KR100680699B1 - Method of measuring biochemical changes in skin tissue using magnetic resonance spectroscopy - Google Patents

Abstract

The present invention is a biochemical in skin tissue using magnetic resonance spectroscopy that can measure the biochemical changes caused by metabolic infiltrates into the skin tissue using magnetic resonance imaging in a continuous, repetitive and non-invasive way It relates to a change measuring method.

The method of measuring biochemical changes in skin tissues using magnetic resonance spectroscopy (MRS) according to the present invention is a method for measuring biochemical changes occurring in skin tissues, and the skin to be tested by magnetic resonance imaging equipment. Performing primary magnetic resonance spectroscopy on a predetermined portion of the tissue to obtain a primary spectrum; Applying a metabolite to the epidermis of the test subject, and then obtaining a secondary spectrum by performing secondary magnetic resonance spectroscopy on the same region as the first magnetic resonance spectroscopy after a predetermined time elapses; Measuring the biochemical change of the metabolite in the skin tissue by comparing the primary spectrum and the secondary spectrum, and comprising the magnetic echo acquisition method used to obtain the primary and secondary spectra. It is characterized by excluding the water suppression method commonly used in the.

The method of measuring biochemical changes in skin tissue using magnetic resonance spectroscopy according to the present invention is a biochemistry that occurs in skin tissue in a repetitive and non-invasive manner by using skin tissue or a small animal of an anatomical body as a test subject. It is effective to measure the change of enemy.

Description

A measurement method of biochemical change in skin tissue using magnetic resonance spectroscopy

1 is a monitor screen showing the selection of voxel position and size to the skin dermis of the test subject in order to measure the biochemical changes in the skin tissue using magnetic resonance spectroscopy according to the present invention.

FIG. 2 is a first spectrum obtained by performing first order magnetic resonance spectroscopy on the voxels shown in FIG. 1; FIG.

3 is a second spectrum obtained by measuring the first magnetic resonance spectroscopy, after applying a cosmetic to the skin epidermis of the test subject and the second magnetic resonance spectroscopic measurement on the same site as the first magnetic resonance spectroscopy after 3 hours.

The present invention relates to biochemical changes in skin tissues using magnetic resonance spectroscopy, which can measure biochemical changes caused by metabolic infiltration into skin tissue using magnetic resonance imaging apparatus in a continuous, repetitive and non-invasive manner. It relates to a measuring method.

Currently, products that use drug delivery through the skin are widely used, such as cosmetics for skin moisturizing effects such as packs, skins and lotions, scopolamine used for motion sickness, and nitroglycerin and patch contraceptives used for heart disease. have. These products are effective as the appropriate amount of biochemicals are penetrated through the skin, but it is very important to analyze how much biochemicals pass through the epidermis because the skin's epidermis acts as a major obstacle to the passage of biochemicals. I will call it work.

Until now, most skin meters have measured the moisture and oil content of the skin by stripping part of the skin tissue with adhesive tape on the epidermis or by using a video microscope or electromagnetic wave, but in the end, only the skin epidermis was measured. Biochemical changes in the dermis below were unknown unless biopsy was performed. In addition, when measuring the moisture and oil content of the skin using the electromagnetic waves as described above, there was a problem that there is always a possibility that the electromagnetic waves can adversely affect the skin.

Accordingly, the present invention provides a magnetic resonance spectrometer capable of measuring biochemical changes occurring in skin tissue repeatedly and continuously through a non-invasive measuring method using a magnetic resonance imaging apparatus generally used to solve the above problems. It is an object of the present invention to provide a method for measuring biochemical changes in skin tissue using the Magnetic Resonance Spectroscopy (MRS) method.

In order to achieve the above object, a method of measuring biochemical changes in skin tissue using magnetic resonance spectroscopy according to the present invention,

In the method for measuring the biochemical changes occurring in the skin tissue,

Obtaining a first spectrum by performing first magnetic resonance spectroscopy on a predetermined portion of the target skin tissue in a magnetic resonance imaging apparatus;

Applying a metabolite to the epidermis of the test subject, and then obtaining a secondary spectrum by performing secondary magnetic resonance spectroscopy on the same region as the first magnetic resonance spectroscopy after a predetermined time elapses;

Comparing the primary spectrum and the secondary spectrum and measuring the biochemical change of the metabolite in the skin tissue, comprising;

It is characterized by excluding the water suppression method commonly used in the magnetic echo acquisition method used to obtain the primary and secondary spectra.

