DE102008055755A1 - Ophthalmologic measurement system i.e. optical biometer, for obtaining biometric data of eyes of patient, has test unit i.e. test eye, with test eye receiving device for varying position of test unit with respect to evaluating unit - Google Patents

Abstract

The system has an illuminating unit for illuminating eyes with light, and a detecting and evaluating unit for detecting and evaluating re-scattered and reflected light portion. A test unit i.e. test eye (PA), is integrated in the system and tests functions and calibration conditions of the system. The test unit has a test structure i.e. bent surface, and a test eye receiving device (AV) for varying position of the test unit with respect to the detecting and evaluating unit. The illuminating unit emits light at different angles greater than 5 degrees with respect to an optical axis.

Description

The The present invention relates to an ophthalmic measuring system to obtain the biometric data of an eye, which the for checking the functionality and the calibration state required calibration and test equipment features.

The calibration used in ophthalmic measuring systems and test agents are also called so-called test eyes designated.

Most of time are users of ophthalmic devices stopped calibrating and test equipment at predetermined intervals or before measurements on the patient on the device, to measure and compare the obtained measured values with the specifications in order to Check functionality and calibration condition. This is especially true for devices for biometry, keratometry, Topography of the eye or in Scheimpflug cameras the case. Complex light structures such as slices, rings, Slits o. Ä. Under large or very different Angle, sometimes projected simultaneously on the eye.

To The prior art includes both ophthalmic measuring systems for the determination of the biometric data of an eye as well as calibration and test equipment for checking the functionality and the calibration state in the form of test eyes sufficient known.

That's how it describes DE 195 04 465 A1 a calibration and test equipment for optical eye length measuring instruments, in particular for interferometric measurements. For this purpose, transparent balls of a diameter of about 16 mm and a refractive index of about 2 are used as calibrating and testing means. As a result, the radius of curvature of the surface of the specimen corresponds approximately to that of the cornea, so that the beam path in the measuring system as in the measurement in the natural eye runs. In a preferred embodiment, the test specimen has a defined reduced transmission in order better to adapt the transmission and / or reflectivity to the conditions at the eye. By changing the reflectivity of the coatings of the front side and / or the back of the specimen or their transparency different human eyes can be modeled.

Another calibration and test equipment for optical eye length measuring instruments is in the DE 199 36 571 B4 described. This consists of two arranged in the illumination beam path, oppositely oriented plano-convex lenses, between which there is a neutral filter with a defined transmission. Hereby, a test specimen is provided which, despite its relatively simple construction, is universally applicable to optical eye length measuring instruments. To reduce unwanted reflections on the plane plate, the entire assembly is used at an angle between 10 and 20 degrees. Through the use of another gray filter or the variation of its thickness, further test spheres can be dimensioned which simulate different turbidity values through eye cataract. Advantageously, by varying the tilt in the beam path to set an accurate absorption, since tilting by about degrees means a transmission correction of about 20-25%.

To The prior art are to ophthalmological measuring systems for Determining the biometric data of an eye only solutions known in which the required calibration and test equipment are designed as separate optical elements and in regular Time intervals for checking the functionality and the calibration state.

to Determining the biometric data of an eye, there are a number known methods and measuring devices. For example it required prior to surgery to replace the Eye lens in the presence of a lens opacity (cataract) different biometric parameters of the eye. To one as possible to ensure optimal vision after surgery it is necessary to have these parameters with correspondingly high accuracy to determine. The selection of a suitable replacement lens on the basis of measured values are determined using established formulas and calculation methods.

The The most important parameters to be determined are u. a. the axis length (Distance to the retina), the corneal curvature and refractive power, as well as the length of the anterior chamber (distance to the eye lens). These Readings can be taken consecutively at different ophthalmic Devices or with the help of specially optimized, biometric Measuring instruments are obtained.

to Determination of these parameters have in addition to ultrasonic measuring devices especially optical measuring instruments based on short coherence interferometry methods enforced. These on short-coherence interferometry based methods are depth profiles or two-dimensional Depth-sectional images of scattering potentials, especially of scattering at structure transitions, shown. As a short-coherent Measuring methods have hereby the so-called OCDR method (OCDR = optical coherence domain reflectometry) and the so-called OCT method (OCT = optical coherence tomography) enforced.

