DE4114646C2 - Ophthalmoscope attachment for a surgical microscope - Google Patents

Description

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

Around the fundus or vitreous areas near the fundus Being able to look at the human eye microscopically is also possible an ophthalmoscopic lens an intermediate image of the observed Eye part generated with a surgical microscope is looked at. This picture viewed in this way is height and reversed and pseudo-stereoscopic, d. H. in the depths perception is reversed at the front and back. To micro being able to work surgically is an erect, stereoscopic correct image required. At the same time with The necessary image alignment must therefore be done in the surgical microscope an exchange of the two observation beam paths (Pupil exchange) to be done at stereoscopic Consider the otherwise occurring pseudo-stereo effect avoid.

The image erection and pupil exchange can be done by a Prismatic system take place between binocular tubes and magnification changer of the surgical microscope becomes.

Such a prism system is used, for example, in the DE 35 07 458 A1 described. With this additional component the working distance between the patient's eye and Observer pupil. Ergonomic and practical medical reasons is such a change in Working distance undesirable. Continue hiring such a prism system is particularly complex Solution if a co-observer on a second binocular tube should work. For this would be a corresponding one second such prism system required.

Another solution is in DE 35 39 009 A1 and proposed in DE utility model G 89 02 035 U1. Here  are the ophthalmo in an attachment to the surgical microscope scope lens and a system for image reversal of the generated Intermediate image housed. A corresponding one will be used Prism system immediately in front of the main lens of the operation arranged microscope. The focus on the interested the section of the eye is the actual one here Surgical microscope made a two-part main has one lens group against the other is movable. When replacing and changing this attachment must therefore always change settings on Surgical microscope can be done during a Surgery is very cumbersome. Another disadvantage of Arrangement of a reversal system immediately in front of the main lens is that at this point it is still partially overlapping, divergent beam paths through two separate Reversal systems are completely spatially separated. Doing so part of these two beam paths are hidden, d. H. it result in image errors in the surgical microscope (Vignetting). A disadvantage of such a Arrangement further that from the two-part main lens of the used surgical microscope an overall larger construction length of the system results in what is called for contradicts the largest possible field of work for the surgeon.

DE 38 26 069 A1 also describes a prism system for a Stereomicroscope known, which is simultaneously an image erection and swapping the two stereoscopic Observation beam paths caused, however, between the lens and the binocular tube is arranged.

DE 35 28 356 A1 proposes an ophthalmoscopy Attachment for a surgical microscope in which a pupil Exchanger after the main lens immediately before Binocular tube is attached.

The object of the present invention is an ophthalmo to create a microscope attachment for a surgical microscope an image erection of an ophthalmoscopic lens  generated intermediate image causes the observation beam paths swapped and an optional use of the surgical micro skops in a conventional way or as an ophthalmoscope allowed without entering the beam path of the surgical microscope to have to intervene. The ophthalmoscope attachment should be used an image error-free viewing of the intermediate image by the Ensure surgical microscope. Furthermore, with help this resolution is the stereoscopic view for one Co-observers may be possible, with only one more Binocular tube is required.

This task is solved by an ophthalmoscope attachment with the measures in the characterizing part of claim 1.

In the ophthalmoscope attachment according to the invention there is a optical system, which the desired image erection of the Intermediate image provides that from an ophthalmoscopic lens or an ophthalmoscopic lens in a first intermediate image plane is generated. Furthermore, the optical system works the exchange of the observation beam paths (Pupil exchange). The image erection and pupils swapping takes place here immediately after the first intermediate image plane where the stereoscopic observation beam paths not yet completely separate, but still are intertwined. The upright and right side Image can then be used with conventional operations microscope can be viewed stereoscopically correctly without additional operations on this surgical microscope are necessary. There is also a focusing lens in between the respective optical system and the lens end of intent. The focusing lens is along the optical one Movable axis. This lens is used for focusing on the section of the eye of interest. So that becomes the focus Sation made on the intent according to the invention without on to have to change the actual surgical microscope. Of the rapid change of perspective through operations microscope or through the surgical microscope with the ophthalmo Scope resolution is therefore possible for the user without time  elaborate refocusing with every change of Have to consider the operating microscope. By a suitable swivel device for the intent according to the invention can this rapid change possibility the point of view can be realized. The working distance thus remains between the patient's eye and the observer's pupil when changing the attachment according to the invention constant. So this attachment is variable for every conventional one Use surgical microscope. When watching through further employees are therefore only one of them Intent is necessary. The employee is considered in in this case with additional binocular tubes and that common main lens. The image erection and Pupil swapping is done either by an optical Arrangement consisting of two field lenses and a triplet, or caused by a straight-vision reversing prism, which in the according to the invention 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 is performed for image inversion and Pupillenvertauschung as a lens assembly;

