JPH0759554A - Biological tissue display method and device - Google Patents

Abstract

(57) [Summary] [Object] The present invention relates to a biological tissue display device, and an object thereof is to display in a state where the relationship between the activity state of MGF and the biological current can be easily grasped. [Structure] A fluorescence microscope 31 that produces a magnified fluorescence image of MGF of the ganglion, a TV camera 32 that captures this image, a TV monitor 34 that displays the image captured by the TV camera 32, and M
The glass microelectrode 37 for taking out the bioelectric current of GF and the waveform of the bioelectric current taken out by the electrode 37 are displayed on the TV monitor
4 and a computer 33 for displaying a window at the right corner of the window 4.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and apparatus for displaying living tissue.

In recent years, with the development of confocal laser scanning microscopes and fluorescent dyes for staining various cells, it has become possible to observe changes in the fine structure of living cells over time, and in the fields of science and medicine, biological Functional studies are underway.

In this research, the displayed image is
It is desirable to be able to easily understand the activity status of biological tissues.

[0004]

2. Description of the Related Art FIG. 5 shows a conventional biological tissue display device 10. The device 10 is generally a microscope 11 and a TV camera 12.
The TV monitor 13 and the oscilloscope 14.

The biological sample 15 is transferred to the T
An enlarged image 17 of the tissue of the biological sample 15 is taken by the V camera 12 and displayed on the TV monitor 13.

On the other hand, from the biological sample 15 to the probe electrode 18
The bioelectric signal taken out through the preamplifier 19
Through the oscilloscope 14 and is displayed here as waveform 20.

[0007]

According to the conventional device 10, a magnified image 17 of a tissue of a living body and a waveform 20 of a bioelectric signal are obtained.
Since and are displayed in different places, the researcher observes while watching both the TV monitor 13 and the oscilloscope 14.

Therefore, it has been difficult to grasp the relationship between the activity status of the living tissue and the bioelectric signal.

Further, the activity status of the living tissue and the bioelectric signal cannot be recorded in association with each other, which is inconvenient for analysis.

Therefore, it is an object of the present invention to provide a biological tissue display method and device that solve the above problems.

[0011]

According to a first aspect of the present invention, an image of a living tissue obtained from a microscope is displayed on a screen of a display device, and a part of the screen of the display device is displayed on the display device. The waveform of the bioelectric signal detected from the living tissue is also displayed.

According to a second aspect of the present invention, an optical microscope for obtaining a magnified image of living tissue, a television camera for picking up an image obtained by the microscope, an electrode for taking out a bioelectric signal of the living tissue, and a display device. And a computer for displaying a fluorescence magnified image of a biological tissue on the screen of the display device and also displaying the waveform of the bioelectric signal on a part of the screen.

According to a third aspect of the present invention, a confocal laser scanning microscope for obtaining a confocal fluorescence image of a living tissue, an electrode for extracting a bioelectric signal of the living tissue, a display device, and a screen of the display device are provided. The computer is configured to display a confocal fluorescence image of a biological tissue and also to display the waveform of the bioelectric signal together on a part of the screen.

[0014]

According to the first aspect of the present invention, the waveform of the bioelectric signal is also displayed on a part of the screen for displaying the image of the biological tissue, so that the researcher can visually observe the image of the biological tissue and the waveform of the bioelectric signal at the same time. Act as you can.

The second aspect operates so that a general optical microscope can be used.

The configuration utilizing the confocal laser scanning microscope according to claim 3 functions so that an image in which the fluorescence concentration changes according to the activity situation is displayed.

[0017]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 shows a biological tissue observation apparatus 30 according to a first embodiment of the present invention.

The device 30 is constructed by using a general optical microscope, and is generally an inverted fluorescent microscope 31 which is a kind of optical microscope, a CCDTV camera 32, a multiple measurement computer 33, and a TV. It comprises a monitor 34, an image analysis device 35, a video tape recorder 36, and glass microelectrodes 37.

The microscope 31 has a light source 41 having a visible light source 41a and an ultraviolet light source 41b above the stage 40.
And the condenser lens 42, and the objective lens 43 below the stage 40.