Hereinafter, preferred embodiments of the present invention will be described in detail.

Magnetic resonance spectroscopy is a method of precisely observing a change in the magnetic resonance signal (frequency) with respect to an applied RF pulse when a subject is placed in a magnetic field, and quantitatively analyzing the structure, components, and states of the subject. Therefore, the biochemical information according to the mechanism of the metabolite in a given sample can be obtained in a method that is harmless to the object to be measured, and the biochemical information is determined according to the type of molecular composition in the sample.

In general, magnetic resonance spectroscopy is known as an excellent technique among the analytical methods used in chemistry and biochemistry. Since 1990, it has been actively used in the clinical field. It is used in the field of brain neuroscience.

In the present invention, it is intended to measure the biochemicals absorbed into the skin tissue by using such magnetic resonance spectroscopy.

In magnetic resonance spectroscopy, countless protons present in the human body are distinguished from each other by analytical chemistry by determining the molecular structure by using the magnetic resonance frequencies that are unique to each other. Magnetic resonance spectroscopy data is expressed as a spectrum representing various signal intensities using a reference compound that provides the frequency of the reference point, and each peak position is expressed as a function of frequency (Hz). The protons that make up the different tissues have the same protons, but because of the surrounding environment, there is a slight difference in chemical and magnetic properties, that is, a local magnetic field. Because of this, the resonance frequency also shows a slight difference so that it can be easily distinguished by spectrum. This fine resonance frequency difference is called chemical shift and peaks at 4.7 ppm, for example for moisture.

In general magnetic resonance spectroscopy, water suppression is performed because it is intended to see peaks of metabolites having a small signal, not water peaks. However, in the present invention, the peaks of various metabolites including water should be measured. Therefore, no water suppression method was performed. To this end, except for chemical shift selective saturation, which is a typical method of water suppression method that is commonly performed at the beginning of the stimulus echo acquisition method, the moisture signal is protected to its original size without damage.

Magnetic resonance spectroscopy according to the present invention may be carried out by using a magnetic resonance imaging apparatus having a magnetic field strength of about 1.5T that is currently used in the clinic, preferably using a magnetic resonance imaging apparatus having a magnetic field strength of 3T or more It is effective. The use of high magnetic field equipment can increase spin net magnetization compared to low magnetic field equipment, which can shorten the shooting time, and it is easy to acquire a small region of interest for acquiring a local region of the MR image. In the case of magnetic resonance spectroscopy, the resolution of the spectrum is improved because the spectrum of the component material appears to be enlarged according to the magnetic field strength.

The method of measuring biochemical changes in skin tissues using magnetic resonance spectroscopy according to the present invention is performed by using non-invasive measurement method by using a small animal such as a rat in addition to a pathological examination method using an anatomical body. Biochemical changes in can be measured repeatedly and continuously.

In addition, the method for measuring biochemical changes in skin tissue using magnetic resonance spectroscopy according to the present invention does not use a cylindrical coil commonly used in magnetic resonance imaging equipment, because the test subject is relatively small. It is desirable to use surface RF coils that can collect data from the circuit.

EMBODIMENT OF THE INVENTION Hereinafter, although the Example of this invention is described in detail, this invention is not limited to a following example, unless the summary is exceeded.

In the embodiment according to the present invention, Bruker, which is a high magnetic field magnetic resonance apparatus in Daejeon Korea Research Institute of Basic Science and Technology, was used. The test subject was obtained by collecting a cadaver forearm skin having a size of 7 × 7 mm. Used. In order to measure the skin moisturizing effect of the metabolite cosmetics, magnetic resonance spectroscopy was performed before and 3 hours after the cosmetic application. Repetition time is 2000ms, Echo time is 10.46ms, Number of Excitation is 256 times, Voxel size is 1.0mV Is the dermis under the skin epidermis, matching before and after applying cosmetics for equivalent experimental conditions. In addition, in order to compare the same site, a single Voxel Spectroscopy (SVS) using a single voxel was performed. In addition, by excluding the chemical shift selective saturation method, which is a representative method among the water suppression methods performed at the beginning of the magnetic resonance spectroscopy stimulus echo acquisition method, the moisture signal is not damaged and protected to its original size.

