JP2000217800A - Esr imaging device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily position an object to be measured and to easily search ESR signals from the measurement object by attaching a standard material generating the ESR signals onto a fixing tool for fixing the measurement object provided on a holding and moving mechanism. SOLUTION: The measurement object 8 of ESR imaging which is an experimental small animal such as an anesthetized mouse is fixed and held on a sample base 9 and then moved and inserted to the internal space of a loop gap resonator 5 and the measurement of ESR imaging is performed. At the time, at a position for not affecting the fixation of the measurement object 8, a prescribed position provided on the side wall of the sample base 9 for instance, the standard material 16 generating the strong ESR signals of DPPH or the like is attached. In such a manner, since the position of the sample base 9 is recognized on imaged ESR images, the measurement object 8 is easily positioned and installed at the appropriate position inside the loop gap resonator 5.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to an ESR imaging apparatus, and more particularly to an ESR imaging apparatus for measuring small experimental animals such as mice and guinea pigs.

[0002]

2. Description of the Related Art An ESR apparatus applies a high-frequency magnetic field to a sample placed in a static magnetic field in a direction orthogonal to the direction of the static magnetic field, and observes high-frequency resonance absorption by unpaired electrons contained in the sample. It is a device to do. In recent years, an ESR imaging apparatus has been developed which superimposes a gradient magnetic field on the static magnetic field of the ESR apparatus to image the spatial distribution of unpaired electrons.

FIG. 1 schematically shows a configuration of an ESR imaging apparatus. The high frequency oscillated from the high frequency oscillator 1 is attenuated to an appropriate power by the step attenuator 2, and then supplied to the loop gap resonator 5 via the circulator 3 and the high frequency line 4. The loop gap resonator 5 is placed in a magnetic pole gap where a magnetic field generated from the static magnetic field coil 6 and the gradient magnetic field coil 7 is superimposed.

The resonator axis of the loop gap resonator 5 is arranged in a direction perpendicular to the static magnetic field direction (z-axis direction) (ie, in the x-axis direction), so that the high-frequency magnetic field and the static magnetic field are orthogonal to each other. Has become. In the loop gap resonator 5, an experimental small animal such as an anesthetized mouse or guinea pig is placed on a sample table 9 as an object 8 to be measured.
Inserted along the resonator axis.

[0005] The coupling of the high frequency supplied to the loop gap resonator 5 is adjusted by the movable coupler 10 so that there is no reflected wave. If the measuring object 8 is ES
If high frequency absorption is caused by the R phenomenon, the coupling between the loop gap resonator 5 and the high frequency line 4 is deviated, and a reflected wave is generated from the loop gap resonator 5. This reflected wave,
Take out through the circulator 3 and the high-frequency detector 11
The result of detection by the high frequency detector 11 is converted into image data by the data processing device 12.

In order to apply an appropriate bias to the high-frequency detector 11, a part of the high-frequency wave oscillated from the high-frequency oscillator 1 is branched by the directional coupler 13, the phase is adjusted by the phase shifter 14, and then the phase is adjusted again. An operation of merging with the directional coupler 15 is added.

[0007]

In such a configuration, when an object to be measured such as an experimental small animal is inserted into the internal space of the loop gap resonator and ESR imaging is measured, the position of the object to be measured is determined by the position of the sample. It has to be calculated from the initial value and the movement amount of the table feed mechanism, and there is a problem that the positioning of the measurement target is difficult. In addition, since there is no index of the ESR signal on the sample stage, it is difficult to bring the part to be measured at the optimum position in the loop gap resonator, and it is difficult to search for the ESR signal from the object to be measured. there were. In addition, when ESR imaging is measured using the same experimental small animal as that measured last time, there is a problem that the position of the measurement object and the measurement reference position cannot be matched with good reproducibility. .

An object of the present invention is to provide an ESR imaging apparatus capable of easily positioning a measurement target and easily searching for an ESR signal from the measurement target in view of the above points. It is in. Another object of the present invention is to provide an ESR imaging apparatus capable of matching the position of a measurement target with a reference position for measurement with good reproducibility.