The TV camera 32 captures an enlarged transmitted light image and fluorescent image of the living tissue.

The image analysis device 35 performs processing such as filtering of a captured image, pseudo color processing, shading correction, and difference calculation.

The computer 33 causes the TV monitor 34 to display the image information from the TV camera 32, and
Open a window 45 in the right corner of the screen 44 of the monitor 34,
Here, the waveform of the bioelectric signal extracted by the glass microelectrode 37 is displayed.

The tape of the video tape recorder 36 has a video track and an audio track. Image data from the TV camera 32 is simultaneously recorded on the video track, and electrophysiological data from the electrodes is simultaneously recorded on the audio track.

A preamplifier 46 amplifies a bioelectric signal taken out through the electrode 37.

Reference numeral 47 is a data analysis interface, 4
8 is a PCM processor.

Next, the operation and operation of the device 30 having the above structure will be described with reference to FIG.

The following items (1) to (3) are preparation work.

Sample Set 50 A chamber 61 containing the abdominal ganglion 60 of red earthworm as a biological tissue sample is set on the stage 40.

The abdominal ganglion 60 has been previously treated with 1% protease for 3 minutes to remove the surface striated muscle.

Transmitted light image display of the abdominal ganglion 51 The visible light source 41a is turned on, and the T
An enlarged transmitted light image of the abdominal ganglion 60 is displayed on the V monitor 34.

Open a window 52 Operate the computer 33 to display the screen 4 of the TV monitor 34.
Open a window 45 in the right corner of 4.

Electrode insertion 53 While operating the hydraulic manipulator (not shown) while observing the image on the TV monitor 34, the glass microelectrode 37 filled with the 7% lucifer yellow (fluorescent dye) solution is connected to the abdominal ganglion 60. MGF, one of the giant neurons present in the
62 near the midline part where it seems that there is
Insert into F62.

When the electrode 37 is inserted into the MGF 62,
A potential is induced on the electrode 37, which is applied to the computer 33 via the amplifier 46 and the interface 47, and the potential waveform is displayed in the window 45.

From this, it is confirmed that the electrode 37 has been inserted into the MGF 62.

Fluorescent dye injection 54 The electrode 37 is negatively energized at −5 nA for 10 minutes.
This injects the fluorescent dye into the MGF62.

Fluorescent image display of MGF 55 The visible light source 41a is turned off and the ultraviolet light source 41b is turned on. Thereby, the MGF62 is irradiated with ultraviolet rays,
The fluorescent dye injected into the MGF62 emits light,
The camera 32 captures a magnified fluorescence image of MGF.

The video signal from the TV camera 32 is appropriately processed by the image analysis device 35, processed by the computer 33, and then displayed on the TV monitor 34.

In FIG. 1, 63 is a magnified fluorescence image of MGF.

In the window 45, an MGF electric signal waveform 64 showing the fluctuation of the potential taken out by the electrode 37 from the MGF 62 is displayed.

With the above, preparation for the physiological experiment is completed.

Physiological Experiment 56 Various physiological experiments are conducted.

The researcher looks at the TV monitor 34 and looks at the MGF.
The magnified fluorescence image 63 and the MGF electric signal waveform 64 can be grasped at a glance.

Therefore, the researcher has found that the MGF magnified fluorescent image 63
From this, it is possible to grasp the form of the MGF 62 and the insertion site of the electrode 37. In addition, the MGF bioelectric signal waveform 6
It is possible to grasp the state of the MGF bioelectric signal from 4. This makes it possible to easily understand the relationship between the part of the MGF 62 into which the electrode 37 is inserted and the response state of the MGF 62.

The MGF magnified fluorescent image 63 is recorded on the video track of the tape by the video tape recorder 36, and the MGF bioelectric signal is recorded by the PCM processor 48.
Via the videotape recorder 36,
It is recorded simultaneously on the audio track of the same tape.