FIG. 2 shows the inventive ophthalmoscope attachment from FIG. 1 with the corresponding lens arrangement;

Fig. 3 is a cross-sectional thickness of the lens arrangement of Figure 2 with the corresponding names of the lens radii, lenses and lens spacings.

Fig. 4 shows the ophthalmoscope attachment according to the invention, which contains a rectilinear reversing prism for image alignment and pupil exchange.

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 ) for image erection and pupil exchange is housed. On the side facing the eye ( 2 ), the ophthalmoscopic attachment ( 1 ) contains an ophthalmoscopic lens ( 8 ), which in the first intermediate image plane ZE1 generates an image of the fundus ( 3 ) that is inverted in terms of height and sides. This image is erected by means of the following optical system ( 14 ), in this exemplary embodiment a lens arrangement, and is imaged correctly 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. So behind the common main lens ( 5 a, b) the magnification changer ( 6 a, b) as well as tube lenses ( 16 a, b) and reversing prisms ( 7 a, b) for the two separate beam paths are arranged. The binocular tubes ( 4 a, b) are used for stereoscopic viewing. The use of a common main objective ( 5 a, b) for both observation beam paths is not specific to the invention. A separate lens 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 ) so as to be displaceable along the optical axis. With the help of this lens ( 15 ) it is possible 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 swiveling device, which is not shown in FIG. 1, the optional use of the surgical microscope in a conventional manner and in ophthalmic surgery is thus possible.

In Fig. 2 the ophthalmoscope attachment ( 1 ) according to the invention is shown, which contains the optical system for image erection and pupil exchange, which in this embodiment, for example, as an optical arrangement with a plurality of lenses (A12, A11, 10 , 11 , 12 , A21, A22 ) is executed. The ophthalmoscopic lens ( 8 ), arranged on the side of the attachment ( 1 ) facing the patient's eye, provides an upside-down and side-inverted image of the eye part under consideration in the intermediate image plane ZE1. This image is imaged on the following five lenses (A11, A12, 10 , 11 , 12 , A21, A22) on a scale of 1: 1 upright and to the right in the intermediate image plane ZE2. The actual imaging is done by a triplet, consisting of two lenses with positive refractive power (L3: 10 , L1: 12 ) and a lens with negative refractive power arranged in between (L2: 11 ). Two further lenses (A11, A12; A21, A22) act as field lenses. With the aid of a lens ( 15 ) which can be displaced along the optical axis, focusing on the section of the eye 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 use the optical arrangement in a corresponding header It is not possible to accommodate a large construction length possible, but not the individual elements of the optical arrangement linearly in succession, but within to arrange that the imaging beam path is redirected.

For a triplet lens system (L1: f₁; L2: f₂; L3: f₃) and the two field lenses (A11, A12; A21, A22), for the Wavelengths 436 nm, 480 nm, 546 nm and 644 nm in the visible Spectral range is color-corrected, the realisier focal length ratios for a main lens focal length of 200 mm in the following areas:

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

Within these ranges, an acceptable length of the Reach the ophthalmoscopic attachment of the largest possible Working area below the surgical microscope offers. Next  a correspondingly good image quality of the ensures optical arrangement.

Exemplary embodiments with the associated data records are shown in to find subclaims 4, 5 and 6. Variations of individual parameters of this Records can be compared to a good image result.