[0009]

To achieve this object, an ESR imaging apparatus according to the present invention comprises a means for generating a static magnetic field, a high-frequency resonator arranged in the static magnetic field, and a high-frequency resonator. A holding and moving mechanism for holding the object to be measured therein and moving the object to be measured in the axial direction of the high-frequency resonator, a gradient magnetic field generating means for applying a gradient magnetic field to the object to be measured, and a high-frequency resonator An ESR imaging apparatus comprising: a high-frequency oscillator that oscillates a high frequency supplied to the high-frequency resonator; a high-frequency detector that detects a high frequency from a high-frequency resonator; and a data processing unit that converts a detection signal from the high-frequency detector into image data. Provided on a holding and moving mechanism, on a fixture for fixing the measurement object,
It is characterized in that a standard substance that emits an ESR signal is attached.

Also, means for generating a static magnetic field, a high-frequency resonator arranged in the static magnetic field, an object to be measured held in the high-frequency resonator, and an object to be measured in the axial direction of the high-frequency resonator A holding and moving mechanism for moving an object, a gradient magnetic field generating means for applying a gradient magnetic field to the object to be measured, and a high-frequency oscillator for oscillating a high frequency supplied to a high-frequency resonator,
A high frequency detector for detecting a high frequency from the high frequency resonator,
An ESR imaging apparatus comprising: a data processing means for converting a detection signal from a high-frequency detector into image data; and an ESR signal provided near the fixture for fixing the object to be measured, provided on the holding and moving mechanism. It is characterized in that the emitted reference material is movably mounted.

A fixture provided on the holding and moving mechanism for fixing the object to be measured is composed of a pair of vertically movable holding members, and is slidably mounted on the holding and moving mechanism. It is characterized by:

[0012]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 2 shows an ESR according to the present invention.
1 schematically illustrates an embodiment of a main part (a peripheral part of a sample stage) of an imaging apparatus.

As shown in FIG. 2, an object 8 to be measured by ESR imaging, which is a small experimental animal such as an anesthetized mouse or guinea pig, is fixed and held on a sample table 9 and the inside of a loop gap resonator 5. Moved and inserted into space, ES
Used for measurement of R imaging. At this time, DPPH (2,2-diphenyl-1-picrylhydrazyl; 2,2-diphenyl; DPPH) is located at a position that does not affect the fixation of the measurement object 8, for example, at a predetermined position provided on the side wall of the sample table 9. -1-pi
Attach a reference material 16 that emits a strong ESR signal, such as crylhydrazyl).

In this way, the imaged E
Since the position of the sample table 9 is known on the SR image, it is easy to position and install the measurement target 8 at an appropriate position in the loop gap resonator 5. When the reference signal is ESR
Can be used as a measurement marker, and thus a standard substance 16 such as DPPH can be used.
There is a merit that it is easy to search for and determine a weak ESR signal derived from the measuring object 8.

FIG. 3 schematically shows another embodiment of a sample stage for an ESR imaging apparatus according to the present invention. In the invention shown in FIG. 3, the sample stage 9 is provided with a reference portion fixing tool 17 composed of a pair of vertically movable holding members for fixing a reference portion such as an ear.
8 so as to be slidable. ES, which is an experimental small animal such as an anesthetized mouse or guinea pig,
The object 8 to be measured for R imaging is
By being pressed by 7, it is fixed and held on the sample table 9.

As a method of aligning the position of the reference part of the measuring object 8 with the position of the reference part fixing tool 17, the measuring object 8 is placed on the sample table 9, and then the reference part fixing tool 17 is moved to the reference part of the measuring object 8. (For example, the position of the ear). A reference material 16 that emits a strong ESR signal, such as DPPH, is attached to the pair of reference portion fixing tools 17 to be aligned.

This makes it possible to improve the reproducibility of the positional relationship between the standard substance 16 and the object 8 to be measured.
Not only that, the distance from the ear to each organ such as the brain, stomach and liver is measured by the standard material 1 attached to the reference site fixture 17.
6 from the position of the ESR signal derived from
In addition to being able to predict the appearance position of the signal derived from each organ on the SR image, it is possible to accurately know on the image how far the position of the organ to be ESR-imaged is from the ear position. Reference material such as DPPH at the position 1
By superimposing the six reference signals, it is possible to easily compare the previous imaging result with the current imaging result.

