DE19812297A1 - Method and device for examining an eye section - Google Patents

Abstract

A method and a device for examining an eye section by exposing the same and measuring the backscattered light with the aid of a punctiform exposure and measuring device (PBME), in particular the fiber end of a sample arm of an optical coherence tomography (OCT) interferometer, which in a sample beam path into a The slit of a slit lamp conjugate plane E is imaged and is imaged on the eye portion to be examined by means of a slit imaging optics 1080, the PBME in the conjugate plane E being deflected along the slit direction by a scanning device 1040 during the measurement.

Description

The invention relates to a method according to the preamble of claim 1 and a device according to the preamble of claim 5.

To examine the eye are used for the front section and for the rear section different recording techniques used so far. For the representation of the So far, a fundus camera or a Slit lamp together with the ophthalmoscopic lens, e.g. B. a contact glass or egg ner Volk lens used. The representation of the front section is by means of a Slit lamp possible. The examination of the posterior section of the eye is also known With the help of a fundus camera based on optical coherence tomography (OCT), for example in WO 92/19930 and US Patents 5,537,162; 5,506,634; 5,493,109 and 5,321,501 corresponding apparatuses are described. The known apparatuses are based on the examination of the rear section (fundus) of the Eye optimized.

To avoid inhomogeneities in the OCT of the posterior section of the eye, in particular the Avoiding breaking media is a complicated and lengthy adjustment process required to pass the OCT beam path past the inhomogeneities of the eye to judge the back of the eye. Required when using the OCT technique the setting and the target process with which the OCT beam path (sample beam) a special one is aimed at the fundus, in particular the retina Training and instruction as well as constant practice of the examining doctor.  

In a device known from FIG. 1 of US Pat . No. 5,537,162, the sample beam path of the OCT interferometer is focused in the focal plane (image plane) of a slit lamp microscope. With the help of an ophthalmoscopic pier lens designed as a Volk lens, the image plane of the slit lamp microscope is then imaged on the retina of the eye in conjunction with the refractive media of the eye.

The known device can only be used for OCT scanning of the rear section of the eye be used. Two separate deflecting mirrors are used to generate the Cross-sectional images of the eye are used with any orientation. This results in the Difficulty that the separate deflecting mirror a beam offset and not opti painterly coating create a double image of the eye. In addition, the work stood between the instrument and the patient's eye down because both are Deflecting mirror in front of the last optical component of the slit lamp. The Be use of necessary optical devices, such as an ophthalmoscope pier lens, is difficult.

The object of the invention is therefore to provide a method and a device at the outset to create the type mentioned, in which the setting and targeting process for the Untersu The relevant eye section is considerably simplified using OCT technology becomes.

This object is achieved in the method by the characterizing Features of claim 1 and in the device by the characterizing Features of claim 5 solved. The subclaims contain advantageous ones Embodiments of the invention.

The invention involves combining the conventional investigation of one selected section of the eye using the slit illumination (optical slice process ren) with the OCT technique (coherent slice image method), which is preferably a coherent light generated sectional image from the examined eye section wins. Here can both front sections (cornea, iris, lens) and rear sections  (Vitreous, retina, choroid) of the eye with the same examination device can be examined and recorded using the OCT technique.

The invention uses instruments established in ophthalmology (slit lamp, Ophthalmoscopic lens) for setting and targeting the exam location at the eye section of the scanning OCT sample beam. This is advantageous part of the slit lamp optics for guiding the OCT sample Beam path used.

Since the examination with the slit lamp for the ophthalmologist is a routine examination represents the setting and targeting process, which is more conventional when using OCT examination technique is considerably more complicated and time-consuming simple and essentially based on the conventional slit lamp technology Settings are reduced. It is also possible to have eye exams conventional slit lamp technology and with the OCT technology with an examination device and thereby a better and more accurate correlation between To produce slit lamp images and OCT slice images.

Advantageously, various slit lamp manipulations can be used to manipulate different types Cross-sectional images of an examination site on the eye can be obtained in succession. These sectional images can be recorded parallel to one another and lying next to one another men. However, it is also possible to have intersecting sectional images of one To win the examination site on the eye.