In Fig. 3 is a section through the optical arrangement of Fig. 2 is shown 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 subclaims 4, 5 and 6.

Fig. 4 shows as a second embodiment, the inventive attachment ( 1 ), which includes an optical system for image erection and pupil exchange, which is designed here as a rectilinear prism system ( 17 ). The intermediate image of the fundus or vitreous areas of the eye near the fundus generated by the ophthalmoscopic lens ( 8 ) is erected by a straight-sighted Schmidt-Pechan prism with a 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 reversing prism ( 17 ) at this point, where the stereoscopic beam paths are still intertwined, allows a very compact design of the reversing prism ( 17 ) or the attachment ( 1 ) according to the invention, since the total beam path has its smallest extension at this point. Furthermore, a focusing lens ( 15 ) is arranged in the attachment ( 1 ) according to the invention between the reversing prism ( 17 ) and the lens-side end of the attachment. This focusing lens ( 15 ) can be moved along the optical axis and serves to focus on the section of interest.

Claims (9)

1. Ophthalmoscope attachment for a surgical microscope with a main objective and stereoscopic observation tube, which enables imaging of the fundus or vitreous areas of a patient's eye and has an ophthalmoscopic lens ( 8 ) on the patient side and an optical system ( 14 , 17 ) for image erection on the observer side, characterized in that

• - That the optical system ( 14 , 17 ) for image erection also swaps the two stereoscopic observation beam paths, and
• - That between this optical system ( 14 , 17 ) for image erection and the observer-side end of the ophthalmoscope attachment ( 1 ) a slidable along the optical axis lens ( 15 ) is provided, which allows focusing on a desired part of the patient's eye.

2. Ophthalmoscope attachment according to claim 1, characterized in that the optical system ( 14 ) as a lens system (A11, A12, 10, 11, 12, A21, A22) is formed and from two field lenses (A11, A12; A21, A22 ) and a lens triplet ( 10 , 11 , 12 ) arranged between them, which is formed from two lenses of positive refractive power ( 10 , 12 ) and a lens ( 11 ) lying between these two lenses ( 10 , 12 ) of negative refractive power. 3. Ophthalmoscope attachment according to claim 2, characterized in that the lens system (A11, A12, 10, 11, 12, A21, A22) images the intermediate image generated by the ophthalmoscopic lens ( 8 ) on a scale of 1: 1 and is color-corrected, whereby at a focal length of the microscope objective ( 5 a, 5 b) of 200 mm for the lens triplet ( 10 , 11 , 12 ) the focal length ratio (f₃: f₁) of the patient lens ( 10 ) to the observer lens ( 12 ) between 0.88 and 2.0 and the focal length ratio (-f₂: f₁) of the central lens ( 11 ) to the observer-side lens ( 12 ) is between 0.4 and 0.6. 4. ophthalmoscope attachment according to claim 3, characterized in that

• - The lenses (A11, A12, 10, 11, 12, A21, A22) of the optical system ( 14 ) are designed as spherical lenses (A11, A12, 10, 11, 12, A21, A22) and the lens radii specified below ( r₁ to r₁₂), lens thicknesses (d₁, d₂, d₄₁ d₆, d₈, d₁₀, d₁₁) and lens distances (a₃, a₅, a₇, a₉) from each other, each in mm, and the specified refractive indices at a wavelength of 546 nm and the specified Have Abbe numbers,
• - The counting based on the indices 1 to 12 for the lens radii, on the basis of the indices 1, 2, 4, 6, 8, 10, 11 for the lens thicknesses and on the basis of the indices 3, 5, 7, 9 for the lens distances takes place towards the patient and begins with the observer-side field lens (A21, A22), in sequence over the observer-side lens ( 12 ), the central lens ( 11 ) and the patient-side lens ( 10 ) of the lens triplet ( 12 , 11 , 10 ) runs and ends with the patient's field lens (A11, A12),
• - And wherein the field lens (A21, A22) is designed as a double lens with an observer-side lens (A21) and a patient-side lens (A22) and these two lenses (A21, A22) abut each other with a common radius of curvature (r₂)
• - And wherein the field lens (A11, A12) is designed as a double lens with an observer-side lens (A11) and a patient-side lens (A12) and these two lenses (A11, A12) abut each other with a common radius of curvature (r₁₁):

