DE4114646A1 - OPHTHALMOSCOPY ATTACHMENT FOR SURGICAL MICROSCOPE - Google Patents

Description

The invention relates to an ophthalmoscopy attachment for a Surgical microscope according to the preamble of claim 1.

Around the fundus or near the fundus vitreous body areas of a Being able to view the human eye microscopically becomes an intermediate image of the viewer with an ophthalmoscopic lens teten part of the eye generated with a surgical microscope is looked at. This image viewed in this way is height and reversed and pseudo-stereoscopic, d. H. in the depths perception is reversed in front and behind. To microsurgery but to be able to work is an erect, stereoscopically correct image required. At the same time with the necessary image erection must therefore be carried out in the operation microscope an interchange of the two observation beams courses (exchange of pupils) are carried out in order to use the stereo scopic consideration the otherwise occurring Avoid pseudo-stereo effect.

Image erection and pupil reversal can be achieved by a Prism system take place, the additional between Binocular tubes and magnification changer of the surgical microscope is arranged. Such a prism system is an example as described in DE-OS 35 07 458. Through this additional module increases the working distance between the patient's eye and the observer's pupil. From ergono mix and practical-medical reasons is one of the however, such a change in the working distance is undesirable. Furthermore, such a prism system is in particular then a costly solution if a co-observer is on a second binocular tube should work. For this would be then a corresponding second prism system of this type necessary.

Another possible solution is in DE-OS 35 39 009 and proposed in DE utility model G 89 02 035.9. here are the ophthalmic in an attachment to the surgical microscope moscopy lens and a system for image reversal of the generated Housed intermediate image. A corresponding Prism system directly in front of the main lens of the Opera tion microscope arranged. Focusing on the interes sizing eye segment is here in each case on the actual Surgical microscope made, which has a two-part main objectively, in which one lens group against the other is movable. When changing this attachment therefore each time you have to change settings on the Opera tion microscope can be done during an opera tion is very cumbersome. Another disadvantage of the arrangement tion of an erecting system immediately in front of the main lens consists in the fact that at this point it is still partially overlapping, divergent beam paths through two separate Reversal systems are completely spatially separated. It will some of these two beam paths are masked out, d. H. it image errors result in the surgical microscope (vignettia rungs). Such an arrangement is disadvantageous Furthermore, that from the two-part main lens of the ver used a surgical microscope with a larger overall length of the system results in what the demand for a poss the surgeon's largest field of work.

The object of the present invention is therefore to provide a Ophthalmoscopy attachment for a surgical microscope too create an erection of an ophthalmic image Moskopierlinse generated intermediate image causes the Observation beam paths swapped and one optional Use of the surgical microscope in a conventional manner and Way or as an ophthalmoscope, without having to go to the surgery microscope having to make changes. The Ophthalmoscopy attachment an image-free viewing of the Ensure intermediate image through the surgical microscope. Furthermore, with the help of this resolution, the stereosco pical observation be possible for a co-observer, only one additional binocular tube is required.

This problem is solved by an ophthalmoscope attachment with the characteristics of claim 1.

In the ophthalmoscopy attachment according to the invention is located an optical system, which the desired image erection of the intermediate image provided by an ophthalmoscope lens or an ophthalmoscopy lens in a first Intermediate image plane is generated. Furthermore, this causes optical system interchanging the observation beams courses (interchangeability of pupils). The image erection and Pupil swapping takes place here immediately after the first Intermediate image plane where the stereoscopic Observation beam paths are not yet completely separated, but are still intertwined. The upright and laterally correct image can then with the conventional Surgical microscope can be viewed correctly stereoscopically, without additional interventions on this surgical microscope are necessary. There is also a in the header Focusing lens between the respective optical system and the objective-side end of the intent. The focusing lens can be moved along the optical axis. With this Lens takes place focusing on the interesting Eye segment. This will focus on the fiction made according to intent, without taking part in the actual operation microscope to have to change something. The rapid change of View through the surgical microscope or through is the surgical microscope with the ophthalmoscopy attachment thus possible for the user without time-consuming after-sales focussing each time you change your perspective on To have to make a surgical microscope. Through a suitable Swivel device for the attachment according to the invention can this quick change of perspective reali be sated. The working distance between the patient's eye and The observer pupil remains even when the intent according to the invention constant. So this is before Set variable for every conventional surgical microscope use. When other employees are also observing consequently only one such attachment is necessary. the In this case, the employees will consider it through additional binocular tubes and the common head lens. The image erection and pupil reversal will be either by an optical arrangement consisting of two Field lenses and a triplet, or by a Straight vision erecting prism caused in the invention Intent are arranged accordingly.

Two embodiments of the invention are explained in more detail with reference to FIGS. 1-4 of the accompanying drawings.