The fluorescent microscope 31 described above can be used as a general transmission optical microscope to display the image of the biological tissue and the waveform of the bioelectric signal simultaneously on the TV monitor 34 for observation.

In this case, the above-mentioned steps 1 to 3 are performed. When the work of (3) is completed, the TV monitor 34 displays the magnified transmitted light image of the abdominal ganglion 60 and the waveform of the bioelectric signal of the MGF 62 in the window 45.

FIG. 3 shows a biological tissue observation apparatus 70 according to the second embodiment of the present invention. The device 70 is constructed using a confocal laser scanning microscope 71. 3, those parts which are the same as those corresponding parts in FIG. 1 are designated by the same reference numerals, and a description thereof will be omitted.

The microscope 71 includes a laser light source 72, an objective lens 73 for focusing the laser light from the laser light source 72 on the sample,
It is composed of an XY scanning device 69 for scanning the laser light on the sample, a photomultiplier tube 74 for measuring the intensity of the point image formed by the reflected light from the sample, and the like.

No photo camera, photomultiplier tube 7
The output terminal 4 is connected to the input terminal of the image analysis device 35.

Reference numeral 75 denotes a double barrel glass microelectrode, which has two barrels 75a and 75b and is fixed to a holder (not shown).

One barrel 75a is filled with a 3M KCl solution 76. This solution 76 is used for potential detection and stimulation.

On the other hand, the barrel 75b is filled with a 6 mM solution 77 of the Ca ²⁺ sensitive dye Fluo3.

A microinjector 78 is connected to the barrel 75b. A nitrogen gas source 79 is connected to the microinjector 78.

Reference numeral 80 denotes a stimulator, which produces a pulse-shaped stimulation current.

The configuration other than the above is the same as the configuration of the apparatus 30 of FIG.

Next, the operation and operation of the device 70 will be described.

An example will be given of the case where the calcium imaging and the change in the membrane potential are simultaneously measured for the MGF of the abdominal ganglion of the red earthworm.

Sample set 50 The same procedure as described above is performed.

Display of transmitted light image of abdominal ganglion 90 The microscope 71 is operated to open a window displaying the magnified transmitted light image of the abdominal ganglion 60 on the TV monitor 34. 91 The computer 33 is operated, Screen 4 of TV monitor 34
Open a window 45 in the right corner of 4.

Electrode Insertion 92 When a hydraulic manipulator (not shown) is operated while observing the image on the TV monitor 34, it is assumed that the electrode 75 has MGF62 which is one of giant neurons existing in the abdominal ganglion 60. It approaches the vicinity of the supposed midline and is inserted into MGF62.

When the electrode 75 is inserted into the MGF 62, a potential is induced in the electrode 75, which is applied to the computer 33 via the amplifier 46 and the interface 47,
The potential waveform is displayed in the window 45.

From this, the researcher found that the electrode 75 was MG.
Confirm that you have inserted into F62.

Ca ⁺² Sensitive Dye Injection 93 Nitrogen gas source 79 applies nitrogen gas pressure to microinjector 78, and a 6 mM solution 77 of Ca ²⁺ sensitive dye Fluo3, which is a kind of fluorescent dye, is injected into MGF62.

Confocal fluorescence image display of MGF 94 After waiting for the solution 77 to spread sufficiently over the entire MGF62, the confocal fluorescence image 100 of MGF62 is captured,
This is displayed on the TV monitor 34.

With the above, preparation for the physiological experiment is completed.

Physiological Experiment 95 For example, the stimulator 80 is operated, a stimulation current is applied to the MGF 62 by the electrode 75, and positive energization stimulation is performed on the MGF 62.

As a result, the window 4 of the monitor TV 34
In FIG. 5, the waveform 101 of the stimulation current is displayed along with the MGF electrical signal waveform 102.

On the screen 44 of the monitor TV 34, M
MGF whose brightness changes depending on the activity of GF62
62 confocal fluorescence images 100 are displayed.

As a result, the researcher can observe both the state of stimulation by the electric current to the MGF 62 and the state of the activity of the MGF 62 by observing only the monitor TV 34.