In the OCDR, time-incoherent light is used with the aid of an interferometer to acquire depth profiles on reflective and scattering structures and distance measurements based thereon. When OCT is, moreover, as in the US 5,321,501 described, realized by means of a beam deflection imaging on the reflective or scattering structures. Such systems, as well as Scheimplugkamerasysteme, for example, are suitable for obtaining biometric data from image information, such as the dimensions of the anterior chamber, such as those needed for the adaptation of Phakischer intraocular lenses.

That's how it describes US 7,322,699 B2 a combination device for the non-contact determination of biometric data, such as axle length, anterior chamber depth and corneal curvature. With the solution described, it is possible, starting from the measurement of the required data on the calculation up to the selection of the intraocular lens IOL to be implanted to perform with only one device. Increased stress on the patient by multiple placement and measurement on different devices can be avoided as well as data loss or data corruption by transmitting the measured values between different devices.

A combination device for the contactless determination of axis length, anterior chamber depth and corneal curvature of the eye, as well as the calculation and selection of an intraocular lens IOL to be implanted is described in US Pat DE 198 57 001 A1 described. In particular, before a cataract operation, but also in the monitoring of school myopia and the Aniseikoniebestimmung these measures must be determined, which are also important for the selection of the intraocular lens IOL to be implanted. The determined measured variables are used in formulas which calculate the optical effect of the IOL. Depending on the type of device used, different errors may occur which influence the selection of the IOL.

In clinical practice it has been customary to measure these quantities at least by means of two devices (eg ultrasound a-scan and automatic keratometer). Since the calculation of the IOL can now be carried out by means of a device arrangement, data losses or data falsifications in the transmission of the measured values from different devices to the computer performing the calculation of the IOL are also eliminated. The method based on a short-coherent IOLMaster ^® from Carl Zeiss Meditec AG provides an optical measuring device, according to the described principle of the solution is.

Usually is for calibration and / or function check the measuring functions of such devices a supplied Test ball at regular intervals to measure.

To For example, a holder with a test ball in addition the chin rest holes are plugged. On the test balls the corresponding nominal values and the tolerances are noted, those of the review serve the calibration state. The device should only be in Operation when the measurements provide results, the setpoints specified on the test ball within correspond to the specified tolerances. After successful Measurement, the test balls are removed again and safe to stow, damage and / or dirt to prevent.

In the US 2007 / 0291277A1 An ophthalmic system is described which consists of an optical coherence tomography (OCT) system, a fundus acquisition system, an iris acquisition system, a motorized chin rest, internal test structures and a fixation tag unit. In this case, the internal test structures, which are designed essentially as spaced-apart surfaces and as cross-hairs or as horizontal or vertical beam structures, are provided for checking individual functionalities. However, with these internal test structures, only internal functional tests and calibrations of the OCT system (optical coherent tomography) or of the LSLO system used for fundus acquisition (line scanning laser ophthalmoscope) are possible, ie in particular not considering all the optical components on the whole Beam path to and from the patient's eye. That is why in Scripture US 2007/0291277 A1 in addition to the internal test structure also described a conventional test eye, which is intended only for calibrations and must be set up manually.

adversely In these solutions, that affects the use external test eyes awkward for the user is and has a significant source of error. Understandably is the storage, plugging, measuring the test eye, as well reading and comparing the calibration data is not user-friendly.

Of the The present invention is based on the object an ophthalmological Measuring system, in particular for the determination of biometric data develop, which mentioned in the prior art Disadvantages not. The test eye should be at least one Have test structure and for use in ophthalmic Devices with structure projection, in particular Keratometern suitable be.

According to the invention the object by the features of the independent claims solved. Preferred developments and refinements are Subject of the dependent claims.

The ophthalmic measuring system according to the invention, in particular for obtaining the biometric data of an eye, consists of at least means for illuminating an eye with light and Funds for collection and evaluation scattered back or reflected light components, as well as a control unit. there are for a calibration as well as the review Calibration required for the function and calibration state. and test equipment integrated into the ophthalmic measuring system, what the ophthalmic measuring system over at least a device for receiving and aligning the position at least a calibration and test equipment with respect to the means to capture the backscattered or reflected Has light components.

in the The following is the simplicity instead of the term, calibration and Test equipment 'only, test equipment' used, without however the possibility of using it gained Exclude measurement data for calibration of the measuring system.

Even though the present invention an ophthalmological measuring system, in particular concerning the determination of biometric data is the inventive solution the integration of test equipment also for others ophthalmic, dermatological or other devices, with calibrations at regular intervals and / or functional checks are required, suitable. This includes measurement systems as part of ophthalmic therapy systems a, for example, those for photocoagulation on the retina or laser processing for refraction correction.

