JPS6314617B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an endoscopic laser diagnostic device that performs diagnosis by transendoscopically irradiating a body cavity of a living body into which a fluorescent substance has been administered with a low-power laser beam.

A diagnostic method is known in which a fluorescent substance is administered to a living body and fluorescence emitted from a diseased tissue, such as a cancer tissue, is observed. In this diagnosis, a light source device that combines a white light source and a filter to generate light of a certain wavelength, or an ultraviolet generator device that uses carbon electrodes, is used as a fluorescence excitation light source device, and the light from this light source device is used as a fluorescence excitation light source device. The system irradiates the tissue and causes the diseased tissue to emit fluorescence. Conventionally, this diagnosis involves observing the area that generates fluorescence with the naked eye, or recording it on a television, camera, or photograph as necessary. Even the physical characteristics of fluorescence were not useful for diagnosis, and the diagnosis was simple.

The present invention has been made in view of the above-mentioned circumstances, and its purpose is to provide an endoscope laser diagnostic device that can obtain more detailed information regarding diseased tissues.

The present invention will be described below based on an embodiment shown in the drawings. Reference numeral 1 in FIG. 1 denotes a low-power krypton laser generator for fluorescence excitation, to which a laser probe 2 for guiding laser light and a jacket tube 3 for signal transmission are connected. Reference numeral 4 denotes an endoscope, which includes an operating section 5 and an insertion section 6. The operating section 5 is provided with an eyepiece section 7 and a forceps port 8. The insertion section 6 of the endoscope 4 is inserted into the large cavity of the living body 9, and the laser probe 2 is inserted through the forceps port 8, and the insertion passage 10 such as a forceps channel in the insertion section 6 (see Fig. 2). (see) and protrudes from the tip portion 11 through the tip. The laser probe 2 is opposed to a diseased tissue, such as a cancerous tissue 12, that has occurred in the body cavity of a living body 9.

To explain the endoscope 4, as shown in FIG. 2 and FIG. The image and fluorescence of the cancerous tissue 12, which is the object to be examined, are transmitted to the operating section 5. This operation section 5 is provided with a first lens 15 facing the image guide 14 and a second lens 16 facing the eyepiece 7, and between these first and second lenses 15 and 16. A prism 17 is provided. The first lens 15 transmits the image of the cancerous tissue 12 and the fluorescence that have passed through the image guide 14 to the prism 17, and the second lens
The lens 16 passes the cancer tissue 12 and fluorescence transmitted from the prism 17 to the observer 1 through a filter 18.
The prism 17 is configured to divide the fluorescence of the cancer tissue 12 that has passed through the first lens 15 into two directions: toward the eyepiece 7 and toward a detection section 20, which will be described later.

To explain the detection section 20 in detail, reference numeral 21 denotes a through hole protruding from the side wall of the operation section 5. As shown in FIG. A lens holder 23 is provided with a third lens 22 that faces the reflective surface of the prism 17 in this through hole 21.
is fixed. This lens holder 23 is provided with a threaded portion 24, and a base 26 having a sensor mount 25 is removably screwed onto this threaded portion 24. The sensor mount 25 includes a light wavelength detector such as a semiconductor color sensor 27 that detects the wavelength of fluorescence from the cancer tissue 12 and a light intensity detector such as a phototransistor that detects the intensity (light energy) of the fluorescence from the cancer tissue 12. 28 are arranged in parallel. The semiconductor color sensor 27 and the phototransistor 28 are connected to the signal processing device 31 built in the laser generator 1 (see FIG. )It is connected to the. That is, in this signal processing device ₃₁ , as shown in FIG. ₁ and a reference signal. As shown in the figure, this comparator 33 includes a comparator 34 whose one input terminal is connected to the phototransistor 28, and a reference signal generator 35 which is connected to the other input terminal of this comparator 34 and generates a reference signal. It consists of
The output end of the comparator 34 is connected to a CPU 36 that processes the output signal and obtains a diagnostic result.
is also connected to the reference signal generator 35 for indicating the level of the reference signal generated by the reference signal generator 35. Similarly, the semiconductor color sensor 27 is connected via a signal converter 37 to a monitoring device 38 and a comparison device 39. This comparison device 39 is similar to the comparison device 33 described above.
A reference signal generator 40 connected to the CPU 36, this reference signal generator 40, and the semiconductor color sensor 27 are connected to the input end, and the output end thereof is connected to the input end.
It consists of a comparator 41 connected to the CPU 36. For example, when the semiconductor color sensor 27 is composed of a pair of photodiodes 42 and 43 having different spectral characteristics as shown in FIG. 5, the anodes of the pair of photodiodes 42 and 43 are grounded, respectively. Its cathode is grounded to logarithmic compressors 44 and 45 of the signal converter 37, respectively, which logarithmically compress the input signal. This logarithmic compressor 4
4 and 45 are connected to the input side of a subtracter 46 that subtracts the logarithmically compressed signal to generate an output voltage signal having an output voltage characteristic linear with respect to the incident wavelength. Further, the CPU 36 is connected to a display device 47 for displaying diagnosis results and a recording device 48 for recording diagnosis results as peripheral devices.

Since the endoscope laser diagnostic apparatus of the present invention is configured as described above, it is used for diagnosis as follows. That is, the insertion section 6 of the endoscope 4 is inserted into the body cavity of a living body 9 into which a fluorescent agent, for example, hematoporphyrin, has been administered, the laser probe 2 is inserted through the forceps port 8, and the laser probe 2 is inserted through the forceps channel 10. Insert the side end of the laser probe 2 into the endoscope 4.
It protrudes from the tip 11 of. Thereafter, the laser generator 1 is started to oscillate krypton laser light, which is introduced into the body cavity via the laser guide of the laser probe 2. When the tissue in the body cavity is irradiated with laser light, if cancer tissue 12 is present, fluorescence is emitted from this tissue portion. As is clear, the cancer tissue 12 emitting this fluorescence is clearly visible from the objective lens system 1.
3. Image guide 14 and first lens 15
It reaches the prism 17 via. The prism 17 detects the fluorescence in the direction of the observer 19 and the detection unit 20.
The fluorescence traveling in the direction of the detection unit 20 passes through the third lens 22 and reaches the semiconductor color sensor 27 and phototransistor 28, where the fluorescence wavelength and fluorescence intensity are detected. The fluorescence intensity signal detected by the phototransistor 28 is monitored by a monitor device 32 and sent to a comparator 33, where it is compared with a reference signal generated by a reference signal generator 35 in accordance with instructions from a CPU 36. The comparison result is sent from the comparator 34.
It is supplied to the CPU 36. Semiconductor color sensor 2
The fluorescence wavelength signal detected at 7 is sent to a signal converter 37
That is, the logarithmic compressor 4
The signals are logarithmically compressed in steps 4 and 45, subjected to subtraction processing in a subtracter 46, and converted into a voltage signal exhibiting linear characteristics with respect to wavelength. This signal is similarly monitored by the monitor device 38 and compared with a reference signal by the comparator 39, and then supplied to the CPU 36. The comparison results of optical intensity signals and wavelength signals are
Processed by the CPU 36, and the processing results, for example, whether the tissue is normal tissue or abnormal tissue, the state of the diseased tissue, etc. are displayed on the display device 47 as diagnostic parameters for the diseased tissue, and recorded in the recording device 48. .

In the above embodiment, the detection section 20 including the semiconductor color sensor 27 and the phototransistor 28 was attached to the operation section 5 of the endoscope 4, but the present invention is not limited to the above embodiment. It may be configured as shown in the figure. That is, reference numeral 49 denotes a sensor unit attachment part provided on the eyepiece 7 of the endoscope 4, and a sensor unit 50 is removably screwed into this sensor unit attachment part 49. This sensor unit 50 includes a prism 51 and a lens 52.
and a filter 53, a lens barrel section 55 forming an eyepiece section 54, and a detection section 56 provided on a side wall of this lens barrel section 55. This detection section 56
A connecting portion 59 is provided integrally with the lens barrel portion 55, which houses a lens 57 facing the reflective surface of the prism 51 and a sensor mount 58, and the sensor mount 58 has a light wavelength A detector such as a semiconductor color sensor 27 and a light intensity detector such as a phototransistor 28 are provided, and the same components are given the same numbers and the description thereof will be omitted.

The sensor unit 50 configured in this way is removable from the sensor unit mounting part 49 provided in the eyepiece part 7, and can be used as a normal endoscope without manufacturing a special endoscope for fluorescence observation. It can be used by attaching it to the eyepiece.