1 is a monitor screen showing the selection of voxel position and size to the skin dermis of the test subject in order to measure biochemical changes in skin tissue using magnetic resonance spectroscopy according to the present invention, FIG. 2 is shown in FIG. The first spectrum obtained by performing the first magnetic resonance spectroscopy measurement on the voxel, Figure 3 is the first magnetic resonance spectroscopy measurement, after applying the cosmetic to the skin epidermis of the subject 3 hours after the first magnetic resonance spectroscopy measurement It is a secondary spectrum obtained by performing secondary magnetic resonance spectroscopy on the same site as.

The monitor screen shown in FIG. 1 is a skin dermal part of an experiment subject is set as an experimental part in order to perform magnetic resonance spectroscopy, and a part surrounded by a square represents a voxel. The voxel has a size of 1.0 mm 3 as mentioned above, and the voxel location is the dermis area under the skin epidermis.

First, in order to measure biochemical changes in skin dermis, first-order magnetic resonance spectroscopy was performed on a voxel set as an experimental site to obtain a first-order spectrum as shown in FIG. 1.

In the first spectrum shown in FIG. 2, magnetic resonance spectroscopy is performed without using the water suppression method, which was performed at the beginning of the stimulation echo acquisition method, in order to examine in detail the effect of moisture and oil in cosmetics when measuring magnetic resonance spectroscopy. The results of the test are shown. Looking at the first spectrum it can be seen that the peak appears around 4.7ppm and 1.4ppm. Here, the peak appearing around 4.7ppm indicates the spectrum of water, and the peak appearing fine at 1.4ppm indicates the spectrum of oil. The peak size shows the moisture and oil content of the corresponding site.

Next, after applying cosmetics to the skin epidermis of the test subjects, the second spectrum was obtained by performing secondary magnetic resonance spectroscopy to measure biochemical changes in the skin dermis after 3 hours. At this time, the second magnetic resonance spectroscopy measurement was performed by setting the same site as the experimental site in the first magnetic resonance spectroscopy.

The secondary spectrum shown in FIG. 3 was obtained by magnetic resonance spectroscopy measurement on the voxel shown in FIG. 1, and the magnetic spectrum was removed without using the water suppression method, which was performed at the beginning of the stimulus echo acquisition method as in the case of FIG. 2. It is obtained by performing resonance spectroscopic measurement. Looking at the secondary spectra, it can be seen that peaks appear around 4.7 ppm and 1.4 ppm, and the magnitude of the peaks in the primary spectrum shown in FIG. It can be seen that this large amount of penetration.

By comparing the spectra obtained by magnetic resonance spectroscopy as described above, it is possible to easily measure the components and content of the infiltrated substance before and after the metabolite infiltrates the skin tissue.

As described above, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof.

As described above, the method of measuring biochemical changes in skin tissues using magnetic resonance spectroscopy according to the present invention is a non-invasive method for measuring biochemical changes in skin tissues of a test subject using a magnetic resonance imaging apparatus that has been used. Through the method, it is possible to measure repeatedly and continuously.

Claims (3)

In the method for measuring the biochemical changes occurring in the skin tissue, Obtaining a first spectrum by performing first magnetic resonance spectroscopy on a predetermined portion of the target skin tissue in a magnetic resonance imaging apparatus; Applying a metabolite to the epidermis of the test subject, and then obtaining a secondary spectrum by performing secondary magnetic resonance spectroscopy on the same region as the first magnetic resonance spectroscopy after a predetermined time elapses; Comparing the primary spectrum and the secondary spectrum and measuring the biochemical change of the metabolite in the skin tissue, comprising; Method for measuring biochemical changes in skin tissue using magnetic resonance spectroscopy, characterized in that the water suppression method commonly used in the magnetic echo acquisition method used to obtain the primary and secondary spectra are excluded. The method of claim 1, The magnetic resonance spectroscopy measurement method of the biochemical change in the skin tissue using the magnetic resonance spectroscopy, characterized in that carried out using a surface RF coil. The method of claim 1, The magnetic resonance spectroscopy is a method for measuring biochemical changes in skin tissue using magnetic resonance spectroscopy, characterized in that the magnetic resonance imaging apparatus having a magnetic field strength of 3T or more.

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