It shows

Fig. 1, a surgical microscope with the inventive ophthalmic ancillary, wherein the optical system for image inversion and Pupillenvertauschung is designed as a lens array,

FIG. 2 shows the ophthalmoscopy attachment according to the invention from FIG. 1 with the corresponding lens arrangement,

Fig. 3 shows a section of the lens array of FIG. 2 with the corresponding names of the lens radii, lens thickness and lens spacing,

Fig. 4 shows the ophthalmic ancillary according to the invention containing a geradsichtiges erecting prism for image inversion and Pupillenvertauschung.

In Fig. 1, a surgical microscope (13 ) is shown, in front of the main objective (5 a, b) of the inventive ophthalmoscope attachment ( 1 ) is arranged, in which an optical system ( 14 ) is housed for image erection and pupil swapping. The ophthalmoscopic attachment ( 1 ) contains on the side facing the eye (2 ) an ophthalmoscopic lens (8 ) which generates a vertically and laterally reversed image of the fundus (3 ) being viewed in the first intermediate image plane ZE1. This image is erected via the following optical system ( 14 ), in this exemplary embodiment a lens arrangement, and imaged with the correct side in a second intermediate image plane ZE2. The image in the intermediate image plane ZE2 is viewed through the actual surgical microscope (13 ). This surgical microscope ( 13 ) is constructed in a known manner. The magnification changers (6 a, b) as well as tube lenses (16 a, b) and erecting prisms ( 7 a, b) for the two separate beam paths are arranged behind the common main objective ( 5 a, b). The stereoscopic viewing takes place through the binocular tubes ( 4 a, b). The use of a common main lens ( 5 a, b) for both observation beam paths is not specific to the invention. A separate objective could also be provided for each of the two observation beam paths.

Also shown in Fig. 1 is a lens ( 15 ) which is arranged between the optical system ( 14 ) and the lens-side end of the attachment ( 1 ) along the optical axis displaceable bar. With the help of this lens ( 15 ) it is possible, please include to focus on the section of the eye (2 ) of interest without having to change anything on the actual surgical microscope (13). With the aid of a suitable pivoting device, which is not shown in FIG. 1, the surgical microscope can be optionally used in a conventional manner, as well as in ophthalmic surgery.

In Fig. 2, the ophthalmoscopy attachment ( 1 ) according to the invention is shown, which contains the optical system for image erection and pupil swapping, which in this exemplary embodiment from an optical arrangement with several lenses ( 9 a, 10 , 11 , 12 , 9 b) is. The ophthalmoscopic lens (8 ), arranged on the side of the set ( 1 ) facing the patient's eye, provides a vertically and laterally reversed image of the eye part in the intermediate image plane ZE1. This image is imaged upright and laterally in the intermediate image plane ZE2 using the following five lenses ( 9 a, 10 , 11 , 12 , 9 b) on a scale of 1: 1. The actual mapping is made by a triplet, consisting of two lenses with positive refractive power (L3: 10, L1: 12) and a lens with negative refractive power (L2: 11) arranged in between. Two further lenses (A1: 9a; A2: 9b) act as field lenses. With the help of a lens ( 15 ) which can be displaced along the optical axis, the focus on the eye segment of interest takes place within the attachment ( 1). The image generated in the intermediate image plane ZE2 is viewed with the surgical microscope (13 ).

To the optical arrangement in a corresponding attachment with Not being able to accommodate too great a length, it is possible Lich, not the individual elements of the optical arrangement to accommodate linearly one after the other, but so inner half of the intent to arrange that the imaging beam path is diverted.

For a lens system consisting of a triplet (L1: f ₁ ; L2: f ₂ ; L3: f ₃ ) and the two field lenses (A1: 9a, A2: 9b), which is used for the wavelengths 436 nm, 480 nm, 546 nm and 644 nm is corrected for color errors in the visible spectral range, the realizable focal length ratios for a main lens focal length of 200 mm are in the following ranges:

f₃: f₁ = [0.9. . . 2.0]
-f₂: f₁ = [0.4. . . 0.6]

Within these ranges, an acceptable length of the Ophthalmoscopy attachment that is as large as possible Offers working area below the surgical microscope. Furthermore, the image quality is correspondingly good optical arrangement guaranteed.

Embodiments with the associated data sets are in Tab. 1-3 can be found. Variations of individual parameters of this Data sets can result in a comparably good figure lead result.

FIG. 3 shows a section through the optical arrangement from FIG. 2 with the designations of the lens radii r _i , lens thicknesses d _i and lens distances d _i , as used in the data sets in Tab. 1-3.

Fig. 4 shows as a second embodiment the fiction, contemporary attachment (1 ), which contains an optical system for Bildauf direction and pupil swapping, which is designed here as a rectilinear erecting prism system ( 17 ). The intermediate image of the fundus generated by the ophthalmoscopic lens (8 ) or of the vitreous body areas of the eye near the fundus is erected by a straight Schmidt-Pechan prism with roof edge ( 17 ) immediately behind the first intermediate image plane ZE1 and the observation beam paths are exchanged. It is also possible to use a functionally equivalent mirror system. The arrangement of the erecting prism ( 17 ) at this point, where the stereoscopic beam paths are still intertwined, allows a very compact design of the erecting prism ( 17 ) or the attachment ( 1 ) according to the invention, since the overall beam path has its smallest extent at this point . Furthermore, in the attachment ( 1 ) according to the invention, a focusing lens ( 15 ) is arranged between the erecting prism ( 17 ) and the end of the attachment on the objective side. This focusing lens ( 15 ) can be displaced along the optical axis and is used to focus on the eye segment of interest.