In addition, the present invention uses a low-power argon laser for fluorescence excitation, and acridine orange may be used as a fluorescent agent, and a light wavelength detector and a light intensity detector for detecting the wavelength and intensity of fluorescence are: The present invention is not limited to semiconductor color sensors and phototransistors.

In an experimental example of diagnosis using the above-mentioned diagnostic device, the following data were obtained. When hematoporphyrin collected from blood was used as a fluorescent agent and a krypton laser was used as an excitation light source, fluorescence with a peak wavelength of 630 nm was obtained from cancer tissue. In this diagnostic experiment, hematoporphyrin was administered by intravenous injection, and the krypton laser power was 40 mW. In addition, an experiment was conducted using a 0.05% acridine orange aqueous solution as a fluorescent agent, spraying it on the area to be observed, and using an argon laser as the excitation light source. Fluorescence having a peak in the wavelength range of 4650 to 7500 Å was obtained from cancer tissue, and particularly strong fluorescence was obtained in areas where cancer tissue was concentrated.

Note that the semiconductor color sensor mentioned above currently has
There are some that can provide output voltages corresponding to wavelengths from blue to infrared, and a linear output voltage of -0.5 to 0.5V can be obtained between wavelengths λ = 4000 to 10000 Å.
Such a color sensor is not affected by the intensity of light and does not require an optical filter. Furthermore, the phototransistor mentioned above is a photodetector element that measures the intensity of light, and it can obtain an output current that is linear with respect to the light energy (mW/cm ² ), and has a sensitivity peak at the wavelength to be detected. Things can be manufactured.

As explained above, this invention not only allows the observation of fluorescence generated from diseased tissue, but also measures the light wavelength and light intensity, which can be used as diagnostic parameters. In addition to early detection, it is possible to accurately know the degree of progression of diseased tissues, and the reliability of diagnosis can be improved.

Furthermore, by providing a light wavelength and light intensity detector in the operating section, the area of the light receiving section can be increased.
The output current and output voltage of both the detectors are increased, the S/N ratio is improved, and the risk of noise trouble in the signal processing device is reduced. Furthermore, an optical wavelength detector that detects wavelength can be used in a portion of the detector characteristic curve with excellent linearity, and has various effects such as improving the reliability of signal processing.

[Brief explanation of the drawing]

Fig. 1 is a schematic configuration diagram of an endoscope laser diagnostic device showing an embodiment of the present invention, Fig. 2 is a sectional view showing the distal end of the endoscope, and Fig. 3 is a sectional view of the endoscope. 4 is a circuit diagram of the signal processing device, FIG. 5 is a circuit diagram of the signal converter, and FIG. 6 is an eyepiece of an endoscope showing another embodiment of the present invention. FIG. DESCRIPTION OF SYMBOLS 1... Laser generator, 2... Laser probe, 4... Endoscope, 5... Operating unit, 7... Eyepiece, 10... Insertion path, 27... Semiconductor color sensor (light wavelength detector) ), 28... phototransistor (light intensity detector), 31... signal processing device.

Claims (1)

[Claims] 1. A laser generator that oscillates a laser beam that excites fluorescence in diseased tissue to which a fluorescent substance has been applied, a laser probe that guides the laser beam generated by the laser generator, and a laser probe that guides the laser beam generated by the laser generator. An endoscope that has an insertion path that can be inserted up to its tip, an optical wavelength detector that is installed in the operation part of this endoscope and that detects the wavelength of fluorescence emitted from the test area, and an optical wavelength detector that detects the intensity of the fluorescence. A laser diagnostic device for an endoscope, characterized in that it is equipped with a light intensity detector, and a signal processing device that processes the light wavelength signal and the light intensity signal supplied from these detectors and supplies diagnostic information. . 2. A laser diagnostic device for an endoscope according to claim 1, characterized in that a signal processing device is provided within a laser generator. 3. A laser diagnostic device for an endoscope according to claim 1, characterized in that a light wavelength detector and a light intensity detector are provided in an eyepiece section of the endoscope. 4. Claim 1, wherein the laser oscillator is a low-power krypton laser oscillator.
The endoscope laser diagnostic device described in . 5. The laser diagnostic device for an endoscope according to claim 1, wherein the laser oscillator is a low-power argon laser oscillator. 6. The endoscope laser diagnostic device according to claim 1, wherein the optical wavelength detector is a semiconductor color sensor. 7. The endoscope laser diagnostic device according to claim 1, wherein the light intensity detector is a phototransistor.