5. ophthalmoscope attachment according to claim 3, characterized in that

• - The lenses (A11, A12, 10, 11, 12, A21, A22) of the optical system ( 14 ) are designed as spherical lenses (A11, A12, 10, 11, 12, A21, A22) and the lens radii specified below ( r₁ to r₁₂), lens thicknesses (d₁, d₂, d₄, d₈, d₁₀, d₁₁) and lens distances (a₃, a₅, a₇, a₉) from each other, each in mm, as well as the specified refractive indices at a wavelength of 546 nm and the specified Abbe - have numbers,
• - The counting based on the indices 1 to 12 for the lens radii, on the basis of the indices 1, 2, 4, 6, 8, 10, 11 for the lens thicknesses and on the basis of the indices 3, 5, 7, 9 for the lens distances takes place towards the patient and begins with the observer-side field lens (A21, A22), in sequence over the observer-side lens ( 12 ), the central lens ( 11 ) and the patient-side lens ( 10 ) of the lens triplet ( 12 , 11 , 10 ) runs and ends with the patient's field lens (A11, A12),
• - And wherein the field lens (A21, A22) is designed as a double lens with an observer-side lens (A21) and a patient-side lens (A22) and these two lenses (A21, A22) abut each other with a common radius of curvature (r₂)
• - And wherein the field lens (A11, A12) is designed as a double lens (A11, A12) with an observer lens (A11) and a patient lens (A12) and these two lenses (A11, A12) with a common radius of curvature (r₁₁) abut each other:

6. ophthalmoscope attachment according to claim 3, characterized in that

• - The lenses (A11, A12, 10, 11, 12, A21, A22) of the optical system ( 14 ) are designed as spherical lenses (A11, A12, 10, 11, 12, A21, A22) and the lens radii specified below ( r₁ to r₁₂), lens thicknesses (d₁, d₂, d₄, d₆, d₈, d₁₀, d₁₁) and lens distances (a₃, a₅, a₇, a₉) from each other, each in mm, and the specified refractive indices at a wavelength of 546 nm and the have given Abbe numbers,
• - The counting based on the indices 1 to 12 for the lens radii, on the basis of the indices 1, 2, 4, 6, 8, 10, 11 for the lens thicknesses and on the basis of the indices 3, 5, 7, 9 for the lens distances takes place towards the patient and begins with the observer-side field lens (A21, A22), in sequence over the observer-side lens ( 12 ), the central lens ( 11 ) and the patient-side lens ( 10 ) of the lens triplet ( 12 , 11 , 10 ) runs and ends with the patient's field lens (A11, A12),
• - And wherein the field lens (A21, A22) is designed as a double lens with an observer-side lens (A21) and a patient-side lens (A22) and these two lenses (A21, A22) abut each other with a common radius of curvature (r₂)
• - And wherein the field lens (A11, A12) is designed as a double lens (A11, A12) with an observer lens (A11) and a patient lens (A12) and these two lenses (A11, A12) with a common radius of curvature (r₁₁) abut each other:

7. ophthalmoscope attachment according to claim 1, characterized in that the optical system ( 17 ) is designed as a rectilinear reversing prism, in particular as a Schmidt-Pechan prism with a roof edge, or as a functionally equivalent mirror system. 8. ophthalmoscope attachment ( 1 ) according to any one of claims 1-7, characterized in that the attachment ( 1 ) with the aid of a pivoting device in front of the main objective ( 5 a, b) of the surgical microscope ( 13 ) can be pivoted. 9. Operating microscope with an ophthalmoscope attachment after Claim 1, characterized by the use in the Eye surgery to get an enlarged image of the back of the eye reason or parts of the vitreous.