of the heart, with full coverage of the chest area, with the location of the heart in the center of the visualization area. The study can be carried out both with synchronization of recording MRI images by ECG trigger, and without it.

Then, 0.25 M MnCl ₂ solution is administered intravenously at the rate of 1 ml / 10 kg of body weight. Administration is carried out intravenously slowly at a rate of 1 ml / 5 s or less. Then, 5 minutes or more after the introduction of MnCl ₂ , magnetic resonance imaging is repeated, observing the same research parameters and with the same location of the tomographic sections as before the introduction of this paramagnetic contrast agent. To ensure the best quality of diagnostic images, the introduction of a paramagnetic contrast medium is performed without displacing the patient with a relative magnetic resonance imager.

Then compare the intensity of the images of magnetic resonance imaging in T1-weighted mode before and after the introduction of the compound MnCl ₂ . The enhancement of the MRI image of the myocardium as a result of the introduction of MnCl ₂ occurs in proportion to the accumulation of this drug, which in turn reflects the level of blood flow in the myocardial tissue. For all diagnostically significant regions of the myocardium, the magnification index of the T1-weighted image is calculated

.

.

In all areas of myocardial ischemia, its value is less than 1.10, and in intact areas of the myocardium - more than 1.10 (Fig.6).

The proposed method was used on 7 rabbits with experimental myocardial infarction and on 8 healthy rabbits. The experiments were conducted on rabbits with experimentally obtained myocardial infarction, created by ligation and electrothermocoagulation of the trunk of the anterior descending coronary artery, with ischemia (infarction) of the septum and the anterior wall of the left ventricle.

Example. Changes in the pattern of a T1-weighted MR imaging upon administration of the MnCl ₂ compound to an experimental animal (rabbit) with experimental left ventricular myocardial infarction in the septum.

Initially, an experimental animal (silver chinchilla rabbits weighing 4,500 ± 50 g) is performed MR imaging without introducing contrast in a T1-weighted mode, with the parameters of the repetition time TR = 400 ms and the excitation time TE = 15 ms. The image of the T1-weighted MRI tomogram of the rabbit before the introduction of a contrast medium is presented in figure 4. Transverse MR images of the rabbit body at the level of the middle of the left ventricle in T1-weighted mode (TR = 420 ms, TE = 15 ms, thickness of the tomographic section 5 mm). MRI was performed first before intravenous administration of 0.9 ml of a 0.25 M solution of MnCl ₂ . The extremely weak visualization of the myocardium of both the left and the right ventricle without the introduction of a paramagnetic contrast agent is obvious.

Then, a solution of MnCl ₂ is introduced intravenously into the marginal vein of the ear at a dosage of 0.5 M / kg body weight. Repeated MR imaging is performed at a constant position of the rabbit body and in the same T1-weighted mode (TR = 400 ms, TE = 15 ms). An analysis of MRI images contrasted with MnCl ₂ shows (Fig. 5) a pronounced increase in the intensity of a T1-weighted image in the region of an intact myocardium, which corresponds to normal blood supply and high accumulation of the MnCl ₂ preparation in the heart muscle. Thus, MnCl ₂ uniformly accumulates in the heart muscle and causes a pronounced image enhancement in them, with a minimum increase in the intensity of a T1-weighted diffuse image in muscle tissue, correspondingly, significantly lower blood flow in it compared to the myocardium.

The introduction of the drug does not cause any pathological or physiological reactions and was not accompanied by any significant changes in the blood picture or physical condition of the animal.

Based on the greater availability and low cost of the drug used, the high efficiency of the method in an animal experiment, we can conclude that the proposed method allows you to visually diagnose ischemic myocardial blood supply disorders using any magnetic resonance imaging scans that can receive T1-weighted tomograms, as well as allows you to reduce the cost of the study compared to traditionally used methods for visualizing impaired myocardial blood supply with with the help of high-field superconducting magnetic resonance imaging scanners.

Literature:

1. Plein S., Ridgway J.P., Jones T.K., Bloomer T.N., Sivananthan M.U. Coronary Artery Disease: Assessment with a Comprehensive MR Imaging Protocol-Initial Results. // Radiology 2002; 225: 300-307.

2. http://www.pharmindex.ru/dist_offers.asp?pid=2064&rgn=77.

3. Takagi Y., Okada A., Sando K., Wasa M., Yoshida H., Hirabuki N. Evaluation of indexes of in vivo manganese status and the optimal intravenous dose for adult patients undergoing home parenteral nutrition // Am J Clin Nutr 2002; 75: 112-8.

4. Chauncey D.M. Jr, Schelbert H.R., Halpern S.E. et al. Tissue distribution studies with radioactive manganese. // J. Nucl. Med.- 1977. - V.18. - No. 9. - P.933-936.

5. ICN biochemicals and reagents catalog 2002-2003, p. 450.

Claims (1)

The method of magnetic resonance imaging diagnosis of ischemic coronary circulatory disorders, which consists in performing magnetic resonance imaging of the heart in T1-weighted mode before and 5-30 minutes after intravenous administration of a paramagnet, 0.25 M MnCl ₂ solution, in an amount of 1 ml / 10 kg of body weight and calculate the image enhancement index for all areas of the heart muscle by the formula

where YIU - image gain index;

- the intensity of the T1-weighted image of the myocardium on MRI scans recorded after the introduction of a solution of MnCl ₂ ;

- the intensity of the T1-weighted image of the myocardium in the initial non-contrasted MRI tomograms, and diagnose coronary ischemia in the area of the heart where the image enhancement index is less than 1.10.

Images