The Invention will be described below by way of exemplary embodiment described in more detail. Show this.

1 : an IOLMaster ^® with a test probe integrated in the headrest,

2 : a device for receiving at least one Prüfauges with a cover and means for cleaning the Prüfauges and

3 : an ophthalmic measuring system with an inspection eye integrated into the device measuring head.

The ophthalmic measuring system according to the invention, especially for obtaining the biometric data of an eye at least means for illuminating an eye with light and Funds for collection and evaluation scattered back or reflected light components, as well as a control unit. The for calibration as well as for verification the function and the calibration condition required test equipment are integrated into the ophthalmic measuring system, for which purpose the ophthalmic measuring system via at least one device for receiving and aligning the position of at least one test device in terms of the means of detection scattered back or reflected light components.

When Means for detecting backscattered or reflected Light components are available photodetectors or cameras used.

The This ophthalmic measuring system can in particular about Means for simultaneous illumination of an eye with light off one or more light sources and under different, in particular large angles to the visual axis of the eye of> 5 °,> 10 ° or even> 15 °, as for example in ophthalmic devices for keratometry or topography is required.

Preferably the test equipment has at least a curved surface as a test structure and over a serial number that automates mechanically, electrically, magnetically, is optically and / or electromagnetically detectable, so that the measurement data clearly assignable, in particular the need for a error-prone interaction with the user of the measuring system to avoid. For example, the serial number can be binary coded in the form of conductor bridges between electrical contacts at the base. Alternatively or optionally, the test equipment also the calibration data itself in a example electronically include readable memory.

• – Testflächen, insbesondere -sphären, für die Bestimmung des Krümmungsradius an Kornea und/oder Augenlinse,
• – Abstandsstrukturen zur Kalibrierung von Teilstreckenmessungen, wie Achslänge oder Vorderkammertiefe,
• – Reflektoren mit bestimmten Reflexionsgraden (Abschwächer) zur Sensitivitätsbestimmung und
• – Testmuster für Auflösungstests und laterale Kalibrierung von Fundus- oder Vorderkammerabbildungen.

The test equipment used can have one or more test structures. Possible test structures are:

• Test surfaces, in particular -spheres, for determining the radius of curvature of the cornea and / or eye lens,
• Distance structures for the calibration of partial distance measurements, such as axis length or anterior chamber depth,
• - Reflectors with certain reflectivities (attenuators) for the determination of sensitivity and
• - Test patterns for dissolution tests and lateral calibration of fundus or anterior chamber images.

The device for receiving at least one test means has a device with which the test means is moved mechanically or semi-automatically or fully automatically into the position required for the measurement. One possible speed of the semi-automatic positioning, for example, a manual reset of the test means in the recording Device, after an electromechanically triggered unfolding or extension of the test means from the recording by means of a spring. This makes it possible, for example, to realize a positioning of the test device with a minimum of electromechanical components.

Preferably However, the movement of the test equipment is motorized and fully automatically into the position required for the measurement, d. H. to a predetermined or signal-optimized position near the Nominal position of the patient's eye.

To Moving to this position may be relative Fine positioning between the test equipment and the device measuring head required to allow the measuring beams from a lighting unit after reflection or backscattering on the test equipment optimally or sufficiently in the measuring module come to mind.

To can also sensors, such as photoreceivers with pinhole, in the test equipment or in the receptacle behind the test equipment be provided, which is a suitable feedback signal for automatic fine positioning or also signals for detecting laser power or also transmission changes on the test equipment, for example due to contamination.

The Device for receiving at least one test means is here on the headrest or on the device head arranged yourself. Furthermore, it is advantageous that the agent designed to accommodate at least one test means is that the test equipment is interchangeable.

In a first execution shows 1 by way of example an ophthalmological measuring system in the form of a IOLMaster ^®, wherein the device for receiving at least one test agent to the headrest is arranged. The IOLMaster ^® consists at least of a computer connected via a base plate GP with a headrest KS for fixing the to the eye under examination devices measuring head GK, which is adjustable to align with the examined eye in x, y and z, as well as a control and evaluation unit not shown , In this case, the required test means in the form of a Prüfauges PA are integrated, the headrest KS has a device AV for receiving at least one Prüfauges PA. The device AV for receiving at least one test eye PA has means with which the test means is moved mechanically or semi-automatically or fully automatically into the position required for the measurement. The movement can, as in 1 shown by swings or tilting, but also by turning or linear extension done. Preferably, the device AV has appropriate actuators for fully automatic movement.

Farther it is advantageous that the device AV is designed such the test eye PA is exchangeable. To the clear Identification of the test eye PA and a unique Assignability of the measured data has this over a serial number that can be detected electrically, optically and / or optoelectrically is. In a further advantageous embodiment, the identification of the test eye PA via its serial number by means of an RFID system (radio frequency identification).

To ensure that both the calibration and the verification of the function and the calibration state comply with the relevant standards, it must be ensured that the test eye PA used is neither dirty nor damaged. This shows the 2 a further advantageous embodiment, in which the device AV for receiving at least one Prüfauges PA has a cover flap AK for protection against damage and means for cleaning RB. In the simplest case, the means for cleaning RB of the test eye PA may be a brush, which is arranged on the cover flap AK and moves when opening the flap on the Prüfauge PA and cleans this. In addition to mechanical but also pneumatic and / or acoustic means for cleaning the Prüfauges PA can be used. Furthermore, the use of dirt-repellent coatings or surface structures on touchable optical surfaces of the measuring system, in particular of the test device, is preferred. Such coatings are for example in JP 62080603 A described.

to Prevention of injury is for the time of calibration and checking the functionality and the calibration state must be ensured that no patient put his head on the headrest Has. For this purpose, the ophthalmic measuring system additionally has Safety devices that move the test eye Prevent PA when a patient already has his head on the headrest has filed. As safety devices, for example Photocells or pressure sensors or capacitive sensors be used on chin and / or forehead support.

In a further very advantageous embodiment, the device AV described above for receiving at least one Prüfauges PA with all its described advantageous embodiments in a motorized patient recording for devices for eye examination or treatment, according to US 7,401,921 B2 to get integrated. This has the advantage that the drives provided for the movement of the patient admission also for a Positionie tion of the test eye PA can be used.

Due to the simple and compact design, which in the US 7,401,921 B2 described motorized patient recording, it can be combined with a variety of ophthalmological devices, such as refractometers, keratometers, fundus cameras, corneal topographers, OCT-based imaging systems, wavefront sensors, laser eye surgery systems and so on.

In a second embodiment shows 3 an example of an ophthalmological measuring system in which the device for receiving at least one test means is arranged on the device measuring head itself. The ophthalmological measuring system comprises at least one device measuring head GK connected via a base plate GP with a headrest KS for fixing the eye to be examined, which can be adjusted to align with the eye to be examined in x, y and z, and a control and evaluation unit (not shown) ,

The required test equipment in the form of a test eye PA are integrated here, whereby the device measuring head GK via a device AV for receiving at least one Prüfauges PA features. Again, the device has AV for receiving at least one test eye PA via Means by which the test equipment is mechanically or semi- or fully automatically in the required for the measurement Position is moved. The movement is preferably carried out here by linear extension, but can also by pans, Tilting or turning can be realized. Preferably has the device AV for this via corresponding actuators for fully automatic movement.

In addition, the shows 3 the test eye PA in the extended state, ie in the measuring position for calibration or checking the functionality or the calibration state.

To Extending and / or aligning the Prüfauges PA is this illuminated by a lighting unit BE. The one from the test structure of the test eye PA reflected measuring beam MS is of a Measuring module MM recorded and evaluated. Based on the comparison of determined data with the stored calibration data is determined whether any existing deviations within the specified Tolerances are.

Around Dirt or damage to the test eye Preventing PA has the device AV for recording at least one test eye PA via a cover flap AK for protection against damage and over (not shown) means for cleaning features. The means for Cleaning can be done mechanically, pneumatically and / or acoustically work.

to Prevention of injury is for the time of calibration and checking the functionality and to ensure the calibration state here, that no patient put his head on the headrest Has. For this purpose, the ophthalmic measuring system additionally has Safety devices that move the test eye Prevent PA when a patient already has his head on the headrest has filed. As safety devices, for example Photocells or pressure sensors or capacitive sensors be used on chin and / or forehead support.

The Integration of the device AV for receiving at least one Prüfauges PA in the device measuring head GK has an advantageous effect, that the distance of the Prüfauges PA regardless of the position of the headrest KS is. This makes it possible before extending the test eye PA the distance between Device measuring head GK and head rest KS on one Minimum distance MA to enlarge that injury a patient can already be excluded thereby. On Safety devices could also be dispensed with.

In a special embodiment is the device for recording and changing the position of the test means in Regarding the means of detection scattered back or reflected light components designed so that in addition to the device for receiving the test means, means for moving a additional optical element are present to the Test equipment with regard to the means of recording the return Aligned scattered or reflected light components.

When additional optical element is here in the simplest Case uses a plane mirror, which moves in the measuring beam path and redirects it towards the test equipment. The Movement also takes place here mechanically or semi-automatically or fully automatically. The test equipment is arranged at such a distance, usually containing the patient eye to be examined located.

A Such an arrangement has the advantage that the test equipment can be integrated into the ophthalmic measuring system and not has to be moved. By a 45 ° inclined arranged Plane mirror, the measuring beam path is angled 90 °, so that the test equipment for example in the device base can be integrated.

The test equipment has also in this embodiment variant at least one curved surface as a test structure and a serial number, the electrical, optical and / or opto-elek is metrically detectable, so that the measurement data are clearly assigned.

The Device for receiving at least one test means is designed so that the test equipment is interchangeable and preferably has a cover for Protection of the test equipment and / or means for Cleaning the test equipment.

With The inventive arrangement is an ophthalmic Measuring system, in particular for the determination of biometric data of an eye, provided which in the state does not have the disadvantages mentioned in the art. The solution is especially for use in ophthalmic Devices with structure projection, in particular keratometers suitable.

The proposed solution allows automated verification of calibration state and functionality of ophthalmic Measuring systems that used to be a manual working with a test eye required. The measurement of test eyes can be standard be designed as part of the device initialization.

Furthermore Solutions are realized that do not require care (Cleaning) on the test eye require and a swap or error when Reading of calibration data is impossible.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 19504465 A1 [0005]
• - DE 19936571 B4 [0006]
• - US 5321501 [0011]
• - US 7322699 B2 [0012]
• - DE 19857001 A1 [0013]
• US 2007/0291277 A1 [0017, 0017]
• JP 62080603 A [0040]
• US 7401921 B2 [0042, 0043]

Claims (12)

Ophthalmological measuring system, in particular for obtaining biometric data of an eye, at least consisting of means for illuminating an eye with light and means for detecting and evaluating scattered or reflected light components, and a control unit, characterized in that for checking the function and the calibration state of At least one measuring device integrated in the ophthalmological measuring system is provided, which has at least one test structure and that a device is provided to receive the test means and to change its position with respect to the means for detecting the backscattered or reflected light components. Ophthalmological measuring system according to claim 1, characterized characterized in that means for simultaneous illumination of a Eye with light from different, especially angles> 5 ° to the visual axis available. Ophthalmological measuring system after at least one the aforementioned claims, characterized in that the device for picking up and changing the position the test equipment with respect to the means of detection scattered or reflected light components is designed so that in addition to the device for receiving the test medium for moving an additional optical element are to the test equipment in terms of the means of detection to align the backscattered or reflected light components. Ophthalmological measuring system after at least one the aforementioned claims, characterized in that the test equipment over at least one curved Surface as a test structure features. Ophthalmological measuring system after at least one the aforementioned claims, characterized in that each test equipment has a serial number, which is automatically detectable, so that the measurement data can be uniquely assigned are. Ophthalmological measuring system after at least one the aforementioned claims, characterized in that the device for receiving at least one test means via Has means with which the test equipment mechanically or semiautomatically or fully automatically in the for the measurement required position is moved. Ophthalmological measuring system after at least one the aforementioned claims, characterized in that the device for receiving at least one test means is designed so that the test equipment is interchangeable. Ophthalmological measuring system after at least one the aforementioned claims, characterized in that the device for receiving at least one test means on the headrest or on the device head itself is arranged. Ophthalmological measuring system after at least one the aforementioned claims, characterized in that the device for receiving at least one test means via a cover to protect the test equipment and / or over Agent for cleaning the test equipment features. Ophthalmological measuring system after at least one the aforementioned claims, characterized in that the ophthalmic measuring system additionally over Safety features, which include moving the integrated Prevent test agent when the head of a patient located on the headrest. Ophthalmological measuring system after at least one the aforementioned claims, characterized in that Means for detecting contamination of the test equipment are provided. Ophthalmological measuring system after at least one the aforementioned claims, characterized in that the means for automatic cleaning of the test equipment provided on mechanical, pneumatic and / or acoustic methods are.