Claims (11)

1. Ophthalmoscopy attachment ( 1 ) for a main lens ( 5 a, b) and one or more stereoscopic observation tubes ( 4 a, b) existing surgical microscope ( 13 ), characterized in that

• - One or more ophthalmic moscopy lenses (8 ) are provided in the attachment ( 1 ) for imaging the fundus or glass body areas of the eye,
• - An optical system (14 ; 9 a, 10 , 11 , 12 , 9 b; 17 ) is arranged behind the ophthalmoscope lens (8 ) or the ophthalmoscope lens for the purpose of erecting the image and interchanging the observation beam paths,
• - Between the optical system ( 14 ; 9 a, 10 , 11 , 12 , 9 b; 17 ) and the lens-side end of the ophthalmoscopy attachment ( 1 ) a ver displaceable lens ( 15 ) is provided along the optical axis, the focus focus on the part of the eye of interest.

2. Ophthalmoscopy attachment ( 1 ) according to claim 1, characterized in that the optical system is designed in the form of an optical arrangement which consists of two field lenses ( 9 a, b) and an interposed triplet made of two lenses of positive refractive power ( 10 , 12 ) and a lens ( 11 ) with negative refractive power lying between them. 3. Ophthalmoscopy attachment ( 1 ) according to claim 1 and 2, characterized in that the optical system ( 9 a, 10 , 11 , 12 , 9 b) an image of the ophthalmoscope lens ( 8 ) generated intermediate image in Abbil training scale 1 : 1 causes. 4. Ophthalmoscopy attachment ( 1 ) for a surgical microscope with a main lens focal length of 200 mm according to claims 1-3, characterized in that for a color error-corrected lens system consisting of a triplet ( 10 , 11 , 12 ) and two field lenses ( 9 a , 9 b), the focal length ratios (f ₃ : f ₁ ) and (-f ₂ : f ₁ ) of the triplet lenses (L1: 12, f ₁ ; L2: 11, f ₂ ; L3: 10, f ₃ ) in lie in the following ranges: (f₃: f₁) = [0.9. . . 2.0]
(-f₂: f₁) = [0.4. . . 0.6] 5. Ophthalmoscopy attachment ( 1 ) according to claims 1-4, characterized in that the lenses used ( 9 a, 10 , 11 , 12 , 9 b) of the optical arrangement the data given in the following Tab. 1 for the lens radii r _i , lens thickness d _i , lens spacing d _i as well as the refractive indices n (546 nm) and Abbe numbers ν _{e of} the types of glass used or values that lead to a comparably good imaging result according to this data set by varying individual parameters. Table 1 (f₃: f₁ = 2.0, -f₂: f₁ = 0.545) 6. Ophthalmoscopy attachment ( 1 ) according to claims 1-4, characterized in that the lenses used ( 9 a, 10 , 11 , 12 , 9 b) of the optical arrangement the data given in the following Tab. 2 for the lens radii r _i , lens thickness d _i , lens spacing d _i as well as the refractive indices n (546 nm) and Abbe numbers ν _{e of} the types of glass used or values that lead to a comparably good imaging result according to this data set by varying individual parameters. Table 2 (f₃: f₁ = 1.66, -f₂: f₁ = 0.56) 7. Ophthalmoscopy attachment ( 1 ) according to claims 1-4, characterized in that the lenses used ( 9 a, 10 , 11 , 12 , 9 b) of the optical arrangement, the data given in the following Tab. 3 for the lens radii r _i , lens thickness d _i , lens spacing d _i as well as the refractive indices n (546 nm) and Abbe numbers ν _{e of} the types of glass used or values that lead to a comparably good imaging result according to this data set by varying individual parameters. Table 3 (f₃: f₁ = 0.88, -f₂: f₁ = 0.40) 8. Ophthalmoscopy attachment ( 1 ) according to claim 1, characterized in that the optical system is designed in the form of a rectilinear erecting prism system ( 17 ) or as a functionally equivalent mirror system which causes an image erection and an exchange of the observation beam paths. 9. Ophthalmoscopy attachment ( 1 ) according to claim 1 and 8, characterized in that the optical system is designed in the form of a Schmidt-Pechan prism with a roof edge ( 17 ) or as a mirror system with a corresponding beam path. 10. Ophthalmoscopy attachment ( 1 ) according to claim 1 and one or more of the following, characterized in that the attachment ( 1 ) can be positioned with the aid of a pivoting device in front of the main lens ( 5 a, b) of a surgical microscope ( 13 ). 11. Surgical microscope with an ophthalmoscope attachment according to claim 1 and one or more of the following, characterized in that it is used in eye surgery used to get a magnified picture of the back of the eye base or parts of the vitreous.