In the present embodiment, the standard material 16 is provided on the reference region fixing tool 17, but the standard material 16 and the reference region fixing device 17 are not necessarily required to be integral, and After fixing with the fixture 17, the standard substance holder provided near the reference part fixture 17 separately from the reference part fixture 17 is moved to the reference part of the measurement object 8, and the standard substance 16 and the measurement object are moved. The position of the object 8 may be adjusted.

[0019]

As described above, according to the ESR imaging apparatus of the present invention, a strong ESR signal is generated at a position that does not affect the fixation of the measurement object, for example, at a predetermined position provided on the side wall of the sample stage. Since the standard substance is attached, the measurement target can be easily positioned when measuring the ESR imaging, and the ESR signal from the measurement target can be easily searched.

Further, for example, a reference portion fixing device is provided for fixing a reference portion such as an ear, and is fixed and held on the sample table by a fixing method using the reference portion as a fixing reference, and is strong against the reference portion fixing device. Since the standard substance that emits the ESR signal is attached, not only the reproducibility of the positional relationship between the measurement object and the standard substance can be improved, but also the appearance position of the signal derived from each organ on the ESR image is predicted. In addition to this, it is now easy to compare the previous imaging result with the current imaging result.

[Brief description of the drawings]

FIG. 1 is a diagram showing a configuration of a general ESR imaging apparatus.

FIG. 2 is a diagram showing one embodiment of an ESR imaging apparatus according to the present invention.

FIG. 3 is a diagram showing another embodiment of the ESR imaging apparatus according to the present invention.

[Explanation of symbols]

1. High frequency oscillator 2. Step attenuator 3.
・ Circulator, 4 ・ ・ ・ High frequency line, 5 ・ ・ ・ Loop gap resonator, 6 ・ ・ ・ Static magnetic field coil, 7 ・ ・ ・ Gradient magnetic field coil, 8 ・ ・ ・ Measurement object, 9 ・ ・ ・ Sample stand, 10 coupler, 11 high frequency detector, 12 data processing device, 1
3 ... Directional coupler, 14 ... Phase shifter, 15 ... Directional coupler, 16 ... Standard substance, 17 ... Reference site fixing tool, 18
···groove.

Claims (3)

[Claims] 1. A means for generating a static magnetic field, a high-frequency resonator disposed in the static magnetic field, and an object to be measured held in the high-frequency resonator and to be measured in an axial direction of the high-frequency resonator. A holding and moving mechanism for moving an object, a gradient magnetic field generating means for applying a gradient magnetic field to the object to be measured, a high frequency oscillator for oscillating a high frequency supplied to a high frequency resonator, and detecting a high frequency from the high frequency resonator In an ESR imaging apparatus comprising a high-frequency detector and a data processing means for converting a detection signal from the high-frequency detector into image data, an ESR imaging device is provided on the holding and moving mechanism, on a fixture for fixing the object to be measured. An ESR imaging apparatus comprising a standard substance that emits an ESR signal. 2. A means for generating a static magnetic field, a high-frequency resonator arranged in the static magnetic field, and an object to be measured held in the high-frequency resonator and to be measured in an axial direction of the high-frequency resonator. A holding and moving mechanism for moving an object, a gradient magnetic field generating means for applying a gradient magnetic field to the object to be measured, a high frequency oscillator for oscillating a high frequency supplied to a high frequency resonator, and detecting a high frequency from the high frequency resonator In an ESR imaging apparatus comprising a high-frequency detector and data processing means for converting a detection signal from the high-frequency detector into image data, in the vicinity of a fixture provided on the holding and moving mechanism for fixing the object to be measured. An ESR imaging apparatus characterized in that a standard substance that emits an ESR signal is movably attached thereto. 3. A fixing tool provided on the holding and moving mechanism for fixing the object to be measured is constituted by a pair of vertically movable holding members, and is slidably mounted on the holding and moving mechanism. 3. The ESR imaging apparatus according to claim 1, wherein: