JPH03165743A - Contrast inhalation gas used for nuclear magnetic resonance tomography and nuclear magnetic resonance tomography using this gas - Google Patents

Abstract

PURPOSE:To inhale the contrast inhalation gas into organism cells via respiration and utilize a primary metabolic mechanism and metabolic materials related to it as they are for photographing by containing the oxygen containing the stable isotope <17>O in the contrast inhalation gas at the abundance ratio larger than the natural abundance ratio. CONSTITUTION:The stable isotope <17>O of oxygen is contained in 100% oxygen gas at the abundance ratio larger than the natural abundance ratio (0.037%), e.g. 40-50%, for the contrast inhalation gas. A nuclear magnetic resonance tomograph (NMR-CT) detects the hydrogen distribution to form an image by detecting the resonance signal of hydrogen mainly contained in water, <17>O has a magnetic spin different from that of <16>O, and the relaxation time of the resonance signal differs for the hydrogen of the ordinary water H2<16>O and the hydrogen of H2<17>O. When the concentration of H2<17>O becomes dense, the time until the resonance signal is erased (transverse relaxa tion time) is made short, thus only the hydrogen of the H2<17>O newly produced by the metabolism of an organism is detected due to the difference of the transverse relaxation time, and the metabolism of cells can be grasped.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention provides a method for obtaining information about the metabolism of a living body when taking a tomographic image of a living body using a nuclear magnetic resonance tomography device (NMR-CT). The present invention relates to a contrast inhalation gas and a tomography method using nuclear magnetic resonance using the contrast inhalation gas.

[Conventional technology]

Compared to conventional X-ray CT scanners, NMR-CT can easily perform tomography on an inclined plane at any angle, and bone and air do not interfere with contrast imaging.
It is also extremely safe as there is no risk of harm to living organisms due to radiation.

For example, by emitting a sine wave signal corresponding to the resonant frequency of hydrogen atoms to the living body, moisture can be reduced to 0rz in the living body.
o) The distribution state of hydrogen atoms present is detected, and tomography is performed based on this.

However, conventional NMR-CT obtains tomographic images based on the distribution state of hydrogen existing in the living body, so although it is possible to visualize the structure of the living body, it is difficult to obtain information regarding metabolic functions. I couldn't do that.

In addition, by administering ``O'' in the form of water (Hz' 70) to warm-blooded animals and observing the distribution of water in the living body using nuclear magnetic resonance imaging, we were able to track the location of 1?0. Although it is possible to do so, it is extremely dangerous to directly introduce water into living organisms.

Therefore, the inventors of the present application injected 170, a stable isotope of oxygen, into a living body as a liquid composition (artificial blood) that is ionically equivalent to blood. By detecting the distribution of H,”O),
We devised a means to obtain information about metabolic function.

That is, l! by NMR-CT. In IrN imaging, the distribution state of hydrogen atoms is determined by detecting the nuclear magnetic resonance signal emitted from the resonated hydrogen, and the time during which the resonance signal is output (1,! sum time)
differs depending on the nature of the oxygen atom bonded to the hydrogen atom, and the relaxation time of the resonance signal emitted from each hydrogen atom is different between H, "O" and H, "O.

Therefore, if I60 is taken into living cells through normal blood and 1)0 through artificial blood, H
Since z' 60 and H21T o are produced, information regarding metabolic function can be obtained by detecting the distribution of hydrogen at Hz 160 or H,"O based on the difference in relaxation time.

[Problem to be solved by the invention]

However, when attempting to incorporate 170 into a living body using artificial blood, an invasive method such as injection must be used, which may impose a certain amount of burden on the subject when, for example, imaging the 1gT layer of a living body. becomes.

In addition, as carriers for 170, those that have a large oxygen-carrying capacity and an ionic composition equivalent to blood are used, but these carriers are still foreign substances to living organisms.
Therefore, it cannot be said that the metabolites involved in the original metabolism g1)ffz are utilized as they are, and when administering in large quantities and over a long period of time, there is a problem in terms of safety.

Furthermore, even if such a carrier composition is stored frozen with its components separated, there is a problem that the quality deteriorates when stored for a long period of time, making long-term storage difficult.

Therefore, when using 170 to obtain information about the metabolic mechanism of a living body, the present invention makes it possible to capture information about the metabolism of living cells by using the original metabolic mechanism and the metabolites involved in it as they are. The goal is to make it possible to take it into the body in a non-invasive manner.

[Means to accomplish the task]

In order to achieve this objective, the contrast inhalation gas used in the nuclear magnetic resonance new calendar imaging according to the present invention contains stable isotopes "o".
It is characterized by containing oxygen in an abundance ratio higher than that naturally occurring.

In addition, I! by nuclear magnetic resonance using the contrast inhalation gas! The frN imaging method involves introducing contrast inhalation gas containing oxygen containing stable isotope +70 at a ratio higher than that naturally occurring, into living cells through respiration, and then using the metabolic action of living cells. H zl produced?
It is characterized by subjecting the hydrogen of o to nuclear magnetic resonance and imaging using the resonance signal of the hydrogen.

[Action of the invention]

Since the contrast suction gas according to the present invention contains oxygen, the oxygen is taken into the blood through breathing action. Oxygen and nutrients are then transported to living cells via the blood, and living cells take in oxygen and nutrients.
It generates bioenergy and performs metabolism that produces and excretes water and carbon dioxide.

Since the oxygen +70 contained in the contrast inhalation gas is the same oxygen as total <1 & O except for the difference in mass, it is used for the metabolism of each living body in the same way as normal oxygen +60.
+70 is H2 in the part of each biological cell where the metabolic a capacity is active.
``O'' is produced in large amounts, and H2''0 is produced in small amounts in areas where the ``1'' function is not active.

Therefore, )(21? Due to the hydrogen resonance signal of Q,
The image shows the area where Hz''O is newly generated due to metabolism.

By observing this change over time, it is possible to determine how the inhaled 170 is being used for metabolism in which part of the body, and at the same time, the parts of the image that change slowly over time indicate metabolic function. It can be determined that the metabolic function is not active, and it can be determined that the metabolic function is active in the part that changes quickly over time.

〔Example〕

The present invention will be described below based on specific examples.

The contrast inhalation gas used in the nuclear magnetic resonance tomography of the present invention is, for example, 100% oxygen gas containing a stable isotope of oxygen +? 0 is mixed in at a natural abundance ratio (0,037%) or higher, for example, about 40 to 50%.

This suction gas is supplied, for example, in a gaseous or liquid state and packed in a cylinder, etc., and the concentration is adjusted at the time of use, or it can be used without adjusting the concentration from a cylinder packed at a predetermined concentration in advance. be done.

Oxygen taken into the living body is taken into the blood from the lungs and sent to each cell along with nutrients, and each cell uses its metabolic function to take in oxygen and nutrients, produce water and carbon dioxide, and excrete them. do.

However, at this time, oxygen taken in through respiratory metabolism is produced and excreted as water (HzO), and oxygen contained in nutrients is produced and excreted as carbon dioxide (COz).

Therefore, even if the isotope 1-0 is included in addition to IhO in the attractive force, 170 is chemically +
Since it is oxygen with exactly the same properties as 60, H2+
hO and H21? 0 will be produced.

In addition, NMR-CT mainly detects the resonance signal of hydrogen contained in water to detect its hydrogen distribution and form an image, but +70 has a different magnetic spin from 1bO, so , the relaxation time of the resonance signal is different between hydrogen in normal water H2160 and hydrogen in H2''O.

Figure 1(a) ~ fcl is 0% Hz ”O, respectively.
2 is a graph showing changes over time in resonance signals output from hydrogen in water containing 1% and 2%.

When the concentration of Hz ”O is 0%, the resonance signal is still output as shown in Figure 1 (even after 1800 msec from a+,
If the concentration is 1%, approximately 1200m5e from Figure 1(b)
c, and when the concentration is 2%, it disappears from Figure 1 (approximately 9 from C1).
It disappeared at 00m5ec.

In other words, as the concentration of H2170 increases, the time it takes for the resonance signal to disappear (transverse relaxation time) becomes shorter, so due to the difference in the yellow relaxation time, H z "O newly produced by the metabolism of the living body It is possible to understand cellular metabolism by detecting only hydrogen.

This is because metabolically active cells produce a large amount of H2"O, while metabolically inactive cells produce only a small amount of H2"O.

Furthermore, since the sensor does not detect normal water but detects Hz"O newly produced through metabolism, it is possible to determine whether or not the metabolic function of a certain region has stopped.

Furthermore, by observing changes in the distribution of Hz'70 over time, it is possible to grasp the metabolic state, which is very effective information for determining, for example, the extent of functional impairment. be.

In addition, in the example, 17
I explained the case of using something mixed with 0, but
1 through metabolic mechanism? As long as O can be introduced into the living body, for example, it is not limited to 100% oxygen gas, but it can be mixed into a non-toxic gas that contains the minimum amount of oxygen necessary to support life, It is also possible to mix 170 into ordinary air (for example, a gas mixed at a ratio of 4 nitrogen to 10 oxygen).

Further, the concentration of '7o can be arbitrarily selected depending on the usage as long as it is higher than the natural abundance ratio.

For example, if you want to shorten the detection time, you can
It is best to use a highly concentrated drug so that it can be quickly supplied to the body, or if biological functions are to be continuously observed over a long period of time, a diluted drug may be continued. .

However, according to the accuracy of current detection devices, the concentration of '7o in oxygen is preferably 10% or more.

[Experiment example]

In this example, as the contrast inhalation gas, 100% oxygen gas containing 46% of the stable isotope "o" was used.

First, a dog weighing approximately 5 kg was anesthetized with bendoparbital (approximately long/kg), and the Shimadzu superconducting MRI system (
Nuclear magnetic resonance images of the head were taken using SMT-100).

Next, about 300 cc of contrast inhalation gas was inhaled for 1.0 minutes under natural breathing, and then a cross section of the brain was imaged while breathing in normal air.

Figure 2 is a tomographic photograph of the brain in the sagittal plane of the head of a dog lying with its mouth facing the right side.

Figure 3 shows the fifth tomographic photograph of areas 1 to 8 surrounded by the white line in Figure 2, in the order of upper left, upper right, lower left, and lower right, respectively, before '70 inspiration and after 8 inspirations. Photographs are shown after 20 minutes, 40 minutes, and 60 minutes.

In Figure 3, the image of the bright part that appears white is Hz'
This is a tomogram based on resonance signals detected from hydrogen in hO. The dark areas that appear black are Hz'? produced by cellular metabolism. This is the part where the resonance signal from the hydrogen of O is output, that is, the part where cell metabolism is actively taking place.

Looking at the changes over time in Figure 3, first of all, the primitive parts (central part) such as the thalamus, which controls respiration, body temperature, etc., appear dark.
It can be seen that the brain is functioning normally in that area even though the patient is under anesthesia.

Then, over time, the black part reaches the surrounding cerebral cortex.

In particular, in the photograph taken after 60 minutes, the dark area in the upper left corner of the brain has expanded considerably, indicating that the higher-order functions of the subject's dog's brain are not sufficiently activated after 60 minutes. I can see that you are recovering.

In this way, using the contrast inhalation gas of the present invention, NMR
- By taking images with CT, it is possible to distinguish between parts of the brain that are actively functioning and those that are not, and by observing changes over time, it is possible to determine how the brain is functioning. can be judged.

〔Effect of the invention〕

As described above, according to the present invention, since the inhalation gas contains oxygen used for metabolism, it has the effect of being able to be taken into the body by simply inhaling it, rather than by injection or drip. .

In addition, "o" is radiochemically stable and biochemically +6
Since it is equivalent to 0, it does not have a negative effect on the living body and the original metabolic function can be used as it is.Moreover, it contains 170 at a ratio higher than the natural abundance ratio, so hydrogen at Hz "O" By detecting this, it is possible to capture information regarding the metabolism of living cells, which is a very excellent effect.

Furthermore, since the stable isotope "o" is a chemically stable substance, it has the advantage that it does not undergo deterioration and can be stored for a long period of time.

[Brief explanation of the drawing]

Figures 1(a) to (C) show Ht''O at 0% and 1%, respectively.
% and 2% of hydrogen in water. Figure 2 is a sagittal tomogram of the head of a dog lying with its mouth facing the right side. 3
The figure is the fifth tomographic photograph from the right of the area surrounded by the white line in Figure 2.

Claims (4)

[Claims] (1) A contrast inhalation gas used for nuclear magnetic resonance tomography, characterized by containing oxygen containing the stable isotope ^1^7O in an abundance ratio higher than that naturally occurring. (2) The contrast inhalation gas used in nuclear magnetic resonance tomography according to claim 1, wherein the stable isotope ^1^7O has an abundance ratio of 10% or more in oxygen. (3) The contrast inhalation gas used in nuclear magnetic resonance tomography according to claim 1, wherein the contrast inhalation gas is a liquefied gas. (4) Contrast inhalation gas containing oxygen containing the stable isotope ^1^7O at a ratio higher than that naturally occurring is taken into living cells through respiration, and the metabolic effects of living cells are A tomography method using nuclear magnetic resonance in which the hydrogen of H_2^1^7O produced by is subjected to nuclear magnetic resonance, and imaging is performed using the resonance signal of the hydrogen.