In the invention, a punctiform lighting and measuring device (PBME), which radiates and measures the light, in particular an OCT interferometer, and at formed for example as the fiber end of a sample arm of the OCT interferometer can be by means of imaging optics in the beam path of the slit illumination Coupled like that in the conventional way for straightening a slit image Slit lamp on the optics and eye used to be examined the sample beam together with the slit image on the sample to be examined Straighten the eye section. When measuring the section of the eye to be examined  the scanning movement is predetermined by the orientation of the gap shown. Ins in particular, the scanning movement takes place parallel or along the slit image.

For this, the imaging of the PBME and the imaging of the gap can be done with the help of a Coupling optics or superimposition optics, for example as a dichroic divider (Mirror) can be formed, superimposed. The PBME and the gap can either in a common plane or in conjugate planes be formed in order to then together towards the by means of the slit imaging optics to be examined eye section.

The slit lamp can be arranged opposite the coupling optics or overlay optics in such a way that the common plane, in which the slit is imaged together with the PBME, lies in front of the overlay optics in the OCT beam path coming from the punctiform emission surface of the PBME. For scanning, it is sufficient that the OCT sample beam is deflected in the common plane (conjugate slit plane) in the direction of the slit shown. In a further embodiment, the scanning can be carried out in such a way that the depicted PBME is moved in an arbitrary curve shape which is, however, defined in relation to the depicted gap. This can be done with the help of movable swivel mirrors. Downstream of the overlay optics, the OCT sample beam is guided together with the optical assemblies assigned to the slit illumination, namely the slit imaging optics. With the help of the optical system belonging to the slit lamp, the scanning exposure beam is aligned in the front section of the eye (cornea, iris, lens). For examinations on the posterior section of the eye, the image generated by the slit imaging optics of the PBME and the slit is carried out by means of an ophthalmoscopic lens, e.g. B. a Volk lens and the refractive media of the eye ( Fig. 1 of US 5,537,162).

The lie in the OCT sample beam path before the coupling optics or overlay optics The imaging and guiding optics can be done with the slit lamp, in particular connected to the slit lamp head which has the slit and slit lighting be that during the movement (turning, swiveling, tilting) of the slit lamp head  fes and the resulting movement of the gap, e.g. B. Twisting around the opti cal axis, at the same time also the imaging and guidance optics, in particular those for Scanning along the gap used scanning means, rotated or moved who the. This ensures that the OCT sample beam in each slit position in the common level is mapped. The gap mapping can also be done in the same way optics can be moved. Advantageously, it can be used exclusively for OCT required optics, e.g. B. the OCT interferometer, be removed from the examination site find, so that there is no disability at the examination site during the Untersu on the patient.

When using a Volk lens with the slit lamp, the focal length depends on the education essentially from the distance of the Volk lens to the slit lamp. If correct Tuning this distance, the image remains even when the distance between the measurement setup and patient received, since between the Volk lens and the right the patient's eye the beam path is parallel. This distance should be in the OCT measurement process, which is distance sensitive, can be variable. The goal of another Embodiment of the invention is, when the focus position is found this distance and thus the optical path in the sample beam path without change to vary the focus position.

This goal is achieved in one embodiment of the invention in that for fig an intermediate image containing the gap and the PBME on the fundus of the Eye, e.g. B. the retina of the eye, the Volk lens at a certain distance from the this intermediate image can be fixed. This is done by connecting the Volk lens to the Slit lamp, in particular the slit lamp head, with which the distance the Volk lens from the intermediate image for the respective examination on the eye can be. For this purpose, a holding device is used, in which the Volk lens is underneath keeping a certain distance from the gap, movable in all degrees of freedom is. For this purpose, a gimbal suspension of the Volk lens is advantageously used in the holding device used.  

The holding device can consist of a vertical and a horizontal rod, the ge are connected to each other in an articulated manner.

The invention is explained in more detail with reference to the figures. It shows

Fig. 1 shows schematically an embodiment of the invention; and

Fig. 2 shows an embodiment for an embodiment of the invention.

The exemplary embodiment shown schematically in FIG. 1 shows a device for examining sections, in particular the front section and the rear section of an eye 1100 . For this purpose, 1060 coherent light, in particular a laser beam, is emitted by a punctiform illumination measuring device (PBME). The PBME 1060 can be designed as a fiber end of a light-conducting fiber of an optical coherence tomography interferometer (OCT interferometer). The light emerging from the fiber de or the PBME 1060 is collimated with a collimator lens 1070 and then focused with a focusing lens 1030 in a plane E or with an imaging lens in the plane E. Between the plane E and the imaging system consisting of focusing optics 1030 and collimator optics 1070 there is a scanning device 1040 , which in the exemplary embodiment shown is designed as a pivotable mirror. To generate the scanning movement, the mirror can be driven by a galvanometer, for example, and be mounted in a pivot bearing 1130 .

The laser beam is then overlaid with the illumination beam path of a slit lamp using a coupling optics or superimposition optics 1120 , which can be designed as a dichroic mirror.

A slit lamp head 1110 , which has a slit S in a slit plane SE, belongs to the slit lamp. The slit S is illuminated by an illumination system 1050 . With the overlay optics 1120 (dichroic mirror), the plane E is brought into a plane conjugate to the slit plane SE.

In this way, the PBME 1060 , which can be the fiber end of a sample arm of the OCT interferometer, is brought together with the slit S or the slit plane SE of the slit lamp.

A slit imaging optic 1080 following the superimposition optics 1120 , which belongs to the slit illumination optics, forms the conjugate planes E and SE into the eye section of the eye 1100 to be examined in an image plane 1140 via a deflecting optic 1090 , which can be designed as a deflecting mirror. In the lower illustration (a) of FIG. 1, the plane 1140 is located in the front section of the eye.

For examinations on the rear section of the eye (e.g. retina), as the illustration (b) in FIG. 1 shows, a further image of the image plane 1140 is made by means of an ophthalmoscopic lens, for example a Volk lens 1020 , which is between the patient's eye 1100 and the image plane 1140 is arranged, and by means of the breaking media of the eye on the rear eye section.

The slit lamp head 1110 and the pivot bearing 1130 for the scanning device 1040 and the imaging optics (focusing lens system 1030 , collimator lens system 1070 ) for the PBME 1060 can be rigidly connected to one another. Furthermore, the slit imaging optics 1080 and the overlay optics 1120 can be rigidly connected to the slit lamp head 1110 . When the slit lamp head 1110 moves (twists, tilts, swivels) and the resulting movement of the slit S, the scanning device 1040 is simultaneously moved. Furthermore, the assigned optics 1030 , 1070 and 1080 are moved, so that the merging of the PBME 1060 with the slit S of the slit lamp is ensured by the overlay optics 1120 for any slit position. In this way, by simply actuating the slit lamp, an alignment of the OCT beam path toward the examination site on the eye is achieved for the scanning of the examining eye section. During the scanning, the light beam coming from the PBME is guided through the slit imaging optics 1080 and the deflection device 1090 to the examination site at the eye section. The scanning of the examination site takes place along the illustrated gap, the scanning movement being carried out by the scanning device 1040 , which is designed, for example, as a pivoting mirror. The reflected measuring beam is returned to the PBME via the optical modules explained above, and a sectional image of the examination or measuring location is generated by evaluating the measuring beam. In this way, a combination of slit lamp technology and scanning technology can be used to produce an optical sectional image. A plurality of sectional images can be produced one after the other by multiple scanning, which for example lie parallel next to one another or also lie crosswise to one another.

In a further embodiment, e.g. B. by integrating at least one additional swivel mirror any pattern with a defined position relative to Slit image to be scanned.

In Fig. 2, an embodiment of a holding device is shown schematically Darge, with which the Volk lens 1020 compared to the image plane 1140 of the slit lamp at a fixed distance, which can be adjusted for the respective examination, who can. The holding device is formed by a horizontal rod 1220 , on which, in particular at the end, the Volk lens 1020 is movably mounted in a universal joint 1230 in all degrees of freedom around a pivot point. This enables the movement of the Volk lens in any position for an optimal adjustment of the exposure process with the scanning laser beam of the OCT measuring device. The horizontal rod 1220 is connected to a vertical rod 1210 via a joint 1240 , in particular in the form of a hinge. The hinge 1240 is located at the intersection of the deflection optics 1090 . The centering of the Volk lens 1020 is infinitely adjustable with the aid of the joint 1240 . The vertical rod 1210 is rotatably fixed to the slit lamp by means of a holder 1200 , which can be designed as a magnetic holder. This ensures that a set distance between the Volk lens 1020 and the image plane 1140 of the slit lamp is maintained.

The axial distance between the Volk lens 1020 and the image plane 1040 can be roughly preset by rotating the entire holder 1200 . A fine adjustment of the axial distance and an adjustment of the focus position, for example if the patient is defective, can be ensured by adjusting the length (double arrow 1250 ) of the horizontal rods 1220 .

This makes it possible, when the focus position is found, to vary the optical path without changing the focus position between the Volk lens 1020 and the section to be examined on the patient's eye 1100 .

The holding device for the Volk lens described allows the doctor to observe or control other processes during the examination. Due to the magnetic adaptation of the holding device, a quick and easy change between right and left eyes is possible, since the magnet holder can be attached to one of the sides of the slit lamp as required. Due to the fixed connection of the Volk lens 1020 with the slit lamp, in particular the slit lamp head 1110 , the distance between the Volk lens 1020 and the image plane 1040 remains unchanged when the slit lamp moves.

Claims (12)

1. A method for examining a section of the eye by exposing the same and measuring the backscattered light with the aid of a particularly punctiform exposure and measuring device (PBME), in which the PBME (punctiform lighting and measuring device) is mapped in one plane and is used to scan the object to be examined Eye section is deflected and directed and in which the light reflected at the examined eye section is detected with the PBME and evaluated by coherence tomography (OCT technique), characterized in that the PBME together with the slit of a slit lamp via a slit imaging lens system on the eye section to be examined is mapped and deflected along the mapped gap during scanning. 2. The method according to claim 1 or 2, characterized in that the figure the PBME and the mapping of the slit is done in conjugate planes to the are finally overlaid. 3. The method according to claim 1 or 2, characterized in that the figure the PBME and the mapping of the gap are carried out together in one plane and the joint imaging of the gap and PBME using the gap imaging optics is directed to the section of the eye to be examined. 4. The method according to any one of claims 1 to 3, characterized in that on eye section to be examined several different scanning processes be carried out one after the other.   5. Apparatus for examining an eye section with a coherent light-emitting PBME, an optical imaging device for imaging the PBME in a plane and a scanning device for generating a scanning movement of the PBME for detecting the light reflected by the section of eyes to be examined, characterized in that a Coupling optics ( 1120 ), which merges the image (E) of the PBME ( 1060 ) and the slit (S) of a slit lamp via a slit imaging optics ( 1080 ) into a common image plane ( 1040 ) and maps them together onto the eye section to be examined and that the scanning device ( 1040 ) is designed in such a way that the PBME shown is moved in the longitudinal direction of the shown gap during the scanning process. 6. The device according to claim 5, characterized in that the Abtasteinrich device ( 1040 ) is designed in such a way that the PBME shown is moved in a randomly defined curve shape relative to the gap shown. 7. The device according to claim 5 or 6, characterized in that the Spaltab formation optics ( 1080 ) is arranged subsequently to the overlay optics ( 1120 ). 8. Device according to one of claims 5 to 7, characterized in that the common image plane (E), in which the column plane (SE) and the emission surface ( 1060 ) are brought together, lies in front of the overlay optics ( 1120 ). 9. Device according to one of claims 5 to 8, characterized in that with the movement of the slit (S) and the associated slit formation optics ( 1080 ) a movement of the PBME ( 1060 ) in the common image plane (E) map the image and Guide devices ( 1030 , 1040 , 1070 , 1130 ) is coupled. 10. Apparatus for examining an eye section with a coherent light-emitting PBME, an optical imaging device for imaging the PBME in a plane, a scanner for imaging the PBME in a plane, a scanner for generating a scanning movement of the light beam directed onto the eye section and a detector device for detecting the light reflected by the portion of the eye to be examined, in particular according to one of claims 5 to 8, characterized in that for imaging an intermediate image ( 1140 ) containing the gap (S) and the PBME (10060) onto the fundus of the eye Volk lens ( 1020 ) between the eye to be examined and the intermediate image plane ( 1140 ) at a certain distance from the intermediate image plane ( 1140 ) is arranged. 11. The device according to claim 10, characterized in that the Volk lens ( 1020 ) via a holding device ( 1210 , 1220 ) at a certain distance from the intermediate image plane ( 1140 ) is firmly connected. 12. The apparatus of claim 10 or 11, characterized in that the Volk lens ( 1020 ) is mounted in a gimbal ( 1030 ) in the holding device ( 1210 , 1220 ).