As a result, current stimulation to MGF62 and MG
It is possible to easily understand the relationship with the activity status of F62.

As a result of the experiment, an action potential is generated in association with the depolarization of the membrane when positive electric stimulation is carried out, and at the same time, a wave due to a change in calcium concentration runs in the axon from the stimulation site toward the peripheral side. Observed on the screen.

The MGF confocal image 100 which is the data during the physiological experiment is supplied to the video tape recorder 36, and the MGF bioelectric signal is also supplied to the video tape recorder 36 via the PCM processor 48. The MGF confocal image 10 by the video tape recorder 36.
0 is recorded on the video track of the tape, and the MGF bioelectric signal is recorded on the audio track of the same tape at the same time.

The present invention is not limited to the above embodiment, and other types of microscopes such as a differential interference microscope, a polarization microscope, a stereoscopic microscope and a phase contrast microscope can be used as the microscope.

[0074]

As described above, according to the first aspect of the invention, the image of the living tissue and the waveform of the bioelectric signal can be observed at a glance by seeing the same screen, and the two are different. It is possible to more easily understand the relationship between the activity status of the living tissue and the change in the bioelectric signal, as compared with the case where it is displayed on the screen.

According to the second aspect of the invention, a general optical microscope can be used as the microscope.

According to the third aspect of the invention, it is possible to easily grasp the relationship between the change in fluorescence intensity indicating the activity state of the living tissue and the bioelectric signal.

[Brief description of drawings]

FIG. 1 is a diagram showing a biological tissue display device according to a first embodiment of the present invention.

2 is a flow chart of operation and operation of the apparatus of FIG.

FIG. 3 is a diagram showing a biological tissue display device according to a second embodiment of the present invention.

4 is a flow chart of operation and operation of the apparatus of FIG.

FIG. 5 is a diagram showing an example of a conventional biological tissue display device.

[Explanation of symbols]

30, 70 Biological tissue display device 31 Inverted fluorescence microscope 32 TV camera 33 Multiple measurement computer 34 TV monitor 35 Image analysis device 36 Video tape recorder 37 Glass microelectrode 40 Stage 41 Light source 41a Visible light source 41b Ultraviolet light source 43 Objective lens 44 Screen 45 Window 46 Preamplifier 47 Interface for data analysis 48 PCM processor 60 Abdominal nerve abdominal nerve part (living tissue sample) 61 Chamber 62 MGF 63 MGF magnified fluorescence image 64 MGF electrical signal waveform 69 XY scanning device 71 Confocal 6mM soluble laser scanning microscope 72 laser light source 73 objective lens 74 photomultiplier 75 double barrel glass microelectrode 75a, the 75b barrel 76 3M KCL solution 77 Ca ²⁺ sensitive dye Fluo3 78 confocal microinjector 79 nitrogen gas source 80 stimulator 100 MGF fluorescence image 101 stimulation current waveform 102 MGF electrical signal waveform

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI technical display location G01N 33/483 E

Claims (3)

[Claims] 1. An image (63, 100) of a biological tissue obtained from a microscope (31, 71) is displayed on a screen (44) of a display device (34) and a part (45) of the screen of the display device is displayed. ), The waveform (64) of the bioelectric signal detected from the biological tissue displayed on the display device is also displayed together with the display device. 2. An optical microscope (3) for obtaining a magnified image of biological tissue.
1), a television camera (32) for picking up an image obtained by the microscope, and an electrode (37) for taking out a bioelectric signal of the living tissue.
A display device (34), and a computer (33) for displaying a magnified image of biological tissue on the screen of the display device and also displaying the waveform of the bioelectrical signal on a part of the screen. A biological tissue display device having the following configuration. 3. A confocal laser scanning microscope (71) for obtaining a confocal fluorescence image of biological tissue, an electrode (75) for extracting a bioelectric signal of the biological tissue, a display device (34), and the display device. On the screen, a confocal fluorescence image of the biological tissue is displayed, and a computer (33) is also configured to display the waveform of the bioelectric signal together on a part of the screen. Organization display device.