JP2808000B2 - Ophthalmic equipment - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fundus camera capable of performing visible fluorescent imaging and infrared fluorescent imaging of a fundus of a subject's eye.

(Prior Art) Generally, when performing fluorescence imaging using this type of fundus camera, first, a fluorescent agent is injected into a vein of a subject (hereinafter simply referred to as intravenous injection). Several minutes after the intravenous injection, the fluorescent agent starts to reach the retinal blood vessels in the fundus of the subject. For example, in the case of a fluorescent agent for infrared fluorescence, that is, ICG (indocyanine green), the curve is as shown by curve A in FIG.
In FIG. 2, the amount (concentration) of the fluorescent agent reaching the fundus blood vessels reaches its maximum when about one minute has passed, and thereafter tends to decrease gradually.

On the other hand, on the fundus camera side, a fluorescence excitation filter, that is, an exciter filter, is provided in the illumination optical system in the imaging illumination optical system, and the imaging illumination light source is caused to emit light in anticipation of the time when the fluorescent agent reaches the retinal blood vessels. Let it start.

As a result, of the light from the imaging illumination light source, only light having a wavelength that can be excited by fluorescence passes through the exciter filter and is projected on the fundus of the eye to be examined. The fluorescence excitation wavelength is absorbed by the fluorescent agent that has reached the blood vessels of the fundus, and excites the fluorescent agent. Fluorescence is emitted from the fluorescent agent by this excitation, and the amount of fluorescence at this time is proportional to the amount of the fluorescent agent. Then, the fluorescence from the fundus blood vessels is guided to the film surface via the photographing optical system.

(Problems to be Solved by the Invention) Meanwhile, the fluorescent agent injected intravenously into the subject first reaches the thick blood vessels of the fundus by blood circulation, and gradually penetrates into the thin blood vessels with the passage of time. Will go. For this reason, the concentration of the fluorescent agent existing in the blood vessel in the early stage of the fluorescent imaging due to the blood circulation performed during this time is much higher than the concentration of the fluorescent agent present in the blood vessel in the latter half of the fluorescent imaging. In other words, the amount (concentration) of the fluorescent agent reaching the fundus blood vessels after intravenous injection of the fluorescent agent reaches a maximum after several minutes as shown in FIG. 2, and thereafter tends to gradually decrease. is there.

As described above, in the initial stage of the fluorescent imaging in which the concentration of the tendency agent in the blood vessel with a large fundus is locally higher than the other parts, the brightness of the tendency is high as shown by the part a of the curve B in FIG. For this reason, when imaging is performed with a predetermined constant light amount, halation is likely to occur at the beginning of fluorescent imaging. This point is the same when a visible fluorescent agent is used, as shown by the curve B 'in FIG.

Further, as the fluorescent agent penetrates into the thin blood vessels, the locally high concentration of the fluorescent agent gradually decreases, and the amount of fluorescence gradually decreases as shown in FIG. 3 or FIG. For this reason, the contrast gradually decreases in the middle stage of the fluorescent imaging and the latter stage of the fluorescent imaging, so that it is impossible to perform imaging with an appropriate amount of light.

On the other hand, in such a conventional ophthalmologic apparatus such as a fundus camera, when performing a large number of fluorescent imagings at intervals, it is difficult to fix the position of the head or the position of the eyeball of the subject. is there. Because of this, the focus position and shooting position are shifted,
Prior to each photographing, focusing and positioning with observation illumination light are performed. At the time of such focusing and positioning, the amount of photographing light is adjusted so that an appropriate contrast for photographing can be obtained.

However, since the adjustment of the amount of photographing light is performed separately from the focusing and positioning before the start of each photographing, there is a problem that it takes time and effort.

Therefore, the present invention focuses on adjusting the light amount of the observation illumination light when performing focusing or positioning with the observation illumination light before photographing, and automatically adjusts the photographing light amount in conjunction with the light amount adjustment. An object of the present invention is to provide an ophthalmologic apparatus that can easily adjust the amount of photographing light to an appropriate exposure amount regardless of the decrease even if the amount of fluorescent light decreases with time after the start of fluorescent photographing. It is.

(Means for Solving the Problems) Under this object, the present invention is directed to an observation light amount adjusting means for adjusting an observation light amount of an observation light source, and an increase / decrease adjustment of the observation light amount by the observation light amount adjustment means. An ophthalmologic apparatus having a photographing light amount adjusting means for increasing and decreasing the photographing light amount of the photographing light source.

(Operation) According to such a configuration, when the observation light amount of the observation light source is increased or decreased by the observation light amount adjustment unit, the imaging light amount of the imaging light source is increased or decreased in cooperation with the observation light amount adjustment unit.

Therefore, when the amount of observation light by the observation light source is adjusted so that the contrast of the observation unit by the observation light is appropriate,
If the increase / decrease ratio between the observation light amount and the photographing light amount is set in advance so that the photographing light amount by the photographing light source becomes appropriate, for example, even when the fluorescence amount from the fundus blood vessel or the like is large at the beginning of the fundus fluorescent photographing, the fluorescent photographing By adjusting the amount of observation light so that the contrast of the fundus becomes appropriate, the amount of light from the imaging light source at the beginning of fluorescent imaging is adjusted in conjunction with this adjustment. Even if the amount of fluorescent light from the camera becomes large, the occurrence of halation or the like during fluorescent imaging is prevented beforehand, and appropriate imaging is performed. In addition, even if the amount of fluorescence from the fundus blood vessels gradually decreases with the lapse of time after the start of fluorescence imaging, the amount of observation light is increased and adjusted so that the contrast of the fundus becomes appropriate. Since the initial amount of light from the imaging light source is adjusted so as to be appropriate, appropriate imaging can be performed even if the amount of fluorescence from the fundus blood vessels decreases.

Hereinafter, the present invention will be described with reference to the drawings.

In FIG. 1, an illumination system and an observation imaging system are provided in a main body (not shown) of the fundus camera. This illumination system has an observation illumination optical system and a photographing illumination optical system, and the observation photographing system has a photographing optical system, an observation optical system, and a monitor system.

The observation illumination optical system includes an observation illumination light source 1, lenses 2, 3, a ring slit 4, a lens 5, a reflection mirror 6, a transparent black spot plate 7 having a black spot at the center, a relay lens 8, a perforated mirror 9, an objective It has an optical member such as a lens 10. And the observation illumination light source 1
Illumination light from the lens 2, 3, ring slit 4, lens 5,
Reflecting mirror 6, black spot plate 7, a relay lens 8, holed mirror 9, it is projected onto the fundus E _f of the eye E via the objective lens 10.

The photographing illumination optical system includes a photographing illumination light source 11 such as a xenon lamp disposed between the lenses 2 and 3, and optical members from the lens 3 to the objective lens 10 used in the observation illumination optical system. The imaging illumination light from photographing illumination light source 11 is projected onto the fundus E _f through optical members from the lens 3 to the objective lens 10.

An exciter filter 12 is provided between the lens 3 and the ring slit 4 of such an illumination system so as to be freely inserted and removed. Either a filter for exciting visible fluorescence or a filter for exciting infrared fluorescence is used as the exciter filter 12, but either of them may be selectively used.

The photographing optical system has optical members such as an objective lens 10, a perforated mirror 9, an aperture stop 13, and a relay lens 14. And
Reflected light or fluorescence from the fundus E _f is the objective lens 10, perforated mirror 9, an aperture stop 13 is guided to the film plane 15 through the relay lens 14 and the like.

The observation optical system includes an optical member from the objective lens 10 to the relay lens 14, and a quick return mirror 16, a field lens 17, a reflection mirror 18, and an eyepiece that are detachably provided between the relay lens 14 and the film surface 15. An optical member such as a lens 19 is provided. For observation, the quick return mirror 16 is disposed between the relay lens 14 and the film surface 15. Thus, reflected light or fluorescence from the fundus E _f, the optical member from the objective lens 10 to the relay lens 14, a quick return mirror 16, a field lens 17, reflecting mirror 18, and examinee's eye 20 through the eyepiece 19 Will be guided to.

Further, a barrier filter 21 is provided between the aperture stop 13 and the relay lens 14 of the observation / photographing system so as to be freely inserted and removed. Either a visible fluorescent filter or an infrared fluorescent filter is used as the barrier filter 21, but both can be selectively used. In addition,
At the time of fluorescence imaging, when a filter for excitation of visible fluorescence is used as the exciter filter 12, a filter for visible fluorescence is used for the barrier filter 21, and when a filter for excitation of infrared fluorescence is used for the exciter filter 12, the barrier filter 21 is used. Use a filter for infrared fluorescence.

The monitor system includes an optical member from the objective lens 10 to the lens 14, a quick return mirror 22 provided in the optical path between the lens 14 and the quick return mirror 16, and a lens 23, a reflection mirror 24, and a lens. 25, TV camera 26
And a monitor TV27. Then, at the time of monitoring, the quick return mirror 22 is inserted on the optical path between the lens 14 and the quick return mirror 16. This allows
The light from the fundus that has been guided to the lens 14 enters the TV camera 26 via the quick return mirror 22, the lens 23, the reflection mirror 24, and the lens 25. The fundus image by this incident light is TV
The image is displayed on the monitor TV 27 by the camera 26.

The above-described photographing illumination light source 10 is operated by a light emission amount control circuit 28.

The light emission amount control circuit 28 includes an observation light amount adjustment unit 29 such as a variable resistor for adjusting the light amount of the observation illumination light source 1, and detects a change in the illumination light amount of the observation light amount adjustment unit 29 and outputs a signal corresponding to the change. Is provided. The light emission amount control circuit 28 includes a photographing light amount adjusting circuit 31 (a photographing light amount adjusting unit) for setting a photographing light amount of a photographing light source in accordance with an output signal of the light amount change detecting device 30;
There is provided a light emitting device 32 for controlling the light emission amount of the photographing light source 10 according to the photographing light amount control signal output from 31.

The photographing light amount adjusting circuit 31 is set so as to increase and decrease the photographing light amount at a predetermined ratio in accordance with the increase and decrease of the light amount of the observation illumination light source 1. The increase / decrease ratio of the light amount differs between visible fluorescence imaging and infrared fluorescence imaging, but is actually set based on experimental data.

Next, the photographing light amount adjusting operation of the ophthalmologic apparatus having such a configuration will be described.

In such an ophthalmologic apparatus such as a fundus camera, when many fluorescent images are taken at intervals of several seconds, several minutes, or several tens of minutes after intravenously injecting a fluorescent agent into a subject, the subject's head It is difficult to fix the position of the eyeball or the position of the eyeball. For this reason, since the focal position and the photographing position are shifted, it is necessary to perform focusing and position adjustment with observation illumination light before each photographing.

On the other hand, at the time of such fluorescence imaging, if the amount of illumination light is constant, the amount of fluorescence from the fundus blood vessels decreases with time.

Therefore, before focusing or positioning by the observation illumination light before each fluorescence imaging, the observation light amount adjusting means 29 adjusts the light amount of the observation light source 1. That is, the light amount of the observation light source 1 is increased by the observation light amount adjusting means 29 for each photographing after the start of the fluorescence photographing so that the contrast at the time of observation becomes appropriate.

Then, when the observation light amount is increased by the observation light amount adjusting means 29 for each photographing after the start of the fluorescent photographing, the light amount change detection device 30 outputs a detection signal corresponding to the increase in the observation light amount. This detection signal is input to the photographing light amount adjustment circuit 31. Thus, the photographing light amount adjusting circuit 31
A light amount control signal for obtaining an appropriate photographing contrast from a fundus blood vessel at the time of photographing by 10 is output, and this light amount control signal is input to the light emitting device 32. With this input, the light emitting device 32 is turned on by a photographing switch (release switch) (not shown).
, And causes the imaging light source 10 to emit light based on the light intensity control signal from the imaging light intensity adjustment circuit 31. When the light amount of the observation light source is increased or decreased by the observation light amount adjusting means 29 in this manner, the photographing light amount of the photographing illumination light source 10 is changed to the observation light amount adjusting means.
Automatically increase or decrease in conjunction with 29.

(Effects of the Invention) As described above, the present invention provides an observation light amount adjusting unit that adjusts an observation light amount of an observation light source, and a photographing light amount of a photographing light source linked to the increase / decrease of the observation light amount by the observation light amount adjustment unit. The amount of fluorescent light from the fundus blood vessels decreases over time during fluorescence imaging of the fundus, so that the amount of captured light can be easily adjusted to the appropriate exposure regardless of this decrease. Can be adjusted. That is, when the observation light amount by the observation light source is adjusted so that the contrast of the observation unit with the observation light is appropriate, the increase / decrease ratio between the observation light amount and the imaging light amount is set in advance so that the imaging light amount by the imaging light source is appropriate. If, for example, even when the amount of fluorescence from the fundus blood vessels and the like in the early stage of fluorescence imaging of the fundus is large, by adjusting the amount of observation so that the contrast of the fundus becomes appropriate in the early stage of fluorescence imaging, in conjunction with this adjustment Since the photographing light amount of the photographing light source at the beginning of the fluorescent photographing is adjusted to be appropriate, even if the amount of fluorescent light from the fundus blood vessels increases at the initial stage of the fluorescent photographing, the occurrence of halation or the like during the fluorescent photographing is prevented beforehand. , Appropriate photographing is performed. Moreover,
By setting in this way, even if the amount of fluorescence from the fundus blood vessels gradually decreases over time after the start of fluorescence imaging,
By increasing and adjusting the amount of observation light so that the contrast of the fundus becomes appropriate, the increase in the amount of light from the imaging light source in the initial stage of fluorescence imaging is adjusted in conjunction with this adjustment. Even if the amount is reduced, proper photographing will be performed.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram showing a relationship between an optical system and a control circuit of a fundus camera according to the present invention. FIG. 2 is an ICG circulation characteristic curve diagram showing the relationship between the amount of ICG in the ocular fundus of the eye and time when an ICG (infrared fluorescent agent) is intravenously injected into the subject. FIG. 3 is an explanatory diagram showing an example of infrared light intensity characteristics when an ICG (infrared fluorescent agent) is intravenously injected into a subject and a certain amount of excitation light is projected onto the fundus. FIG. 4 is an explanatory diagram showing an example of a light amount characteristic of visible fluorescence when a visible fluorescent agent is intravenously injected into a subject and a certain amount of excitation light is projected on the fundus. 1 Observation illumination light source 10 Photography illumination light source 15 Film surface (photographing means) 28 Light emission amount control circuit 29 Observation light amount adjustment means 30 Light amount change detection device 31 Photographing light amount adjustment circuit 32 ...... Light-emitting device

Claims (1)

(57) [Claims] 1. An observation light amount adjusting means for adjusting an observation light amount of an observation light source, and a photographing light amount adjusting means for increasing and decreasing a photographing light amount of a photographing light source in conjunction with an increase / decrease adjustment of the observation light amount by the observation light amount adjustment means. An ophthalmologic apparatus comprising: